The Chief Public Health Officer’s Report on the State of Public Health in Canada 2017 – Designing Healthy Living

A message from Canada's Chief Public Health Officer

Without being aware of it, our neighbourhoods and how they are built influence how healthy we are.

I chose designing healthy living as the topic for my first report as Canada’s Chief Public Health Officer because of the tremendous potential that changing our built environment has for helping Canadians live healthier lives.

Chronic diseases like diabetes, cancer and cardiovascular disease are the leading causes of death in Canada. It is alarming that in 2011, almost 2.7 million or 1 in 10 Canadians 20 years and older were living with diabetes. Rising rates of type II diabetes can be considered a red flag for poor health as they are associated with higher rates of other diseases and conditions and linked to an unhealthy diet, low physical activity and higher rates of overweight and obesity. Rates of type II diabetes and other chronic diseases in Canada could be reduced by seamlessly integrating healthy living into our daily lives which can be achieved, in part, by designing and redesigning our communities.

Improving public health and preventing disease through changes to our environment is a well-founded concept. For example, infectious disease rates in the last century were reduced not just through scientific innovation and vaccination, but also through infrastructure planning by improving sanitation and addressing overcrowding in residential neighbourhoods.

This report answers many questions but also raises several others. We need better information if we are to measure the health impacts of community design to incorporate evidence-based strategies into community planning. This report will raise awareness among Canadians about the unique aspects of their communities that they could take advantage of to improve their health. It will also encourage more dialogue across the many disciplines involved in community planning and health promotion so that neighbourhood design considers and promotes physical activity, healthy diets and mental wellness.

Dr. Theresa Tam
Chief Public Health Officer of Canada

Table of Contents

Download the alternative format
(PDF format, 7 MB, 74 pages)

Organization: Public Health Agency of Canada

Date published: 2018-07-20

Acknowledgements

Many individuals and organizations have contributed to the development of The Chief Public Health Officer's Report on the State of Public Health in Canada, 2017: Designing Healthy Living.

I would like to express my appreciation to the consultants who provided invaluable expert advice:

  • Dr. Cory Neudorf, Chief Medical Health Officer, Saskatoon Health Region, University of Saskatchewan
  • Dr. David Mowat, Canadian Partnership Against Cancer
  • Dr. Daryl Pullman, Memorial University
  • Dr. Elizabeth Saewyc, University of British Columbia
  • Dr. Jeff Reading, Simon Fraser University
  • Dr. John Frank, University of Edinburgh
  • Dr. Margo Greenwood, University of Northern British Columbia, National Collaborating Centre for Aboriginal Health
  • Dr. Michael Routledge, Medical Officer of Health, Manitoba
  • Dr. Peter Donnelly, President and Chief Executive Officer of Public Health Ontario

I would like to extend a special thank you to Dr. Mowat for sharing his expertise in reviewing many drafts. In addition, I would also like to recognize contributions made by partners and stakeholders who were consulted on the report under tight timelines, including Health Canada, Dr. Steven Hoffman at the Canadian Institutes of Health Research, Dr. Jim Dunn at the McMaster University, Dr. Meghan Winters at Simon Fraser University and Nathan Taylor at Memorial University.

I would also like to sincerely thank the many individuals and groups within the Public Health Agency of Canada for all of their efforts related to the development of my report, including John Cuningham and representatives from the Health Promotion and Chronic Disease Prevention Branch: Simone Powell, Dawn Sheppard, Greg Butler, Ahalya Mahendra, Wendy Thompson, Dr. Margaret de Groh and Christine Soon.

I appreciate the excellence and dedication of my support staff and CPHO Reports Unit in researching, consulting on and developing this report: Dr. Stephanie Rees-Tregunno, Anne-Marie Robert, Dr. Hong-Xing Wu, Michael Halucha, Judith O’Brien, Rhonda Fraser, Meheria Arya, Benjamin Jiaming Wang, Aimée Campeau, Stephanie Davies and Lori Engler-Todd.

Key messages

This Report raises awareness about how our built environment provides a foundation for healthy living and ultimately our health.

It is possible to improve or worsen the health of populations by changing our physical world. Conditions and chronic diseases linked to unhealthy living are increasing in Canada. For example, over 7.8 million Canadians 18 years and older were living with obesity in 2015, which is more than a quarter of this population. Obesity increases the risk for premature death and chronic diseases, such as cardiovascular disease, cancer and diabetes.

The relationship between the built environment, healthy living, people’s behaviour and health status is complex.  Even so, cities and communities can be designed and built to set people up for success so that healthy choices are the easier choices.

The majority of Canadians – about 80% – live in urban or suburban areas. While there are trends, the health of a population varies within the same geographic area. The rise of urban sprawl is a concern as it has been linked to sedentary lifestyles, easy access to unhealthy food, more time spent driving, less physical activity and higher rates of obesity.

While we know that changing the built environment can be a cost-effective way to increase physical activity, less is known about how to improve healthy diets and mental wellness through neighbourhood design as these are newer fields of study.

Improving the opportunity to cycle, walk or take public transit to work or school by changing the built environment is a growing area of research. Changing the built environment could significantly influence people’s daily physical activity. Community design features, such as connected streets, a mix of residential, commercial, educational and employment areas, bike paths, and good public transit can support being active to get to work or other places; whereas green spaces, waterways, walking paths, trails and recreation facilities can promote recreational physical activity.

Neighbourhoods with easy access to healthier food options appear to be linked to better diets and better health. Those with a higher ratio of unhealthy to healthy food options appear to be linked to poor diets and worse health. However, there are significant gaps in our knowledge and other factors, such as affordability, may have a bigger influence on diet than the built environment.

Neighbourhoods may not be set up to address social isolation and loneliness. Communities with houses that have front yards or that are close to the street, have destinations to walk to and have places for people to gather could encourage social interaction. Studies suggest that green spaces are linked to a variety of health benefits including lower risk for premature death. Ties to the land, water, family, community and identity, as well as a holistic, interconnected view of health and well-being are important components of Indigenous culture that can provide insight into healthy neighbourhood design.

Going forward, decision-makers and planners at all levels should take a multi-sectoral, collaborative approach and consider health as an important outcome as appropriate when making infrastructure planning decisions. More targeted and hypothesis-driven research, standardized data collection, and systematic evaluations of the health impact of community design features are needed.  With the diversity of communities and cities across Canada, considering context and engaging citizens are important for ensuring that a community’s unique needs are met when designing for healthy living.

Understanding the complexities of the link between the built environment and health

Recognizing the complexity of the link between the built environment, healthy living and people’s behaviour is essential when designing communities to improve health. For example Footnote 1-10

It is important to consider where a neighbourhood is situated and who lives there: Neighbourhoods are situated within a bigger context and are impacted by many factors beyond the built environment including laws, policies, socioeconomic factors, culture, beliefs and attitudes. Neighbourhoods are also dynamic and change over time. For example, people move in and out of neighbourhoods for many reasons, including due to their current state of health. People tend to live in neighbourhoods with others who are similar to them, often having similar characteristics, such as culture, values or socioeconomic status.

People’s behaviour and health are affected by many factors: Where we live is one factor among many that influences behaviour and health. Where people live, work, study, shop, play and are active can involve many neighbourhoods. Because it can take time for a neighbourhood to impact the health of its residents, it is difficult to identify which features or which neighbourhoods create a health impact on a population – for example, effects on health could be due to features that no longer exist or neighbourhoods that people lived in as children.

Applying research can be challenging: Research in the area of health and the built environment is rapidly evolving. To date, most studies have been observational and cross-sectional (comparing different groups of people at a specific point in time), making our ability to determine which neighbourhood features cause changes in health challenging. More targeted and hypothesis-driven research and evaluations of the health impact of community design features are needed.

Researchers also use a variety of definitions, methods and measures, which has led to some contradictory results. This limits our ability to draw conclusions and to develop effective initiatives based on existing evidence. Each community is unique with different characteristics, behavioural norms and needs. It can be difficult to directly apply findings from one community to another, including the application of findings from the United States or Europe to the Canadian context. Standardized, open data collection would support knowledge sharing and identification of approaches that can be effective across different communities. Within Canada, much of the research is situated in large urban settings, meaning there is a gap in our knowledge of the role of the built environment in small, rural, remote and Indigenous communities.

Section 1: What this report is about

This Report raises awareness about how our built environment provides a foundation for healthy living and ultimately our health.

It is possible to improve or worsen the health of populations by changing our physical world. The percentage of Canadians who report they are obese, living with diabetes, or a mood disorder has been increasing in Canada.Footnote 11,Footnote 12 These health issues have a serious impact on quality of life and are linked to some of the leading causes of death, including cancer, cardiovascular disease and respiratory disease.Footnote 13

Lifestyle factors, such as a lack of physical activity, sedentary behaviour, poor diet and lack of social connection can increase the risk for poor health outcomes.Footnote 14-18 For example, evidence suggests that about 30% of cancers can be prevented by adopting a healthy lifestyle.Footnote 19 While healthy behaviour is shaped by many forces, these lifestyle factors are all influenced by our built environment.

What is the built environment? For the purposes of this report, the built environment is defined as the external physical environment where we live, work, study and play. It includes buildings, roads, public transit systems, parks, and other types of infrastructure. It is linked to how we design, plan and build our communities.Footnote 20

This report focusses on the built environment and healthy living in terms of physical activity, healthy diets and mental wellness (including social connectedness). Although this report addresses these topics separately, it is recognized that they interact and influence health together. For example, a healthy diet and physical activity can lead to weight loss and reduced risk for obesity separately, but are more effective in combination.Footnote 21

There are many other ways that the built environment can impact health including through its role in air pollution, safety (e.g., injuries), housing, heat, UV exposure, climate change and natural disasters.

Healthy cities and communities are also defined by more than their built environment. Examples of other factors that are important to consider include inequity in terms of health and poverty, community engagement, social factors, cultural factors, economic factors and factors linked to the natural environment.

Changing Canadian lifestyles

In the 1940s, the split between urban-rural living was about 50-50; now about 80% of Canadians live in an urban or suburban area.Footnote 22Our communities are changing and often expanding through urban sprawl rather than by building compact and complete communities.Footnote 23-26 Urban sprawl has been linked to sedentary lifestyles, easy access to unhealthy food, less physical activity and higher rates of obesity.Footnote 27-36 One of the key results of urban sprawl that may explain some of these impacts is more time spent driving.Footnote 34-36 From 1999 to 2016, the number of registered light motor vehicles including cars and SUVs in Canada has increased at a faster rate than Canada’s population, at 36% compared to 19%. This suggests that Canadians are increasingly relying on driving.Footnote 37,Footnote 38

What is urban sprawl? Urban sprawl refers to urban areas expanding beyond their core, often into rural areas to form suburbs. This frequently results in different land use design than in urban centres, a lack of diversity in land use across suburbs and the need for more roads and infrastructure.Footnote 27 Footnote 39

Physical activity and sedentary behaviour:Although they appear to be the same, lack of physical activity and sedentary behaviour are two separate concepts. Lack of physical activity involves not being active enough to meet physical activity guidelines. Sedentary behaviour is any behaviour that involves low energy expenditure, such as sitting or lying down. Based on these definitions, an individual can be both active and sedentary.

Neighbourhoods to support healthy living

Figure 1 explains how neighbourhoods can be designed and built to provide a foundation for healthy living by promoting physical activity, healthy diets and supportive environments. These can be simple, practical measures, such as having stores that sell fresh fruit and vegetables near to where people live.

Figure 1: Examples of potential pathways from a neighbourhood’s built environment to good health. e.g.,Footnote 42-59

Figure  1: Examples of potential pathways from a neighbourhood’s built environment to good health. E.g., reference 42
Figure 1 - Text Equivalent

This image depicts how neighbourhood features may lead to good health through healthy living. Examples of neighbourhood design features that may promote physical activity include high population/residential density, connected streets, places to walk and ride a bike, living close to stores, school and work, attractive areas, parks, green spaces and recreation facilities, and good public transit. Examples of neighbourhood design features that may provide healthy food options include stores that sell healthy food nearby, farmers’ markets and community gardens. Examples of neighbourhood design features that may create a supportive environment include: places to gather, front porches, front yards, good sidewalks, access to attractive and green spaces, cultural spaces, architecture, and public art. Features that promote physical activity may lead to a reduced risk for obesity, diabetes and poor mental health as well as improved mental wellness. Features that provide healthy food options may lead to healthy diets which may reduce the risk for obesity, diabetes and poor mental health as well as improve mental wellness. Features that create a supportive environment may lead to a reduced risk for poor mental health and improve mental wellness.

We do not yet know how to quantify the extent to which the built environment affects healthy living, but we know enough to say with confidence that neighbourhoods that are built with health in mind are important for making healthy choices the easiest choices. For example, this could involve designing communities so that people live close enough to walk or bike to work or school.

The most developed area of research related to the built environment and healthy living is about the impact on physical activity. Research has shown that changing the built environment is a cost-effective way to increase physical activity in large populations. Examples include building multi-use trails on the bed of former railway tracks, equipment in parks, new bike and walking paths and easy access to recreation facilities.Footnote 40,Footnote 41 The roles of the built environment in healthy diets and mental health and wellness are still relatively new fields of study. Our knowledge is growing.

Building healthier Canadian neighbourhoods

Many Canadian cities are changing our built environment for the better. The concept of designing healthy cities as a global issue emerged from an initial healthy cities workshop held in Toronto in 1986.Footnote 60,Footnote 61 Today, there are many promising approaches available to improve communities with most focusing on urban settings.Footnote 62 Multiple sectors working together with community planners is essential to building healthy communities and supporting healthier Canadians.Footnote 62,Footnote 64

Snapshot of what Canada’s largest cities are doing:

Figure 2 captures the complexity of the built environment’s link to behaviour and health outcomes. It outlines how the built environment and other mediating factors can influence human behaviour which can lead to different health outcomes. This complex relationship exists within a multi-dimensional context defined by other determinants of health, such as age, genetics, gender, social environment, culture and health care.

Figure 2 : Overview of how the built environment might influence health. (adapted fromFootnote 72)

Figure 2 : Overview of how the built  environment might influence health. (Adapted from reference 72)
Figure 2 - Text Equivalent

This image depicts how the built environment may lead to various health outcomes based on human responses to the environment and the influence of various mediating factors and other determinants of health. Examples of features in the built environment that may impact health include land use, transportation, buildings and other infrastructure, and public facilities and areas. Examples of mediating factors include environmental contaminants, weather, climate, noise, crime, traffic safety, hazards and natural disasters. Examples of possible human responses to the built environment include behaviours such as physical activity, diet and substance use, psychological responses including satisfaction, depression, distress and social cohesion, and physiological response such as infections, activated immune system and hormones. Examples of possible health outcomes that are influenced by mediating factors and that result from human responses to the built environment include outcomes at the individual level, such as obesity, perceived health status and well-being and outcomes at the population level, such as premature death and rates of disease and other conditions. This complex interaction between the built environment and mediating factors that lead to human responses and health outcomes are all influenced by other determinants of health such as age, genetics, gender, social environment, income, education, culture and the health care system.

The history of public health and urban planning: Public health and urban planning have a long history of working together to tackle disease. In the early 1900s, the focus of this collaboration was on improving sanitation, reducing overcrowding to reduce infectious disease and moving people away from areas with high pollution. However, separating residential areas from areas of employment has likely contributed to our reliance on motor vehicles and urban sprawl.Footnote 31,Footnote 70,Footnote 71 More recently, public health professionals and urban planners are working together to tackle health issues linked to urban sprawl, such as low levels of physical activity and high rates of chronic diseases and conditions, such as obesity and diabetes.Footnote 70,Footnote 71

What this report covers

This report brings together evidence to explore how we can design Canadian communities to serve as a foundation for healthy living. Included in this report are the following sections

  • Canadian communities – This section provides an overview of the Canadian context through a snapshot of trends in health, data on Canada’s population and urban, suburban and rural health.
  • Building blocks of healthy living – This section explores how the built environment can create active neighbourhoods, influence healthy diets and lead to supportive environments.
  • Design features and specific populations – This section covers how the built environment can affect health in different populations by focusing on children, youth and older adults, as well as populations experiencing health inequity.
  • Designing communities for healthy living in Canada – This section provides an overview of how different sectors work together to design healthy communities in Canada and also provides examples of initiatives and approaches underway in some Canadian cities.
  • A call to action – This section aims to provide guidance on how we can better harness the impact of the built environment to improve the health and well-being of Canadians.

Section 2: Canadian communities

This section provides a snapshot of broad factors that differ across Canada and that also relate to the built environment.

While the majority of Canadians, about 80%, live in urban areas, Canada’s considerable geographic expanse creates communities with unique characteristics and needs. This diversity and how it is changing are important to consider when thinking about the built environment and its impacts on health.

Trends in Canadian health

Canadians are generally healthy, but some Canadians are healthier than others.Footnote 11 Diseases and conditions that are linked to unhealthy living have been increasing in Canada. For example, the percentage of Canadians

  • Aged 20 years and older living with diabetes has increased from 6% in 2000 to 10% in 2011 (based on hospitalization and physician claims).Footnote 11
  • Who were obese increased from 21% in 2003 to 25% in 2012.Footnote 12 Data from a revised survey on Canadians ages 18 years and older showed that rates of obesity have increased from 23% in 2004 to 27% in 2015.Footnote 73 Obesity in younger children appears to be decreasing from 14% in 2004 to 10% in 2015.Footnote 74
  • Who said they had been diagnosed with a mood disorder increased from 5% in 2003 to 8% in 2014.Footnote 11

Diabetes, obesity and mental health issues are all linked to a wide variety of other diseases and conditions, making them proxies for overall health.Footnote 11,Footnote 19,Footnote 690-692

Canada’s population is aging: The 2016 Census showed that for the first time, there are more adults over the age of 65 years (5.9 million) than children under the age of 15 years (5.8 million). The number of Canadians over the age of 85 years is growing four times more quickly than the overall Canadian population.Footnote 75,Footnote 76

However, the Prairie Provinces, the Territories and Indigenous populations have proportionally more children than older adults. Ontario has a similar proportion of each age group.Footnote 75

Large urban areas are aging less quickly than rural areas. The suburbs have even younger populations than urban centres.Footnote 75

Where Canadians are living in 2016

In 2016, Canada’s population reached more than 35 million people. Canada has one of the lowest population densities in the world at four people per square kilometre (km2); however, its population is largely clustered in a smaller area, mostly in urban centres and along the southern border with the United States.Footnote 23,Footnote 77 

In 2016, it was estimated that

  • 27 million or 76% of Canadians lived in areas with more than 100,000 residents.Footnote 24
  • 86% of Canada’s population resided in four provinces: Ontario (38%), Quebec (23%), British Columbia (13%) and Alberta (12%).Footnote 23
  • 12.5 million or almost 36% of Canadians lived in one of Canada’s three largest urban centres, namely Toronto, Montreal or Vancouver.Footnote 23
  • The population of Canada’s three territories was 2% the size of Toronto’s population.Footnote 78

Defining urban and rural areas: There are many definitions used to categorize urban and rural areas.Generally, urban areas have large populations in relatively small areas. Rural areas have small populations and are defined as any settlement lying outside urban or suburban areas.Footnote 25,Footnote 39,Footnote 80-82

Statistics Canada defines an urban area or population centre as having a population of at least 1000 and a population density of at least 400 people per km2. Rural areas are those that are outside an urban area.Footnote 82

Rural areas can include small towns, villages and other settlement of fewer than 1000 people and areas that contain estate lots, agricultural land, undeveloped areas and remote and wilderness areas.Footnote 82

For First Nations communities, Indigenous and Northern Affairs Canada defines urban, rural, remote and special access by proximity and access to nearest service centre:Footnote 83

  • Urban – within 50km and having road access; just over 34% of communities.
  • Rural – between 50 to 350 km and having road access; 44% of communities.
  • Remote – over 350 km and having road access; almost 4% of communities.
  • Special access – no year-round road access; 17% of communities.

Suburban living

By the 1960s, many Canadians lived in what we recognize today as suburbs.Footnote 63 Evidence shows that suburbs are not a new phenomenon, reaching back to at least medieval times. Their form and function as well as the characteristics of their residents have changed over time, affected by various events such as the Great Depression and the World Wars.Footnote 63 Compared to urban areas that have compact, walkable neighbourhoods, suburban living is often viewed as having an over-reliance on driving and fewer places to walk to, which can lead to less physical activity and more sedentary behaviour.Footnote 27-32,Footnote 34-36

There is no universal definition of what constitutes a suburb. Suburbs can be defined in many ways, including through administrative or political boundaries, boundaries of a city’s central core, distance from city centre or population density.Footnote 39 How many Canadians live in the suburbs depends on the definition used. Canadian data show that

  • When defining suburbs by administrative or political boundaries, a greater proportion of people lived in the suburbs in Toronto (51%), Montreal (55%) and Vancouver (73%) in 2006. A smaller proportion of people lived in the suburbs in Ottawa (28%), Calgary (8%), Edmonton (29%), Quebec City (31%) and Winnipeg (9%).Footnote 39
  • In 2016, the population of municipalities that were located near large urban centres continued to grow at a faster pace (7%) than the large urban centres (6%). An example of a municipality located near a large urban centre is Whistler, British Columbia which is located near Vancouver. Municipalities that were located farther away from any size of urban centre were less likely to have a growing population.Footnote 25
  • For municipalities located within large urban areas, 31 had a population growth that was more than three times the Canadian average of 5%. Almost 26% of these municipalities were located in Montreal. Examples of municipalities located within large urban areas include Mirabel which is part of the greater Montreal and Cochrane which is part of the greater Calgary area.Footnote 25
  • The proportion of Canadians living in single-detached homes, which is a common characteristic of suburban areas, has been decreasing over the last 30 years, although more than half of Canadians lived in single-detached houses in 2016. Among Canada’s top ten most populated cities, multiple family dwellings (e.g., apartment buildings) were more common in Toronto, Montreal, Vancouver and Quebec City while single-detached homes were more common in Calgary, Edmonton, Ottawa-Gatineau, Winnipeg, Hamilton and Kitchener-Cambridge-Waterloo.Footnote 79

Urban and rural communities have different characteristics, needs and built environments. Although most Canadians live in or near urban areas, 20% of Canadians live in rural areas. Most research on the built environment and its influence on health has focused on urban areas. Existing research on rural areas suggests that they may need a tailored approach.e.g.,Footnote 84,Footnote 85

Urban, suburban and rural health

Health differs across and within urban, suburban and rural areas.Footnote 86 Factors such as age, gender, income, education, employment, population mobility, health care access and other characteristics likely play a role.Footnote 86-91,Footnote 98-100

Determining which areas are healthier and why is challenging due to

  • Multiple definitions of urban, suburban and rural areas.
  • Large variation in health status within urban, suburban and rural areas. For example, within urban areas, poor health can cluster in disadvantaged neighbourhoods.e.g.,Footnote 94,Footnote 101-104
  • Differences in how communities are designed in urban, suburban and rural areas.
  • Variations of socio-demographic factors across communities, such as age and income that influence health.
  • Mobility of populations, particularly people moving from rural to urban areas.
  • Changes in determinants of health across communities over time.

Typically, data on urban, suburban and rural differences provide only a snapshot of the health of current residents. Data from the United States suggest it is important to track changes over time. For example, urban areas in the United States have experienced a larger decrease in mortality rates for many diseases and conditions than rural areas, creating a widening gap in health inequity.Footnote 89

Older Canadian data show that which area is healthier depends on the health outcome being measured. People living in urban areas tend to have lower mortality rates for injury, poisoning, suicide and motor vehicle accidents as well as lower rates of smoking, arthritis and being overweight or obese and higher rates of people eating recommended amounts of fruit and vegetables than rural or suburban areas.Footnote 86 Urban areas also tend to have higher rates of cancer, infectious disease, stress and a weaker sense of community belonging. Urban residents are also more likely to be exposed to poor air quality.Footnote 86,Footnote 93-97

People living in rural areas were more likely to report they were in poor or fair health, were less stressed and had a stronger sense of community belonging than people living in urban or suburban areas. Residents of rural areas also tended to have the highest rates of mortality from all causes as well as from respiratory disease, the latter of which may be linked to smoking patterns. Generally, the more rural the area, the worse the health outcome for these measures, but the stronger the sense of community belonging.Footnote 86

Determining how healthy suburbs are is complicated and sometimes contradictory. Urban sprawl has been linked to sedentary lifestyles, easy access to unhealthy food, less physical activity and higher rates of being overweight or obese.Footnote 27-36,Footnote 86Yet when suburban areas are defined based on the proportion of residents who commuted to work in larger urban centres, those areas with the highest proportion had the lowest rates of people living with any chronic disease or dying from all causes, circulatory disease, respiratory disease, cancer or diabetes. Men living in these areas also had longer life expectancies than all other areas.Footnote 86 Suburbs with a strong connection to urban centres may benefit more from a range of employment opportunities and services.

Where people grow up may affect their health differently than where they live as adults. For example, some evidence has shown that people who grow up in an urban area react more strongly to stressful social situations than those who grow up outside urban areas.Footnote 113,Footnote 114How long an individual has lived in an area may also have an effect. For example, living or growing up in urban areas has been linked to a higher risk for poor mental health, a difference that cannot be fully explained by socio-demographic factors, such as age, gender, marital status, socioeconomic status or ethnicity.Footnote 105-112 This risk may be “dose-dependent” - the longer someone has lived in an urban environment or the “more urban the environment” (e.g., higher population density), the higher the risk.Footnote 110-112

Section 3: Building blocks for healthy living

3A: Active neighbourhoods

This section explores research on how we can build active communities to improve health.

The majority of Canadians do not get enough exercise.Footnote 115 Being physically active is an essential component to good health, yet Canadians are generally not active enough to gain optimal health benefits. How can we increase physical activity? Building communities that make being active an easy choice is an important step. Figure 3 shows how the complexity of neighbourhood features is likely linked to better health by increasing physical activity.

Figure 3: Overview of how the built environment influences physical activity to influence health. (adapted fromFootnote 72)

Figure 3: Overview of how the built environment influences physical activity to influence health. (Adapted from reference 72)
Figure 3 - Text Equivalent

This image depicts how the built environment may lead to various health outcomes based on increasing physical activity and the influence of various mediating factors and other determinants of health. Examples of features in the built environment that may increase physical activity include mixed land use, population density, connected streets, destinations nearby, public transit, paths, trails, sidewalks, recreation areas and facilities, green space and attractiveness. Examples of mediating factors include air pollution, weather and climate, crime, traffic safety and hazards. Examples of possible health outcomes include reduced risk for premature death, obesity, diabetes, cardiovascular disease, cancer and poor mental health. These complex interactions between the built environment and mediating factors that lead to human response and health outcomes are all influenced by other determinants of health, such as age, genetics, gender, social environment, income, education, culture and the health care system.

Physical activity and health

Globally, physical inactivity is thought to cause 6% to 10% of non-communicable diseases.Footnote 117 At least 30 minutes of moderate physical activity a day can decrease the risk of premature death by at least 19%.Footnote 118 Being physically active is strongly linked toFootnote 119-145

  • Better muscle strength, cardiovascular function and mental health.
  • Healthy development in children and youth.
  • Healthy aging.
  • Reduced risk for premature death, even with a small increase in physical activity.
  • Reduced risk of diseases and conditions such as obesity, heart disease, some types of cancer, diabetes, dementia, osteoporosis, and cardiovascular issues.
  • Better health in people who are living with various diseases and conditions (e.g., cancer, diabetes, mood disorders).

Did you know? In 2013, only 10% of Canadian children and youth and 20% of Canadian adults met the Canadian Physical Activity Guidelines when their activity levels were measured via accelerometers.Footnote 115

The Guidelines recommend that:

Toddlers should do at least three hours of physical activity over each day of any intensity.

Children and youth should do:

  • At least one hour a day of moderate to vigorous aerobic activity.
  • Muscle and bone strengthening exercise at least three times a week.
  • Several hours of light activity per day.

Adults should do:

  • At least 150 minutes of moderate to vigorous aerobic activity per week.
  • Muscle and bone strengthening exercise at least twice a week.

These are recommended levels; however, people can still achieve health benefits from lower levels of activity. Health benefits of increasing activity may be greatest for those who are inactive.Footnote 116

Building neighbourhoods that promote physical activity

Neighbourhoods can be designed to promote utilitarian (activity to get somewhere or do something), recreational (activity during leisure time) physical activity or both. Both types of activity can be important contributors for meeting physical activity guidelines and are linked to similar and different types of neighbourhood features.

At a population level, efforts have focused on harnessing the built environment to build communities that encourage active transportation in the forms of walking, cycling and using public transit, as well as recreational physical activity. In some situations, the relationship between the built environment and physical activity has been linked to better health, such as lower body mass index and body fat; improved cardiovascular disease risk factors; lower risk for cancer; lower risk for premature death from all causes; better mental health; and a stronger sense of community belonging.Footnote 146-168

Encouraging active transportation: Walking and cycling are common forms of physical activity and active transportation

  • Walking is popular and considered to be a great way to be physically active for all ages. It is often a better choice in busy, dense areas.Footnote 169-170
  • Cycling is an efficient way of being moderately to vigorously active and allows people to travel farther distances than walking. It often has less infrastructure to support it than has walking.Footnote 169,Footnote 177

What is active transportation? Active transportation is the use of human powered transportation to get places. Examples include biking or walking to work.Footnote 171 Public transit is also a form of active transportation as people walk to access public transit or to their destination at the end of their trip.Footnote 172-176

Active transportation can contribute to people’s daily physical activity.Footnote 178 Not many people currently use active transportation.Footnote 167 At a population level, active transportation has good potential to increase people’s activity levels and improve their health.Footnote 168 It is one way to

  • Address people’s lack of time to be physically active.
  • Reduce the amount of time Canadians spend driving.
  • Help people reach recommended levels of physical activity.

The built environment can play an important role in active transportation. Generally, areas with higher population density, a mix of residential, commercial, educational and employment areas, connected streets, good access to destinations, good public transit and attractiveness have been linked to more active transportation or reduced driving, although the strength of this link is unclear.Footnote 179-187 In Canada, active transportation has been linked to havingFootnote 179,Footnote 188,Footnote 189-192

  • A public transit stop nearby.
  • A choice of destinations within a reasonable distance.
  • Well-maintained sidewalks.
  • Dedicated areas for cycling.
  • Affordable recreation facilities.
  • Safe traffic.

For cycling, examples of features that have been linked to active transportation include bike paths close to where people live; bike paths that provide access to a variety of destinations in a short distance; good connections between roads and routes; safe cycling routes; safe places to park bikes, including near railway or bus stations; available short-term bike rentals; signals and traffic lights for cyclists; and routes with fewer hills and safer traffic. Footnote 49,Footnote 169,Footnote 177,Footnote 193-205

Examples of initiatives on active transportation in Canada can be found here: Public Health Agency of Canada.

Did you know? In 2011Footnote 188

  • 62% of Canadians said there were stores within walking distance of their home.
  • 78% had free or low-cost recreational facilities and areas nearby.
  • 72% had a transit stop within a 15 minute walk of their home.
  • 70% said they lived in an attractive neighbourhood.

Canadians were more likely to be active if their neighbourhoods had places to walk to (e.g., stores), free or low cost recreational facilities or areas specifically for cycling, good sidewalks, interesting features and a higher level of safety.Footnote 188

There are other factors to consider in terms of active transportation. For example, providing employment opportunities closer to where people live and making driving a less appealing choice than active transportation.Footnote 180,Footnote 181,Footnote 200 Examples of strategies that have led to less traffic on the roads include car free zones or days, increasing the cost of driving and free or low cost public transit.Footnote 209-216 Places like Canada where residents can have long distances to travel and rely heavily on motor vehicles may have difficulty implementing some of these strategies.

Promoting recreational physical activity: Physical activity during leisure time is not always linked to the same neighbourhood features as active transportation.Footnote 166,Footnote 191,Footnote 217 Some evidence also suggests that people who live in walkable neighbourhoods and are more likely to use active transportation may be less likely to be active during their leisure time.Footnote 185,Footnote 190

Recreational walking is linked to neighbourhood features such as destinations (e.g., lakes, waterways, sports and cultural destinations), attractiveness, good street lighting, good sidewalks, paths and trails, nearby recreational areas and facilities and green space.Footnote 54,Footnote 217-223 Canadians who live in neighbourhoods with these features were more likely to be active during their leisure time. Traffic and safety can also influence leisure time activity.Footnote 188

A role for raising awareness: Believing that a neighbourhood is walkable, whether or not it actually is, is linked to more walking and better health.Footnote 206-208 This suggests that raising awareness about a neighbourhood’s walkability could be an important way to increase physical activity.

Mediating factors affecting the link between the built environment, physical activity and health

The built environment can impact people’s physical activity and their health. However, there are factors that can affect this link and that should be considered when designing communities. Examples that are relevant in Canada include traffic safety, air pollution, weather, climate and daylight.

Population density: Estimates from the United States suggest that neighbourhoods with a population density of around 360 to 1540 people per km2 are linked to more walking. Less time driving is linked to neighbourhoods with a population density of 1160 people per km2 or more.Footnote 229 In 2016, there were 32 urban areas in Canada with a population density of at least 360 people per km2 and one with a population density of at least 1160 people. About 43% of Canada’s population lived in these urban areas.Footnote 230 Within Canadian urban areas, population density differs across neighbourhoods with those closest to the city’s centre often being most dense (e.g., TorontoFootnote 231) .

Traffic safety: Evidence suggests that the health benefits of walking or cycling are greater than the risk for injury from traffic.Footnote 232 People are more likely to choose active travel when they feel it is a safe alternative. There are many ways to build infrastructure to make roads safer for motor vehicles, pedestrians and cyclists. Effective approaches to influence traffic safety involve reducing speed (e.g., speed bumps, speed limits, narrowing lanes), decreasing points of conflict with pedestrians and cyclists, increasing visibility of pedestrians (e.g., curb extensions) and diverting traffic away from residential areas.Footnote 45,Footnote 56,Footnote 233,Footnote 234

Pedestrian safety can also be increased through pedestrian signals, traffic lights, signs to remind pedestrians to look for vehicles, pedestrian islands, overpasses, underpasses, barriers, fences, sidewalks and good streetlights.Footnote 236,Footnote 237 Collisions between pedestrians and vehicles are more likely to occur near schools and in commercial areas and are linked to higher population density, traffic volume, pedestrian volume, road density and number of intersections.Footnote 237Canadian research has shown that people will choose to walk or bike if their route is safe and attractive. Some evidence suggests that cyclists will pick a safer, more attractive route over a shorter, more direct route.Footnote 232,Footnote 238-242

Cycling safety can influence the likelihood that people will use their bikes. People cycle more when they feel safe and dedicated infrastructure for cycling is available. This may be particularly important for those who are less confident on a bicycle.Footnote 55,Footnote 243 Approaches such as having dedicated cycling routes, paths and lanes, reducing speed limits for motor vehicles, having places to cycle to, having access to public transit and having good street connectivity have been linked to more cycling. More traffic, highways and congestion are linked to less active travel, including less cycling. Some approaches for reducing the number of motor vehicles on the road, such as increasing costs of motor vehicle ownership, limiting parking and car-free areas might also help increase walking and cycling.Footnote 243

Cycling – global comparisons: Cycling on a regular basis is popular in several European countries, particularly the Netherlands, Denmark, Germany, Finland, Sweden and Belgium. Cycling is also safer in these countries.Footnote 224 It is supported through widespread dedicated cycling infrastructure, traffic calming in residential neighbourhoods, bike parking, integration with public transit, traffic education for both drivers and cyclists and events that promote cycling and increase public support. In these cities, mixed land use and high population density ensures there are many places that are accessible by bike. Owning a car is also expensive, and driving to get places is challenging, although some countries like the Netherlands and Germany have high levels of car ownership and cycling.Footnote 200,Footnote 225

Cycling on a regular basis is not nearly as popular in North America. In 2013/2014, about 12 million or 41% of Canadians said they had cycled at least once in the previous year. Younger Canadians were more likely to use their bikes than older Canadians, and men were more likely to use their bikes than women. Men living in urban areas were more likely to cycle than men in rural areas; however, the opposite pattern was seen for women. Canadians are less likely to ride their bikes than in the past, a trend that is likely not due to the aging population. It may be at least partially due to increases in other activities such as running.Footnote 226

Canadians are more likely to use their bikes than Americans. This difference is thought to be due to a more supportive built environment for cycling in Canada (e.g., mixed land use, short distances to destinations, higher costs of driving, safer cycling, more dedicated cycling infrastructure and training related to cycling).Footnote 227,Footnote 228

Air pollution: Being active (e.g., running, cycling) in high traffic areas can increase the risk for exposure to air pollution.Footnote 244 Exercise may increase the amount of pollution that enters the lungs. Air pollutants can irritate the lungs, changing breathing patterns and heart rate during exercise.Footnote 247Particulate matter can increase blood pressure and heart rate as well as activate the immune system.Footnote 248In Canada, this is less of an issue than in other countries because generally, Canada’s air quality is relatively good.Footnote 245,Footnote 246

Did you know? In 2014,90% of people worldwide were living in places where air quality did not meet the World Health Organization’s air quality guidelines (for fine particulate matter).Footnote 263 As a whole, Canada’s air quality meets these standards, although air quality does vary across the country.Footnote 263,Footnote 264

What are the risks? Footnote 168,Footnote 249-254

  • There are more health benefits from exercise than there are health impacts from exposure to air pollution, except in areas with high levels of air pollution.
  • There are many harmful pollutants inside motor vehicles, sometimes at levels that are higher than outside the vehicle.

People can reduce their exposure to air pollution while being active outside by using roads that are less busy or paths and trails without motor vehicle traffic as well as by avoiding exercise or exercising less intensely on days when air quality is poor.Footnote 271,Footnote 272 

Information on daily air quality in Canada can be found at the Air Quality Health Index.

Exposure to air pollution is linked to an increased risk forFootnote 254-270

  • Premature death from diseases and conditions such as heart disease, stroke, respiratory disease, lung cancer, diabetes, and respiratory infections in children.
  • Poor respiratory and cardiovascular health even at low levels of exposure, especially among people at greater risk, such as those with asthma and other lung conditions, children and older adults.
  • Living with respiratory disease, asthma, pneumonia and otitis media in children, sudden infant death syndrome, adverse birth outcomes (particularly in mothers with pre-existing medical conditions), atherosclerosis, hypertension, diabetes and neurological conditions such as dementia.

Weather, climate and daylight: It is no surprise that bad weather, unsafe conditions due to weather, extreme temperatures and lack of daylight all reduce the likelihood that people will be active outdoors.Footnote 273-292 Even in Nordic countries like Finland where many people use active transportation, the proportion of those who do so in the winter is lower than in warmer months.Footnote 293

This is an important consideration in Canada due to our diverse climate. However, it also provides an opportunity for innovation in the built environment to support physical activity across seasons and different types of weather. For example, suggestions to increase physical activity in colder months include having better access to more and better indoor recreation facilities (e.g., swimming pools, gyms) and promoting facilities for outdoor winter recreation (e.g., skating, snowshoeing, skiing).Footnote 281 Well-lit neighbourhoods and access to indoor recreation facilities could also encourage physical activity during periods of shorter daylight.Footnote 291-295

3B: Access to healthy food

This section explores research that relates to how we can design communities that promote healthy eating.

A healthy diet is a key component of good health and involves eating healthy food and avoiding unhealthy food. What we choose to eat is influenced by many factors, including what food is available and accessible in our communities and beyond. Figure 4 shows how the complexity of neighbourhood features is likely linked to better health through healthy diets.

Figure 4: Overview of how the built environment influences diets to influence health. (adapted fromFootnote 72)

Figure  4: Overview of how the built environment influences diets to influence health. (Adapted from reference 72)
Figure 4 - Text Equivalent

This image depicts how the built environment may lead to various health outcomes based on promoting healthy diets and the influence of various mediating factors and other determinants of health. Examples of features in the built environment that may lead to healthy diets include: living close to healthy food sources, such as supermarkets; living farther away from unhealthy food sources, such as convenience stores and fast food outlets; and zoning of unhealthy food sources, farmers' markets and community gardens. Examples of possible health outcomes include reduced risk for premature death, obesity, diabetes and poor mental health. These complex interactions between the built environment and mediating factors that lead to human responses and health outcomes are all influenced by other determinants of health, such as age, genetics, gender, social environment, income, education, culture and the health care system.

Did you know? Many Canadians do not consume a healthy diet.Footnote 296 Canadian diets have been changing – the percent of daily energy intake from carbohydrates has been decreasing for Canadian adults while the intake of fat and protein has increased from 2004 to 2015.Footnote 297 Sugars account for just over 20% of Canadians’ total intake.Footnote 298,Footnote 299 Many Canadians do not meet recommendations for vitamin and mineral intake.Footnote 297

Diet and health

There is little doubt that a healthy diet is linked to better health. Generally speaking, there are certain foods that are considered to be healthy and that together, form a balanced, healthy diet. Examples include vegetables, fruit, grain products, low fat milk, fish and lean meat as well as traditional or country food for Indigenous populations. A balanced, healthy diet also involves eating regularly, consuming appropriate portions and minimizing how much food we eat that is high in saturated fat, sugar and salt.Footnote 300

Access to healthy food at work: Many people spend most of their waking day at work. Some evidence suggests that bringing food to work from home is linked to a healthier diet than buying food at work or near work.Footnote 301 Access to healthier food choices at or near work has also been linked to a healthier diet, but not necessarily to weight loss.Footnote 302-304 Workers in rural areas may face limited food choices.Footnote 305

There are many factors that influence what people choose to eat. Currently, many places that sell food offer a wide variety of choices that includes food that is high in calories, fat, sodium and sugar. This can create challenges for healthy eating. Information about food and nutrition is constantly evolving, often presenting conflicting messages about what to eat and what to avoid.Footnote 306 What constitutes a healthy diet and identifying how it contributes to better health can vary across individuals. People differ in how they digest and metabolize food, meaning not everyone reacts to food in the same way.Footnote 307,Footnote 308 Personalized diets are an emerging area of research that could lead to dietary advice that is based on individual differences.Footnote 309,Footnote 310

Building neighbourhoods that promote a healthy diet

We choose the food we eat based on many interconnected factors, including access to healthy food in our neighbourhoods. The built environment can play a role although results from research are mixed and sometimes conflicting.Footnote 311-313 Experts believe that current food environments are set up so that it is easy for people to eat unhealthy food.Footnote 314

Food or nutrition environments include a wide variety of factors that influence diet, such as government and industry policies, community environment (e.g., accessibility to and type and location of stores and restaurants), organizational environment (e.g., home, school, work, other), consumer environment (e.g., available food options, price, promotion, placement, nutrition information), media, advertising and individual characteristics (e.g., socio-demographic characteristics, psychosocial factors, perceived nutrition environment).Footnote 324 The built environment is part of this overall picture with its main focus being access to healthy and unhealthy food. There are gaps in our knowledge about the role of the built environment in healthy diets in Canada, particularly in rural and remote communities.Footnote 325

Examples of mediating factors that influence food choicesFootnote 58,Footnote 102,Footnote 148,Footnote 306,Footnote 315-323

  • Food prices can have a bigger influence on diet and health than distance to a food source, particularly for low income families.
  • Many people do not always shop for food in their home neighbourhoods and have access to transportation so they can buy food elsewhere.
  • People tend to establish a routine and buy from the same stores most of the time.
  • Many stores sell both healthy and unhealthy food. Store hours can affect access to healthy food.
  • Access to healthy food differs across countries and municipalities. It can also differ across urban, suburban and rural areas.

Access to healthy and unhealthy food: Neighbourhoods that promote a healthy diet should aim to increase the availability and accessibility of healthy food for all residents. Affordability and food quality are also key factors.Footnote 325 Whether or not living near places that sell healthy and unhealthy food affects health is not clear. Some evidence suggests that when people have better access to sources of healthy food than they do to sources of unhealthy food, they are more likely to have healthier diets, are less likely to be obese and have a reduced risk for early death, but not all research has shown a link between access and health.Footnote 58,Footnote 316,Footnote 326-338 

Access to alcohol: Easy access to alcohol is linked to increased alcohol consumption and negative health impacts. For example, neighbourhoods that have a higher density of places that sell alcohol were more likely to have incidents of violent crime, including family violence and motor vehicle accidents.Footnote 91,Footnote 340-345 A higher density of liquor stores was also linked to lower prices for alcohol, problem drinking and bigger impacts on health (e.g., alcohol-related hospital admissions, mental health).Footnote 346-351

Access is also an important factor to consider for other drugs, including for the public health implications of the legalization of cannabis.

Food deserts and food swamps: Food deserts are areas with limited access to nutritious and affordable healthy foods. Some evidence has shown that there is a link between food deserts and poor health, although not all research has found this effect.Footnote 148,Footnote 315,Footnote 327,Footnote 338,Footnote 339Food swamps are areas with many unhealthy food options. Evidence suggests that there is a link between food swamps and poor health (e.g., unhealthy diets, higher BMI, obesity, diabetes).Footnote 323,Footnote 339,Footnote 352-361 

Food deserts and food swamps can co-exist in the same community. However, research suggests that in Canada and particularly in urban areas, food swamps are more common than food deserts.Footnote 362-364 Stores that sell food in rural areas can differ from stores that sell food in urban areas. Food deserts may be more common in rural areas.Footnote 320 Food deserts also tend to be common in remote communities, especially those without grocery stores.Footnote 325

Creating policies and legislation that restrict access to fast food by influencing where fast food restaurants are built and limiting unhealthy food sources (e.g., convenience stores) nears schools are approaches that have been considered to address unhealthy diets and obesity.Footnote 363-365 Zoning could also be used to support healthy diets (e.g., zoning that increases access to places that sell fruit and vegetables in rural communities).Footnote 363,Footnote 366

Farmers’ markets and community gardens: Cities and communities are using various approaches to bring healthy food options to their residents. Two examples include farmers’ markets and community gardens. Currently, our knowledge of their effectiveness is limited.

Farmers’ markets: To help provide their residents with better access to healthy food, some municipalities are supporting or considering farmers’ markets. Their impact appears to be localized, improving access to healthy food options for those who live nearby and in some cases, improving diets.Footnote 367-378 The variety of food is not always better at farmers’ markets than at supermarkets, and certain food can be more expensive.Footnote 379

Community gardens: Similar to farmers’ markets, community gardens are another approach being supported or considered. Some studies have found that community gardens have been linked to better diets, mental health and well-being, as well as lower BMI.Footnote 380-387  Community gardens tend to be found in areas with supermarkets, meaning people already have healthy food options available.Footnote 371 This can make it difficult to assess the impact of community gardens independently of supermarkets. Community gardens are also linked to community belonging and in some cases, social support.Footnote 388,Footnote 389

Mediating factors affecting the link between the built environment and diet

The impact of the characteristics of a particular neighbourhood on diet is often linked to access to healthy or unhealthy food. There are many factors that can influence or are related to food access, including seasons and food insecurity.

Seasons: Canada experiences distinct seasons and fluctuating growing seasons, with both affecting food growth and production as well as availability of traditional or country food. Although a wide variety of food is available all year for many areas in Canada due to food imports, the availability and price of fruit and vegetables in stores fluctuate across seasons.Footnote 390 Farmers markets and community gardens are also seasonal, providing fresh produce based on the growing season. Despite its short growing season, Canada produces a good amount of fruit and vegetables, and production has generally increased.Footnote 391,Footnote 392

Food insecurity: Access to food to form a healthy diet can be difficult for families experiencing food insecurity.Footnote 393 In 2014, about 12% of Canadian households were living with food insecurity at some point in the previous year. Not all provinces and territories collect information on food insecurity, so this is not a full estimate of the issue.Footnote 394

What is food security? Food security occurs when people can afford and have access to enough safe and nutritious food for a healthy diet and life. Lack of food security or food insecurity is linked to poor physical and mental health and wellness.Footnote 394,Footnote 395 

Food security does not appear to be strongly related to living close to stores that sell food or to community food programs.Footnote 396,Footnote 397 Some evidence suggests that food insecurity is lower in rural areas, particularly for those areas with many farms.Footnote 394,Footnote 396

Food insecurity and food prices are much higher in the territories. In 2014, Nunavut reported that almost 47% of households experienced food insecurity in the previous year, and the Northwest Territories reported just over 24%.Footnote 394 In Nunavut, food insecurity was higher in smaller communities than in the capital, Iqaluit.Footnote 398 Examples of approaches that may help address food insecurity in the North include food sharing networks, better access to country food and community greenhouses.Footnote 399,Footnote 400

3C: Supportive environments

This section explores research that relates to how we can build communities that promote mental wellness.

Mental wellness is a key component of daily well-being and a healthy life. Many factors play a role in the risk for poor mental health, including where we live, work, study and play. Figure 5 shows how the complexity of neighbourhood features is likely linked to better health through social support, reduced stress and community belonging.

Figure 5: Overview of how the built environment influences social support, stress and community belonging to influence health. (adapted fromFootnote 72)

Figure 5: Overview  of how the built environment influences social support, stress and community  belonging to influence health. (Adapted from reference  72)
Figure 5 - Text Equivalent

This image depicts how the built environment may lead to various health outcomes based on creating supportive environments and the influence of various mediating factors and other determinants of health. Examples of features in the built environment that may create supportive environments include high population density, houses close to the street, front porches, front gardens, front yards, green space, destinations nearby, public transit, places to gather, community facilities and services, paths, trails, sidewalks, public art and attractiveness. Examples of possible health outcomes include improved mental wellness and reduced risk for poor mental health, premature death, poor immune function and many chronic diseases and conditions. These complex interactions between the built environment and mediating factors that lead to human response and health outcomes are all influenced by other determinants of health, such as age, genetics, gender, social environment, income, education, culture and the health care system.

Social support, stress and health

Social support and low stress have been strongly linked to good health.

Social support: Social support can decrease the risk for premature death and poor health in the form of cardiovascular disease, stress, poor mental health and other health issues such as cancer and infectious disease, likely linked to factors such as impaired immune function or delayed access to health care.Footnote 401-403 Canadians with more family and friends were more likely to report being in very good or excellent physical and mental health at all ages.Footnote 404 It is thought that social support is linked to better health because it promotes healthy behaviours and helps people deal with difficult situations.Footnote 403

Social isolation and loneliness: Feeling socially isolated or lonely can increase the risk for premature death and poor health in the form of increased risk for depression, poor sleep, difficulties paying attention, impaired decision making, problem solving and memory, cognitive decline, poor cardiovascular function, poor immune function and stress.Footnote 406-409

Did you know? In 2013Footnote 404,Footnote 405

Friends and neighbours

  • 6% of Canadians said they had no close friends. This is higher for Canadians 75 years and older at 15%.
  • 75% of Canadians said they had three or more close friends, which is an increase from 70% in 2003. This is higher for Canadians ages 15 to 24 years at 88%.
  • About 40% of Canadians said they knew many or most of their neighbours.
  • 44% of Canadians see their friends at least a few times a week, which is lower than in 2003 at 56%.

Family

  • 55% of Canadians said they felt close to at least five family members.
  • 26% of Canadians see relatives at least a few times a week, which is lower than in 2003 at 38%.
  • 86% of Canadians with close ties to at least five relatives were satisfied with their lives compared to 75% with one or two close relatives and 69% with no close relatives.

Why do we feel lonely? Loneliness is often temporary and is thought to be a motivator for people to seek out social support.Footnote 407 When loneliness becomes a long-term situation, there are risks to health.Footnote 407,Footnote 417 Loneliness can happen at any age, but it is triggered by different factors across the lifespan.Footnote 417 Loneliness appears to be highest in adolescence when teenagers are seeking to establish their own identity and in old age when people begin losing loved ones and have poorer health.Footnote 417

Community belonging: In Canada, people who have a strong sense of community belonging are more likely to report having excellent or very good physical and mental health.Footnote 410,Footnote 411 In 2014, almost 19.4 million or 66% of Canadians age 12 years and older felt a very strong or somewhat strong sense of community belonging.Footnote 412

Stress: Chronic stress has a wide range of impacts on health, increasing the risk for early death and poor physical and mental health. e.g.,Footnote 413-416 In 2014, almost 6.7 million or 23% of Canadians over the age of 15 years said they had experienced quite a lot of life stress in the previous year.Footnote 412

Building neighbourhoods that promote mental wellness

Neighbourhoods can be built to increase social interactions and reduce stress.

Social interactions: Neighbourhoods can affect social interactions by increasing the probability of meeting others and by providing places to gather.Footnote 418,Footnote 419 Neighbourhoods that are linked to higher levels of neighbourliness, social capital (defined as social networks and interactions that increase trust and support among neighbours) or a sense of communityFootnote 419-433

  • Have houses close to the street and with front porches, front gardens or yards.
  • Have green spaces.
  • Are pedestrian friendly.
  • Have walkable destinations and accessible public transit.
  • Are clean.
  • Have low traffic and parking.
  • Have places where people gather (e.g., places of worship, local tavern, coffee shops, restaurants, parks, recreation areas and facilities, community centres, libraries).
  • Are places where people walk for leisure and people see each other out and about.
  • Create feelings of safety.

Areas with these features can have drawbacks that need to be considered when building communities for mental wellness. For example, neighbourhoods that are linked to higher levels of sense of community and social capital may not be affordable for everyone, may not be diverse or may not be what some people prefer.Footnote 435-440 Areas with many stores and restaurants may draw in people from other neighbourhoods, leading to a lower sense of community for residents.Footnote 419

Stress and poor mental health: Neighbourhood features and characteristics linked to an increase risk for stress and poor mental health includeFootnote 441-450

  • Hazards (e.g., uneven sidewalks, potholes in roads, debris)
  • Noise
  • Trash and litter
  • Poor quality housing
  • Lack of places to gather
  • Lack of services
  • Low walkability
  • Unattractiveness
  • Lack of access to green spaces and community facilities
  • Negative characteristics like abandoned buildings
  • Unsafe neighbourhoods.

Getting from home to work or school is a regular routine for many Canadians. In Canada, the majority of people work in the municipality in which they live. For example, 55% of commuters who live in Mississauga work in Mississauga and 81% of commuters who live in Toronto work in Toronto. A similar pattern can be seen in and near Montreal and Vancouver.Footnote 451

Long commute times can be a source of stress, particularly when commuters feel they lack control over conditions, traffic and time.Footnote 452-461 This can also result when travelling by public transit. Improvements in public transit infrastructure (e.g., fewer stops to reach destination) can reduce commuters’ stress in some situations.Footnote 454,Footnote 462-465 Some drivers enjoy their commute and find it is a good buffer between work and home.Footnote 466,Footnote 467 Over the long-term, stressful or long commutes have been linked to poor health in some situations but not others.Footnote 485,Footnote 500-502

Did you know? Commuting varies greatly across Canada,Footnote 451 likely due to factors such as differences in the infrastructure available for commuting, commuting distances and climate.

In 2011, over 15 million Canadians commuted to work. About 80% of these commuters used a private vehicle, while about 12% used public transit and 7% walked or biked.Footnote 451 In 2011, about 27% of Canadians said they had used active transport in the previous three months.Footnote 188

In 2011, Canadians who commuted to work spent about 25 minutes to travel from home to work. About 17% of Canadians spend at least 45 minutes commuting to work.Footnote 451

Taking public transit took longer on average than driving to work – Canadians who drove to work took about 24 minutes to do so while those who took the bus took 40 minutes, those who took the subway took 45 minutes and those who took light rail, a streetcar or commuter train took almost 53 minutes. For public transit, this includes the time to walk to public transit stops and waiting time.Footnote 451

Canadians who commuted by walking or cycling spent less time commuting – people who walked spent about 13 minutes commuting while those who cycled spent about 20 minutes.Footnote 451 This could be because people who choose to commute via active transportation live closer to work.

Mediating factors affecting the link between the built environment and mental wellness

Currently, experts do not agree on how to build crime-free or low crime communities, but safety is considered a key element of healthy communities.Footnote 500

Crime: Being a victim of a crime or a fear of crime can lead to long-lasting effects on mental health and wellness.Footnote 501-505 A fear of crime can lead people to change their behaviour as a response to their fears. This can lead to unhealthy outcomes like physical inactivity and mistrust.Footnote 502,Footnote 506,Footnote 507

Did you know? In 2014, 20% of Canadians over the age of 15 years said they had been victim of at least one crime (e.g., assault, robbery, breaking and entering, theft of personal property, vandalism) in the previous year.Footnote 509

Understanding local crime patterns and neighbourhood features that may promote crime appears to be important for reducing crime.Footnote 508 Two examples of promising strategies that look at the built environment to prevent crime are

  • Crime Prevention through Environmental Design (CPTED): Supported by the United Nations and countries across the world, CPTED aims to decrease crime by reducing opportunity. It supports clear identification of public and private areas (e.g., through signs and fences), removing litter and graffiti, reducing unused or underused spaces, improving surveillance (e.g., improve visibility, strategic placement of windows, good street lighting) and controlling access.Footnote 510
  • Situational Crime Prevention (SCP): This approachaims to understand where, why and when crime happens in a neighbourhood and to reduce opportunities for crime by increasing its risks and decreasing its rewards. This involves tailored solutions that can include changing neighbourhood features to reduce crime.Footnote 508,Footnote 511

Evidence suggests that these approaches are effective in some situations, but may address only the symptoms of crime and not its causes. In some situations, they may potentially increase or displace crime.Footnote 508,Footnote 510,Footnote 512-518 There is some evidence that neighbourhood interventions may reduce fear of crime. Reducing physical disorder (e.g., litter, graffiti, vandalism) and improving the maintenance of properties and public areas appear to increase feelings of safety to some extent.Footnote 519

Improving mental wellness: Research on how to harness the built environment to improve mental wellness is limited and weak but growing. Examples of approaches that could be targeted include

Increasing green spaces: Looking at the impact of green spaces on health is a relatively new area of research. Green spaces have been linked to better mental and physical healthFootnote 44,Footnote 51,Footnote 52,Footnote 468-481 It is thought that their availability may lead to better health through increased physical activity, less exposure to air pollution, more social interactions and/or feeling less stressed.Footnote 471,Footnote 482,Footnote 483 How green spaces are linked to mental wellness may change across the lifespan and differ by gender.Footnote 470,Footnote 484

Reducing noise: Noise in our neighbourhoods can come from sources such as motor vehicles, airplanes, trains, industrial areas, construction and noisy neighbours. The World Health Organization estimates that among environmental factors that influence health, noise pollution is second to air pollution in terms of its impacts in Europe.Footnote 485 Living in a noisy neighbourhood has been linked to an increased risk for health issues such asFootnote 486-491

  • Hearing loss.
  • Stress as well as poorer quality of life, mental health and sleep.
  • Hypertension, cardiovascular disease, diabetes and respiratory disease.
  • Poorer memory and reading skills in children.

Creating public art: The attractiveness of a space can affect how people feel, think and behave. For example, art in public places has been shown to have a calming effect.Footnote 492-494 Art can reflect culture and also build social and community connections.Footnote 495 Some evidence suggests that art projects that involve a community can improve the health and well-being of its residents as well as build a better sense of community.Footnote 496-499

Section 4: Design features for specific populations

This section explores how design features of the built environment impact healthy living in children, youth and older adults as well as their role in health inequities.

Most research on the impact of the built environment on healthy living, and health in general has focused on adults. Research on children, youth, older adults and marginalized groups is limited despite known health risks and inequities for these groups. There is also limited research on how the built environment may affect gender differently. Some research suggests that there may be gender differences, but results are mixed and overall conclusions remain elusive.Footnote 520

Children and Youth

Physical activity: In 2014, Canadian data showed that 31% of boys and 22% of girls in Grade 6 were physically active every day for at least 60 minutes. This dropped to 22% of boys and 10% of girls by Grade 10. Students in Grades 6 to 10 are more likely to participate in team sports than individual sports.Footnote 521 It appears that a greater proportion of Canadian students in Grades 6 to 10 are spending more of their leisure time playing video games and on the computer than in the past.Footnote 521,Footnote 522

The presence of parks and green spaces may play an important role in increasing physical activity in children in urban areas, although some evidence shows that neighbourhoods with destinations, such as recreation facilities, parks, playgrounds and features linked to walking are associated with lower levels of physical activity in children.Footnote 523,Footnote 524 A key factor for physical activity may be the availability of undeveloped areas that allow for unstructured play.Footnote 525

The need for challenging play: Challenging play is important for children’s development as well as their physical and mental health. This type of play encourages children to evaluate their environment and its challenges before taking action. It has also been linked to helping children learn about assessing and managing risks, to be more independent and to develop better learning and judgment skills.Footnote 526 Footnote 527

Living in suburbs or small towns was linked to the highest levels of physical activity in children while living in urban areas was linked to the lowest. Children living in rural areas were more likely to spend time outdoors and in unstructured play than children living in urban areas.Footnote 528 This may be linked to how safe rural neighbourhoods, in terms of both traffic and crime, are perceived to be.

Parents’ concerns about safety are linked to their willingness to allow their children be active outside.Footnote 529-534 Like other age groups, children who walk or cycle are more likely to get injured than children who travel in a motor vehicle.Footnote 535 Measures to increase safety such as traffic calming and having recreation areas nearby were linked to more physical activity and fewer injuries among children. Features such as higher road density, having schools and other services nearby and crosswalks were linked to more walking, but not increased safety.Footnote 536-539 Crime is also an issue. Children living in neighbourhoods with less crime are more likely to be physically active.Footnote 540

Walking, cycling or using public transit to get to school can increase children’s and teenagers’ physical activity levels, yet many Canadian students are not using active transportation.Footnote 541-544 It appears that using active transportation in Canada is decreasing. Among students in Grades 6 to 10, rates appear to be decreasing, particularly in lower grades (see Table 1).Footnote 521,Footnote 522A survey of Canadian parents in 2012 showed that 58% walked to school as children while 28% of their own children walk to school today.Footnote 545

Table 1: Proportion of Canadian students using active transportation in 2011 and 2014Footnote 521,Footnote 522

 

Grade 6

Grade 7

Grade 8

Grade 9

Grade 10

2014

Boys

31%

25%

27%

28%

26%

Girls

29%

25%

26%

24%

19%

2011

Boys

41%

36%

39%

27%

31%

Girls

36%

32%

36%

25%

22%

Distance and safety are two key factors - children are more likely to use active transportation if their school is nearby and the route to get there is safe.Footnote 546-556 They are also more likely to use active transportation in areas experiencing urban sprawl.Footnote 557 Parents are important role models for their children in terms of physical activity. For example, for every 20 minutes of activity a parent did on weekends or during evenings, their children’s activity increased by five to ten minutes.Footnote 558 Children whose parents use active transportation are also more likely to do so.Footnote 559,Footnote 560

Healthy diets: Research in this area is still evolving, but generally, access to healthy or unhealthy food has the same effect on children and teenagers as it does on adults.Footnote 561 One aspect that differs is the fact that children and teenagers can also be influenced by food access near schools or on route to school. Recent findings suggest that children and teenagers who live or go to school in neighbourhoods with many places that sell unhealthy food are more likely to have an unhealthy diet and be overweight, be obese, have higher insulin resistance and have poor bone density.Footnote 561-565

Mental wellness: Green spaces may have a positive influence on children’s brain, behavioural and physical development.Footnote 566-571 In Canada, children who spend more time outdoors are more likely to be physically active, have fewer problems with their friends and have better psychosocial health.Footnote 571

Physical activity, healthy eating and pregnant/postpartum women: There is a lack of research on the role of the built environment on the health of pregnant and postpartum women. However, they may benefit from a neighbourhood that encourages physical activity and healthy eating. Evidence suggests that healthy diets and physical activity are important for appropriate weight gain during pregnancy, although they may have no effect on issues such as preeclampsia, gestational diabetes and induction of labour.Footnote 572,Footnote 573 Weight gain during pregnancy is also linked to a child’s health, including the risk of high birth weight and being overweight in childhood.Footnote 574-576

Research is mixed, but some evidence suggests that exercise and healthy diets in the postpartum period are linked to weight loss and improvement in postpartum depression symptoms.Footnote 577-581 Many women have trouble losing weight during the postpartum period, suggesting a need for specific interventions for this group.Footnote 582,Footnote 583

Older adults

Communities are not always built to support aging. Most older adults want to stay in their homes and neighbourhoods as they get older. As they age, older adults are also more likely to spend more time in their neighbourhoods and to be more sensitive to changes in their environment.Footnote 584 Canada’s population is aging.Footnote 11 Ensuring that the built environment supports healthy aging is becoming increasingly important.

Older adults and falls: In Canada, about 20% to 30% of older adults fall every year. Falls are also the leading cause of hospitalization among older Canadians.Footnote 608,Footnote 609

Older adults who felt that they were part of their community and that people would help them were less likely to experience falls. Neighbourhoods that were thought to be cleaner and safer were linked to fewer falls.Footnote 610

Outdoor hazards increase the risk or the perceived risk for falls among older adults. Examples include uneven surfaces, curbs, lack of street, sidewalk and path maintenance, poor lighting, potholes, cluttered areas, unsafe traffic, unclear signs and crossings that are perceived to be unsafe.611,612

Physical activity: Even older adults who are already in poor health can benefit from being active.Footnote 585,Footnote 586 Many neighbourhood features (e.g., attractiveness, living near stores, services or friends) that are linked to more utilitarian walking in other age groups are also linked to more utilitarian walking in older adults, although research is mixed and likely influenced by other factors like mobility, income and attitudes.Footnote 587-607 Some research suggests that walkable neighbourhoods are linked to more walking even among older adults with mobility issues.Footnote 605

Some of the biggest barriers to being active for older adults include how accessible and safe their neighbourhood is (e.g., access to services, public transit, safety of sidewalks, weather, noise, lighting, street curbs, attractiveness, challenging street crossings due to short traffic lights or wide streets, proximity to destinations).Footnote 588,Footnote 611,Footnote 613,Footnote 614 Living in the suburbs is linked to many of these factors and can create a challenging situation for older adults, particularly for those who no longer drive. Concerns about safety include worries about crowds, crime, violence and traffic.Footnote 615

For older adults who have health and mobility issues, having benches in neighbourhoods is important. They function as rest stops during longer trips and can be good places for older adults to better enjoy green spaces and areas near water.Footnote 616

Social isolation: Neighbourhoods may not be set up to address the risk for social isolation associated with aging. Loneliness is an important public health issue for Canada’s aging population. Risk factors for being lonely at an older age include not being married, being in poor health, having a declining income and having a low education.Footnote 617 Limited research has addressed how the built environment can support social interactions and reduce social isolation for older adults.Footnote 618 Walkable neighbourhoods and physical activity itself are linked to increased activity and being more social in older adults.Footnote 614,Footnote 618

Populations experiencing health inequity

Building a healthy community addresses the needs and improves the health of all of its residents, including those who are marginalized.Footnote 1 Access to food, clean water and housing are basic needs. It makes sense that some approaches to improve healthy living, such as building more recreational areas or cycling infrastructure, may not have a positive impact on community health before these basic needs are met.

Accessibility for people living with a disability: The needs of people living with a disability are not always considered when designing and building communities.Footnote 619-622 In 2012, 3.8 million or 14% of Canadians 15 years and older reported living with a disability that limited their daily activities.Footnote 623

Evidence suggests that neighbourhoods with good accessibility, high quality and safe streets, lower traffic density as well as uncrowded and open spaces increase the likelihood that people with a disability can be mobile, productive and social.Footnote 613,Footnote 621,Footnote 622,Footnote 624-626 Winter can further reduce accessibility for people living with a physical disability, leading to increased risks to health and for being isolated.Footnote 620,Footnote 627-630

Certain features can worsen health inequity, particularly in disadvantaged neighbourhoods. Examples of these features includeFootnote 631,Footnote 632

  • Lack of transportation options
  • Limited access to healthy food, housing and health care
  • Lack of parks and recreation facilities
  • Empty buildings and vacant lots
  • Poor air or water quality
  • Lack of safety, higher crime
  • Increased social isolation
  • Residential segregation

Affordability is an important factor that influences where people decide to live. For those living with a low income, access to affordable housing is linked to better health and more income being available to support health and well-being.Footnote 633-639

Gentrification: Gentrification is the transformation of areas into middle class or affluent neighbourhoods. There is limited evidence and some debate about whether or not gentrification benefits or harms a neighbourhood’s original residents, particularly those with a low income.Footnote 640,Footnote 641

Limited research is available on the role of the built environment for Indigenous populations, people living in poverty, the homeless and people with a disability, and no evident research is available on people who identify as lesbian, gay, bisexual, transgendered, queer, questioning, intersex and two-spirited (LGBTQQI2S).

Indigenous communities: About 50% of Canada’s Indigenous population live in an urban area, a proportion that has grown over time. About 34% of the urban Indigenous population live in Winnipeg, Edmonton, Vancouver, Calgary and Toronto.Footnote 642 Whether Indigenous Peoples live in an urban, rural or remote area varies by Indigenous population:

  • In 2006, about 70% of Metis lived in an urban area.Footnote 643
  • In 2006, about 40% of First Nations lived on-reserve while 60% lived off reserve. Among those who lived off reserve, 47% lived in major urban centres, 31% lived in smaller urban areas and 21% lived in rural areas.Footnote 644
  • In 2011, about 75% of Inuit lived in four northern regions that span the Territories and Labrador.Footnote 645

For First Nations and Inuit populations, particularly those living in remote and isolated communities, there are challenges and opportunities for harnessing the built environment to support healthy living. Challenges can include lack of infrastructure and jurisdictional barriers. From a built environment perspective, some of the more pressing health concerns for remote Indigenous communities are related to safe drinking water, food availability, security and safety, access to health care and housing quality, affordability, accessibility and crowding.Footnote 646-653

Like Canada as a whole, Indigenous populations are also dealing with a shift to sedentary lifestyles, physical inactivity, unhealthy diets and resulting impacts on health.Footnote 653,Footnote 654 This is linked to a shift from traditional built environments. Traditionally, Indigenous communities and camps were designed and located with purpose and to address community needs, well-being and geographic realities. In some cases, communities were temporary and moved in response to changes in season and food availability. With colonization and assimilation, communities were displaced and relocated, often away from traditional lands and practices.Footnote 83

For healthy living, there is limited research on the impact of the built environment on Indigenous communities.Footnote 83 Examples of barriers to physical activity that have been identified include isolation, an environment that does not make being physical active easy (e.g., weather, hazardous roads, safety, aggressive animals) and a lack of time, opportunities, support, programs, facilities and equipment.Footnote 83,Footnote 654-657

There are also opportunities to learn from Indigenous populations. Ties to the land, water, family, community and identity are important components of Indigenous culture that also emphasizes wholeness, connectedness and balance.Footnote 653,Footnote 658 For Indigenous communities, place is an important source of health and is seen as part of a holistic, interconnected view of health and well-being. 658 Many Indigenous communities have developed or are interested in developing land-based programs to support improved wellness outcomes.

Section 5: Designing Canadian communities for healthy living

This section provides a brief overview of some of the approaches that are used to design communities in Canada to improve healthy living. Communities that effectively support, promote and inspire healthy living take a collaborative, multidisciplinary effort that includes expertise not traditionally linked to health, such as economics and transportation. They involve all levels of government and engage at the community level.Footnote 659

Multi-sectoral collaboration: Currently, public health professionals are working closely with urban planners, traffic engineers, architects and policy makers at all levels across Canada to varying degrees. Building these relationships is seen as a particularly important step for moving initiatives forward.Footnote 659

Health in All Policies is an important approach that encourages decision makers across all sectors to consider the health implications of public policies.Footnote 67-69 This has been noted as an important approach for planning, development and equity. 1,2 For public health, designing healthy communities is truly a population health approach. It involves finding a balance to

  • Improve the health of all Canadians and reduce health inequities.
  • Prevent unhealthy behaviours and poor physical and mental health.
  • Consider the influence of the social determinants of health.

Much of what drives this work happens at the local level; however, provincial, territorial and federal laws, regulations and policies can have an impact. Examples include investments in various sectors such as public transportation and the establishment of policies for municipal planning.

Tackling urban sprawl: While some cities are working to proactively address or prevent urban sprawl, the response to urban sprawl is often reactive happening once its effects are already being felt. Urban sprawl is often characterized as living in the suburbs. Although suburbs are linked to unhealthy behavioursFootnote 27-32, they often provide attractive options at affordable prices for some Canadians. Many Canadians want to live in the suburbs and enjoy doing so.Footnote 65,Footnote 66 This suggests that there is a need for innovative thinking to tackle the unhealthy aspects of suburban living.

Examples of proactive approaches can be found in Ontario and Metro Vancouver where growth plans have been developed to address urban sprawl. In southern Ontario, this included establishing density targets for development and protection of green spaces. The goals of the Metro Vancouver plan include

  • Having its population concentrated in compact communities with access to a range of housing choices, employment, amenities and services.
  • Protecting industrial and agricultural land.
  • Protecting natural areas for clean air, water and food as well as diverse recreational activities.
  • Developing complete communities with a range of housing choices, good distribution of employment, access to services and amenities and support for walking, cycling and public transit to foster healthy lifestyles.
  • Having a compact, transit-oriented urban setting that supports a range of sustainable transportation choices.

Examples of Canadian guidelines and other resources: There are many guidelines on promising practices for building healthy communities. Below are some examples

Local planning

All cities in Canada have plans, policies and laws in place to guide the design and building of their communities. Active transportation is now the most addressed issue by planners, followed by access to public spaces, social networks and meeting areas. Lack of government or political support is the most often cited barrier for making sure planning considers health implications.Footnote 660

The built environment is something that can be tangibly changed. It is important for understanding population-level physical barriers and incentives for making healthy choices. e.g.,Footnote 72  To help people maximize health benefits from their built environment, public health can support the evaluation of initiatives or approaches to determine what works and what does not, and in what settings. It can also maximize the effectiveness of the built environment through policies and programs focused on designing healthy living. Improving health should be a goal of all community planning.

The story of Portland: Portland, Oregon is often used as an example of a city that changed its built environment and improved its citizens’ health by containing urban sprawl. Since 1979, the city has put in place many approaches

  • Limiting development outside of its urban boundaries.
  • Keeping its population closer to the city’s centre in dense, mixed-use neighbourhoods.
  • Developing a well-connected light rail system that services many areas of the city.

Mortality rates decreased from almost 9,000 per million people per year in 1989-1994 to almost 8,000 per million people per year in 1995-2000. This change has been linked to the city’s approach to containing urban sprawl.Footnote 72

Examples from Canada’s three largest cities
Many of Canada’s larger cities have initiatives in place to help design and build communities that promote healthy living. Vancouver, Toronto and Montreal are used below as examples of multi-sectoral planning at a large scale for large populations. It should be noted that multi-sectoral community planning is happening in many areas, including planning that covers the suburbs and smaller communities. What works in larger cities may not work for the suburbs, smaller cities and communities or rural or remote communities.

The shift to a focus on the impact of the built environment on healthy living has taken time. Making widespread changes is difficult and often starts as smaller changes at the community level. Evidence is important, but so is context. Evidence needs to match a community’s needs, situation and characteristics to be considered relevant. This makes local knowledge and community engagement important. Seeing the effects of change also takes time, particularly on the health of a population. Together, these challenges show that harnessing the built environment to improve health is no easy task.Footnote 661

Vancouver
Population in 2016: 2.5 million

For many years, the City of Vancouver has focused on developing a sustainable city and on improving the health and well-being of its residents through policies, planning and related initiatives. In 2006, the Vancouver Coastal Health Authority implemented a collaborative focus on the built environment. The Health Authority has worked closely with communities on their Official Community Plans to ensure that the built environment is considered in their development.Footnote 661

Information on planning, zoning, development, community building and public health can be found at:

Healthy City Strategy: Vancouver’s Healthy City Strategy presents a long-term, integrated plan for healthier people, healthier places and a healthier planet. Champions from a range of sectors are guiding the adoption of the Strategy’s Healthy City for All vision.

Below are examples of the Strategy’s themes related to the built environment and healthy living.

Table 2: Examples of themes from Vancouver's Healthy City Strategy.

Theme

Goals and targets

Working towards goals and targets

Active living and getting outside

Goal: All residents are engaged in active living and have incomparable access to nature

Targets:

  • By 2020, all residents live within a five minute walk of a park.
  • By 2025, increase the rate of people meeting Canadian physical activity guidelines by 25% of 2014 levels.

Vancouver Board of Parks and Recreation Strategic Framework
Greenest City Action Plan
Transportation 2040 Plan
Parks, gardens, beaches
Recreational activities 

Getting around

Goal: Safe, active and accessible ways of getting around

Targets:

  • By 2020, make over 50% of trips by foot, bicycle and public transit.

Transportation 2040 Plan
Greenest City Action Plan

Environment to thrive in

Goal: Residents have the right to a healthy environment and equitable access to a livable environment in which they can thrive

Targets:

  • Add a biodiversity target and a target related to toxins prevention to the Greenest City Action Plan and increase neighbourhood Walk Scores.

Building community
Greenest City Action Plan
Climate Change Adaptation Strategy
Urban planning
Vancouver Economic Commission
VIVA Vancouver - creating vibrant pedestrian spaces 
Transportation 2040 Plan

Feeding ourselves well

Goal: A healthy, just and sustainable food system

Target:

  • By 2020, increase citywide and neighbourhood food assets (e.g., more opportunities to grow own food, local food market nearby, better access to affordable food) by a minimum of 50%.

Vancouver Food Strategy

Other city websites and resources:

Citizen engagement and involvement: In Vancouver, citizens can be involved in many aspects of city government and municipal affairs. The City promotes engagement through Talk Vancouver, an on-line forum and public consultations. They also hold open City Council meetings and provide opportunities for members of the public to speak at City Council meetings, for citizens to serve on boards and committees and for citizens to volunteer. They also use various means, including social media, to reach out to citizens.

More information on how to become involved can be found here: Citizen involvement.

Toronto
Population in 2016: 5.9 million

Toronto was one of the first cities to adopt the concept of Healthy Cities. This concept defines a healthy city as one that is continually working to enhance its environments and communities to improve its citizens’ health and well-being.Footnote 662,Footnote 663 Toronto Public Health has been heavily involved in the development of various plans and strategies and in working with other municipal sectors on the built environment.Footnote 661

Information on city planning and public health in Toronto can be found at:

Below are examples of innovative approaches, best practices, activities and projects taking place in Toronto to improve healthy living by focusing on the built environment.

Table 3: Examples of innovative approaches, best practices, activities and projects in Toronto.

Activities

Goals

Working towards goals and targets

Complete Streets Guidelines

Complete Streets involve the following components:

Streets for People

  • Improve safety and accessibility
  • Give people choices and connected networks
  • Promote healthy and active living

Streets as Placemaking

  • Respect local context
  • Create vibrant and attractive public spaces
  • Improve environmental sustainability

Streets for Prosperity

  • Support economic vitality
  • Enhance social equity
  • Be flexible and cost effective

Develop and implement guidelines
Recognized in Toronto’s Official Plan
Developed in consultation with many sectors and stakeholders

Examples of complete streets in Toronto:

  • College Street
  • Royal York Road
  • Front Street
  • Port Union
  • John Street
  • McNicol Avenue
  • Yorkville

Toronto Food Strategy

  • Support food friendly neighbourhoods
  • Make food a centrepiece of Toronto’s new green economy
  • Eliminate hunger in Toronto
  • Connect city and countryside through food
  • Empower residents with food skills and information
  • Urge federal and provincial governments to establish health-focused food policies

 

Examples of projects :

  • Grab Some Good markets
  • FoodReach
  • Food retail environmental mapping
  • Locally grown world crops

Parks, Forestry and Recreation Initiatives

Examples:

Transportation Initiatives

Examples:

Other city websites and resources:

Citizen engagement and involvement: Get Involved Toronto aims to create opportunities for Toronto’s residents to shape a vision for the City’s future, plan changes in its neighbourhoods, provide information and insight on issues being tackled by City Council and serve on boards, advisory groups or volunteer in other ways.

The City of Toronto holds Council and committee meetings that are open to the public, undertakes various public consultations and provides many engagement opportunities to its citizens. A recent pilot project asked citizens to propose and vote on projects to improve their neighbourhoods through the Participatory Budgeting Pilot Project.

Toronto also engages citizens through social media. The City’s chief planner has a blog to discuss and engage citizens on various planning projects and issues.

Montreal
Population in 2016: 4.1 million

Montreal has many initiatives and projects in place that address the built environment. For many years, the City has involved neighbourhoods and non-governmental organizations in addressing issues related to the built environment.Footnote 664 The Direction de santé publique de Montréal has also been involved in policy development and in supporting various projects on the built environment for the past 30 years. Since the early 2000s, it has focused on transportation and health.Footnote 661

Information on planning, health and public safety can be found at:

Urban plan (in French only): The city of Montreal’s urban plan was adopted in 2004 and significantly modified in early 2016.

Table 4: Examples of themes from Montreal's urban plan.

Theme

Goals

Supporting actions, principles and programs

Structuring efficient transportation networks to fully integrate into the urban fabric(in French only)

Goal: Consolidate and develop Montreal’s territory in relation to existing and planned transportation networks

Actions:

  • Facilitate travel between different areas of the City by establishing new public transportation services
  • Promote urban development that favours the use of public transportation
  • Strategically connect different areas of the City by completing the road network
  • Complete the City-wide bikeway network to provide access to activity areas and public transportation infrastructure
  • Promote urban development and the use of public transportation and bicycles by taking action on parking

Other:
The City of Montreal’s transport plan
Design of bicycle parking areas
The cycling action plan
Parking policy actions

An enhanced architectural, archaeological and natural heritage(in French only)

Goal: Preserve and enhance the built and archaeological heritage

Actions:

  • Preserve and enhance natural environments by ensuring their harmonious integration into urban development

Other:
Policy respecting the Protection and Enhancement of the Natural Environment

A healthy environment(in French only)

Goal:

  • Ensure the optimal management of resources in an urban context
  • Mitigate issues caused by urban activities
  • Control development in areas with environmental constraints

Actions:

  • Support healthier urban development
  • Reduce air pollutants and greenhouse gas emissions
  • Ensure efficient management of water and wastewater management infrastructure
  • Ensure the recovery and re-use of waste
  • Pursue the rehabilitation of contaminated sites with government funding
  • Give priority to rehabilitating contaminated sites in the vicinity of certain metro and commuter train stations, as well as in areas to be transformed
  • Control the impact of issues related to urban activities
  • Control construction in areas with environmental constraints

Other:
Strategic plan for sustainable development
Water management policy
Municipal waste management plan
Implementation of traffic calming measures
Noise mitigation policy

Other city websites and resources:

Citizen engagement and involvement: In Montreal, citizens can be involved in many aspects of city government and municipal affairs. The City undertakes consultations on various issues and holds open City Council meetings. They also use various means, including social media, to reach out to citizens.

More information on how to become involved can be found here: Democratic participation.

Community planning and Indigenous populations: Planning has always been a part of Indigenous communities and included many traditional and historical practices. Over time, these practices have been ignored, particularly in urban centres. However, there are examples that this is changing.

  • Today, there are a growing number of examples in Indigenous communities of community-based planning with strong participation, recognition of community needs, collaborative processes and inclusion of traditional knowledge.Footnote 83,Footnote 665-667
  • Indigenous communities have unique factors that need to be considered when undertaking community planning. Examples include Indigenous culture, traditional knowledge, colonization, residential schools, self-determination, language and geography.Footnote 668
  • The federal government supports communities in collaboration with community members for planning that takes place on-reserve.Footnote 83
  • Some planners, municipalities and communities in Canada have strengthened relationships with urban Indigenous populations. Examples of promising practices include involving First Nations, tribal or band councils in decision making and strategic planning as well as recognizing Indigenous history and heritage in planning projects.Footnote 665-667
  • Tools are available that aim to help build collaborative land use planning between First Nations and municipalities in urban settings. Relationship building is important. Treaties, First Nations laws and legal traditions as well as legislation and policies at all levels of government play a role in planning in First Nations reserves.Footnote 668-670

Perspectives from provinces and territories

Based on a survey of planners from Canadian provinces in 2013, strong provincial leadership through policies, legislation and regulations that recognizes the role of the built environment in health can greatly benefit municipalities and communities in planning, designing and building healthy communities. Currently, approaches, policies, regulations and legislation that consider health in the design and building of communities vary considerably across Canada.Footnote 671

Although different sectors do work together to develop healthy communities, the need for better collaboration has been noted at both the provincial and municipal level. Leaders from the health sector, academics and non-governmental organizations are seen as important supporters of healthy communities.Footnote 671

British Columbia, Ontario, Quebec and New Brunswick are provinces where strong healthy community networks exist. The principles that guide these networks include community engagement, political commitment, multi-sectoral collaborations, asset-based community development and healthy public policy. Important factors for this approach include recognizing the social determinants of health, diversity, social justice and equity, empowerment and community ownership, research and evaluation, and creativity and innovation.Footnote 672,Footnote 673 More details on these networks, including their governance and organizational profiles, can be found here and here.

In its Land Use and Sustainability Framework, the Government of the Northwest Territories has noted that “land is life” and has recognized the need to consider spiritual, cultural, physical, economic and social factors when managing lands, waters and natural resource. It also supports many initiatives that help develop healthy communities, including Community Wellness Initiatives and On the Land Healing programs.

Federal programs

The Public Health Agency of Canada (PHAC) supports work on the link between the built environment and healthy living through surveillance, research, knowledge mobilization, collaborations and funded interventions:

The Canadian Institutes of Health Research (CIHR) is supporting research on health and the built environment including $17.7 million for nine Intersectoral Prevention Research Grants that focus on healthier cities and communities.

Healthy Canada by Design
This initiative began in 2009 and was funded by the Canadian Partnership Against Cancer and Health Canada. Its aim was to move evidence into action and build collaborations that harness the built environment to improve health. Members of this initiative include the Urban Public Health Network, the Heart and Stroke Foundation, the Canadian Institute of Planners, the National Collaborating Centre for Healthy Public Policy, the Canadian Institute of Transportation Engineers and several universities.Footnote 62,Footnote 674,Footnote 675

About 163 government policies related to the built environment and increasing physical activity were influenced by the Healthy Canada by Design and the related Children’s Mobility, Health and Happiness projects.Footnote 659

International initiatives

Many countries are looking to the built environment to improve health. Covering all the examples that exist is outside the scope of this report. Outlined below are two examples of World Health Organization initiatives.

Healthy Cities: The concept of building a healthy city has a long history. As an international movement, it grew in part from an initial health city workshop held in Toronto in 1984 and aligns with the Ottawa Charter for Health Promotion. In 1986, the World Health Organization Healthy Cities project began with the involvement of representatives from 21 cities and seven countries in Europe.Footnote 60,Footnote 61 This project focuses on clean and safe environments, community connections, interaction and engagement, stable and sustainable ecosystems, meeting basic needs of all citizens, diverse, vital and innovative local economies and good health.Footnote 60,Footnote 61,Footnote 662 Today, there are approximately 30 national Healthy Cities networks with more than 1400 cities involved.Footnote 61,Footnote 676

In Canada, the healthy communities movement has developed on a different path with a broader approach that looks beyond urban areas and involves several separate networks rather than a pan-Canadian approach. Initiatives tend to be more local and built on existing community capacity. Across Canada, this has led to a wide variety of strategies that reflect individual community needs and have led to a broad range of results.Footnote 677

Age-Friendly Communities: In 2006, the World Health Organization started its Global Age-Friendly Cities project and in 2007, published a guide for developing age-friendly cities. Since that time, its Global Network for Age-friendly Cities and Communities has grown to include 287 communities in 33 countries with Canada being a key partner. This project focuses on eight areas for making communities age-friendly: outdoor spaces and buildings; transportation; housing; social participation; respect and social inclusion; civic participation and employment; communication and information; and community support and health services.Footnote 678,Footnote 679

In Canada, communities in all provinces are implementing age-friendly initiatives. PHAC recently developed a set of indicators to help communities evaluate the implementation of these initiatives, as did the World Health Organization.Footnote 679-681

Most work on age-friendly communities focuses on aging in urban areas, but there is a need to consider what age-friendly communities look like in rural settings.Footnote 682-685 In 2007, a report called Age-Friendly Rural and Remote Communities: A Guide was developed in Canada and endorsed by federal, provincial and territorial Ministers responsible for seniors. Its purpose was to raise awareness of the needs of older adults and to present a practical guide for rural and remote communities in Canada.

Moving research and evaluation into planning

Taking research that links a design feature to a health outcome, such as walkable communities and diabetes, and translating it into community action is challenging. Policies and programs need to be developed and implemented using the most relevant and up-to-date evidence, but they also need to be evaluated to determine their effectiveness.

Many projects and initiatives related to the built environment have taken place or are underway in Canada, but many are not evaluated or if they are, evaluation findings may not be accessible. In addition, cities and communities already collect data on various built environment initiatives, but data are not collected in a standardized way, limiting their use for researchers and planners in other communities. Systematically sharing data, knowledge and lessons learned about the effectiveness of initiatives is important to improve the health of Canadians in all communities.

Doing research that is policy and program relevant and engages stakeholders is a good step towards ensuring that community and neighbourhood planning is evidence-based.Footnote 686-688 This type of research can help create traction with decision-makers and help generate public awareness and community support.Footnote 689

Section 6: Call to action

We can do more to help Canadians take charge of their own health. We have an exciting opportunity to consciously design our communities to support healthy living and help Canadians unconsciously improve their own health and the health of generations to come.

Changing behaviour is complicated. Why people do what they do is based on a wide variety of connected factors. These include age, physical and mental health, socioeconomic status, culture, and genetics as well as how we react to our physical and social environments. The built environment is only one piece of this much larger puzzle.

Designing the built environment for healthy living is about supporting social connection and seamlessly providing access to features that promote physical activity, healthy eating and mental wellness. It can include simple things like connected streets, access to healthy food and places to gather with family and friends.

We know that communities are not all designed the same way and that they evolve over time. In addition, most of us spend our lives in many different neighbourhoods at any given time and across our lifespan. This makes it challenging to quantify how the built environment impacts health.

However, we know that where you live can matter. For example:

  • For someone with a life-threatening chronic disease, being closer to urgent care and specialized health services can be a key consideration for good health.
  • For young families, neighbourhood features that support challenging play, active transportation and parents’ opportunities to be healthy role models can provide the whole family with a foundation for healthy living.
  • Living in smaller communities can foster a strong sense of community belonging.

While many cities in Canada are already considering health in their community planning, there is much that remains to be explored. Research in this area is relatively young and moving findings into action is still a challenge. This means that we can be proactive and now is the time for public health to work closely with other sectors to take advantage of this growing domain.

Public health can influence the way forward and ensure that community planning and infrastructure initiatives, as well as sustainable, economic and technological development are based on integrated evidence and consider good health as a key outcome. Unravelling the complexity of the impact of the built environment on population health lies in precision public health, which uses data to guide interventions to benefit populations more effectively.

Six actions

Going forward, I call on domestic and international partners, all levels of government including municipal, provincial, and federal leaders, political decision makers, community planners and entrepreneurs to take action in the following six ways:

  1. Consider the health of populations when designing and re-designing communities and developing and implementing major infrastructure projects, especially in cities given that most of us live in urban or suburban areas. As much as possible, proactively examine projects for their health promotion potential.
  2. Avoid worsening health inequity when designing and re-designing communities by considering the needs and circumstances of populations experiencing these inequities.
  3. Evaluate the health impacts of community design features by enlisting public health expertise. Make the findings from these evaluations openly accessible.
  4. Strengthen existing approaches, share lessons learned and best practices. For all communities, learn from each other in terms of both successful and less successful approaches. Build on existing Canadian networks to foster a pan-Canadian dialogue.
  5. Collaborate to collect standardized data and engage citizens. Support a better understanding of community needs and the health impact of community design on populations.
  6. Innovate so that the healthy choices are the easy choices. Bring together ideas and concepts from across disciplines and sectors. Combine strategies that promote healthy living with those that improve the built environment to optimise impact and investment.

All of these actions could improve the lives of millions of Canadians. As Canada’s Chief Public Health Officer, this is an easy goal for me to stand behind.

References

Footnote 1

Corburn, J. (2017). Urban place and health equity: critical issues and practices. International Journal of Environmental Research & Public Health, 14(2), 117.

Return to footnote 1 referrer

Footnote 2

Greaves, L.J., Bialystok, L.R. (2011). Health in All Policies – All talk and little action? Canadian Journal of Public Health, 102(6), 407-409.

Return to footnote 2 referrer

Footnote 3

Chaix, B., Billaudeau, N., Thomas, F., Havard, S., Evans, D., Kestens, Y., Bean, K. (2011). Neighborhood effects on health: correcting bias from neighborhood effects on participation. Epidemiology, 22(1), 18-26.

Return to footnote 3 referrer

Footnote 4

Clarke, P., Neiuwenhuijsen, E.R. (2009). Environment for healthy ageing: a critical review. Maturitas, 64(1), 14-19.

Return to footnote 4 referrer

Footnote 5

Diez Roux, A.V., Mair, C. (2010). Neighborhoods and health. Annals of the New York Academy of Sciences, 1186, 125-145.

Return to footnote 5 referrer

Footnote 6

Frohlich, K.L., Dunn, J.R. McLaren, L., Shiell, A., Potvin, L., Hawe, P., Dassa, C., Thurston, W.E. (2007). Understanding place and health: a heuristic for using administrative data. Health and Place, 13(2), 299-309.

Return to footnote 6 referrer

Footnote 7

Geneletti, S., Mason, A., Best, N. (2011). Adjusting for selection effects in epidemiologic studies: why sensitivity analysis is the only "solution". Epidemiology, 22(1), 36-39.

Return to footnote 7 referrer

Footnote 8

Healy, M.A., Gilliland, J.A. (2012). Quantifying the magnitude of environmental exposure misclassification when using imprecise address proxies in public health research. Spatial Spatiotemporal Epidemiology, 3(1), 55-67.

Return to footnote 8 referrer

Footnote 9

Riggs, W. (2014). Steps toward validity in active living research: research design that limits accusations of physical determinism. Health and Place, 26, 7-13.

Return to footnote 9 referrer

Footnote 10

Terashim, M., Kephart, G. (2016). Misclassification errors from postal code-based geocoding to assign census geography in Nova Scotia, Canada. Canadian Journal of Public Health, 107(4-5), 424-430.

Return to footnote 10 referrer

What this Report is about

Footnote 11

11. The Chief Public Health Officer's Report (2016). Health Status of Canadians 2016: Report of the Chief Public Health Officer.

Return to footnote 11 referrer

Footnote 12

Navaneelan, T., Janz, T. (2014). Adjusting the scales: Obesity in the Canadian population after correcting for respondent bias. Health at a Glance, 82-624-X. Statistics Canada.

Return to footnote 12 referrer

Footnote 13

Statistics Canada (2013). Table 102-0561: Leading causes of death, by sex. Statistics Canada.

Return to footnote 13 referrer

Footnote 14

Faienza, M.F., Wang, D.Q., Furhbeck, G., Garruti, G., Portincasa, P. (2016). The dangerous link between childhood and adulthood predictors of obesity and metabolic syndrome. Internal & Emergency Medicine, 11(2), 175-182.

Return to footnote 14 referrer

Footnote 15

Hidaka, B.H. (2012). Depression as a disease of modernity : explanations for increasing prevalence. Journal of Affective Disorders, 140(3), 205-214.

Return to footnote 15 referrer

Footnote 16

Hu, F.B. (2003). Sedentary lifestyle and risk of obesity and type 2 diabetes. Lipids, 39(2), 103-108.

Return to footnote 16 referrer

Footnote 17

Chaput, J.P., Carson, V., Gray, C.E., Tremblay, M.S. (2014). Importance of all movement behaviors in a 24 hour period for overall health. International Journal of Environmental Research & Public Health, 11(12), 12575-12581.

Return to footnote 17 referrer

Footnote 18

Whisman, M.A. (2010). Loneliness and the metabolic syndrome in a population-based sample of middle-aged and older adults. Health Psychology, 29(5), 550-554.

Return to footnote 18 referrer

Footnote 19

Tomasetti, C., Li, L., Vogelstein, B. (2017). Stem cell divisions, somatic mutations, cancer etiology, and cancer prevention. Science, 355(6331), 1330-1334.

Return to footnote 19 referrer

Footnote 20

Public Health Agency of Canada (2014). Supportive environments for physical activity: how the built environment affects our health. Public Health Agency of Canada.

Return to footnote 20 referrer

Footnote 21

Washburn, R. A., Szabo, A. N., Lambourne, K., Willis, E. A., Ptomey, L. T., Honas, J. J., Herrmann, S.D., Donnelly, J. E. (2014). Does the method of weight loss effect long-term changes in weight, body composition or chronic disease risk factors in overweight or obese adults? A systematic review. PLoS One, 9(10).

Return to footnote 21 referrer

Footnote 22

Statistics Canada (2015). Canada's rural population since 1851. Census in Brief. Statistics Canada.

Return to footnote 22 referrer

Footnote 23

Statistics Canada (2017). Population size and growth in Canada: key results from the 2016 Census. Statistics Canada.

Return to footnote 23 referrer

Footnote 24

Statistics Canada (2017). Population and dwelling count highlight tables, 2016 Census. Statistics Canada.

Return to footnote 24 referrer

Footnote 25

Statistics Canada (2017). Municipalities in Canada with the largest and fastest-growing populations between 2011 and 2016. Statistics Canada.

Return to footnote 25 referrer

Footnote 26

Statistics Canada (2017). Municipalities in Canada with population decreases between 2011 and 2016. Statistics Canada.

Return to footnote 26 referrer

Footnote 27

Frumkin, H.(2002). Urban sprawl and public health. Public Health Reports, 117, 201-217.

Return to footnote 27 referrer

Footnote 28

Pohanka, M., Fitzgerald, S. (2004). Urban sprawl and you: how sprawl adversely affects worker health. American Association of Occupational Health Nurses Journal, 52(6), 242-246.

Return to footnote 28 referrer

Footnote 29

Thompson, S. (2014). Healthy built environments supporting everyday occupations: current thinking in urban planning. Journal of Occupational Science, 21(1), 25-41.

Return to footnote 29 referrer

Footnote 30

Turcotte, M. (2008). Dependence on cars in urban neighbourhoods. Canadian Social Trends, 11-008-XWE. Statistics Canada.

Return to footnote 30 referrer

Footnote 31

Vlahov, D., Galea, S. (2002). Urbanization, urbanicity and health. Journal of Urban Health, 79(Suppl 1), S1-S12.

Return to footnote 31 referrer

Footnote 32

Mackenbach, J.D., Rutter, H., Compernolle, S., Glonti, K., Oppert, J.M., Charreire, H., De Bourdeaudhuij, I., Brug, J., Nijpels, G., Lakerveld, J. (2014). Obesogenic environments: a systematic review of the association between the physical environment and adult weight status, the SPOTLIGHT project. BMC Public Health, 14, 233.

Return to footnote 32 referrer

Footnote 33

Owen, N., Sparling, P.B., Healy, G.N., Dunstan, D.W., Matthews, C.E. (2010). Sedentary behavior: emerging evidence for a new health risk. Mayo Clinic Proceedings, 85(12), 1138-1141.

Return to footnote 33 referrer

Footnote 34

Bento, A.M., Cropper, M.L. Mobarak, A.M., Vinha, K. (2005). The effects of urban spatial structure on travel demand in the United States. Review of Economics and Statistics, 87(3), 466-478.

Return to footnote 34 referrer

Footnote 35

Ewing, R., Cervero, R. (2010). Travel and the built environment: a meta-analysis. Journal of American Planning Association, 3, 265-294.

Return to footnote 35 referrer

Footnote 36

Trowbridge, M.J., McDonald, N.C. (2008). Urban sprawl and miles driven daily by teenagers in the United States. American Journal of Preventive Medicine, 34(3), 202-206.

Return to footnote 36 referrer

Footnote 37

Statistics Canada. Table 405-0004: Vehicle registrations (annual (number)). Statistics Canada.

Return to footnote 37 referrer

Footnote 38

Statistics Canada. Table 051-0001. Estimates of population, by age group and sex for July 1, Canada, provinces and territories. (annual (persons unless otherwise noted)). Statistics Canada.

Return to footnote 38 referrer

Footnote 39

Statistics Canada (2008). The city/suburb contrast: how can we measure it? Statistics Canada.

Return to footnote 39 referrer

Footnote 40

Laine, J., Kuvaja-Kollner, V., Pietila, E., Koivuneva, M., Valtonen, H., Kankaanpaa, E. (2014). Cost-effectiveness of population-level physical activity interventions: a systematic review. American Journal of Health Promotion, 29(2), 71-80.

Return to footnote 40 referrer

Footnote 41

McKinnon, R.A., Siddiqi, S.M., Chaloupka, F.J., Mancino, L. Prasad, K. (2016). Obesity-related policy/environmental interventions: a systematic review of economic analyses. American Journal of Preventative Medicine, 50(4), 543-549.

Return to footnote 41 referrer

Footnote 42

Adams, E.J., Goodman, A., Sahlqvist, S., Bull, F.C., Ogilvie, D., iConnect consortium. (2013). Correlates of walking and cycling for transport and recreation : factor structure, reliability and behavioural associations of the perceptions of the environment in the neighbourhood scale (PENS). International Journal of Behavioral Nutrition & Physical Activity, 10, 87.

Return to footnote 42 referrer

Footnote 43

Bancroft, C., Joshi, S., Rundle, A., Hutson, M., Chong, C., Weiss, C.C., Genkinger, J., Neckerman, K., Lovasi, G. (2015). Association of proximity and density of parks and objectively measured physical activity in the United States: A systematic review. Social Science & Medicine, 138, 22-30.

Return to footnote 43 referrer

Footnote 44

Bowler, D.E., Buyung-Ali, L.M., Knight, T.M., Pullin, A.S. (2010). A systematic review of evidence for the added benefits to health of exposure to natural environments. BMC Public Health, 10, 456.

Return to footnote 44 referrer

Footnote 45

Bunn, F., Collier, T., Frost, C., Ker, K., Steinbach, R., Roberts, I., Wentz, R. (2003). Area-wide traffic calming for preventing traffic related injuries (Review). Cochrane Database of Systematic Reviews.

Return to footnote 45 referrer

Footnote 46

Cerin, E., Leslie, E., du Toit, L., Owen, N., Frank, L.D. (2007). Destinations that matter : Associations with walking for transport. Health and Place, 13(3), 713-724.

Return to footnote 46 referrer

Footnote 47

Child, S.T., Schollfman, D.E., Kaczynski, A. T., Forthofer, M., Wilcox, S., Baruth, M. (2016). Neighbourhood attributes associated with the social environment. American Journal of Health Promotion, 30(8), 634-637.

Return to footnote 47 referrer

Footnote 48

Eriksson, U., Arvidsson, D., Gebel, K., Ohlsson, H., Sundquist, K. (2012). Walkability parameters, active transportation and objective physical activity: moderating and mediating effects of motor vehicle ownership in a cross-sectional study. International Journal of Behavioral Nutrition & Physical Activity, 9, 123.

Return to footnote 48 referrer

Footnote 49

Fraser, S.D., Locke, K. (2011). Cycling for transport and public health: a systematic review of the effect of the environment on cycling. European Journal of Public Health, 21(6), 738-743.

Return to footnote 49 referrer

Footnote 50

Hassen, N., Kaufman, P. (2016 ). Examining the role of urban street design in enhancing community engagement: a literature review. Health and Place, 41, 119-132.

Return to footnote 50 referrer

Footnote 51

Lachowycz, K., Jones, A.P. (2011). Greenspace and obesity: a systematic review of the evidence. Obesity Reviews, 12(5), 183-189.

Return to footnote 51 referrer

Footnote 52

Lee, A.C., Maheswaran, R. (2011). The health benefits of urban green spaces: a review of the evidence. Journal of Public Health (Oxf), 33(2), 212-222.

Return to footnote 52 referrer

Footnote 53

Matson-Koffman, D.M., Brownstein, J.N., Neiner, J.A., Greaney, M.L. (2005). A site-specific literature review of policy and environmental interventions that promote physical activity and nutrition for cardiovascular health: what works? American Journal of Health Promotion, 19(3), 167-193.

Return to footnote 53 referrer

Footnote 54

McCormack, G.R., Shiell, A. (2011). In search of causality: a systematic review of the relationship between the built environment and physical activity among adults. International Journal of Behavioral Nutrition & Physical Activity, 8, 125.

Return to footnote 54 referrer

Footnote 55

Mulvaney, C.A., Smith, S., Watson, M.C., Parkin, J., Coupland, C., Miller, P., Kendrick, D., McClintock, H. (2015). Cycling infrastructure for reducing cycling injuries in cyclists. Cochrane Database of Systematic Reviews.

Return to footnote 55 referrer

Footnote 56

National Collaborating Centre for Healthy Public Policy (2012). Urban traffic calming and health. National Collaborating Centre for Healthy Public Policy.

Return to footnote 56 referrer

Footnote 57

Owen, N., Cerin, E., Leslie, E., duToit, L., Coffee, N., Frank, L.D., Baumann, A.E., Hugo, G. (2007). Neighborhood walkability and the walking behavior of Australian adults. American Journal of Preventive Medicine, 33(5), 387-395.

Return to footnote 57 referrer

Footnote 58

Rahmanian, E., Gasevic, D., Vukmirovich, I., Lear, S.A. (2014). The association between the built environment and dietary intake: a systematic review. Asia Pacific Journal of Clinical Nutrition, 23(2), 183-196.

Return to footnote 58 referrer

Footnote 59

Winters, M., Brauer, M., Setton, E.M., Teschke, K. (2010). Built environment influences on healthy transportation choices: bicycling versus driving. Journal of Urban Health, 87(6), 969-993.

Return to footnote 59 referrer

Footnote 60

Ashton, J. (1991). The Healthy Cities project: a challenge for health education. Health Education Quarterly, 18(1) 39-48.

Return to footnote 60 referrer

Footnote 61

Hancock, T. (1997). Healthy cities and communities: past, present, and future. National Civic Review, 86(1), 11-21.

Return to footnote 61 referrer

Footnote 62

Mowat, D. (2014). Healthy Canada by Design: translating science in action and prevention. Canadian Journal of Public Health, 106(1 Suppl 1), S3-4.

Return to footnote 62 referrer

Footnote 63

Harris, R. (2004). Creeping conformity: how Canada became suburban, 1900-1960. Toronto: University of Toronto Press Incorporated.

Return to footnote 63 referrer

Footnote 64

Canadian Institute of Planners (2011). Healthy Communities Practice Guide. Canadian Institute of Planners.

Return to footnote 64 referrer

Footnote 65

Harris, R. (2004). Creeping conformity: how Canada became suburban, 1900-1960. Toronto: University of Toronto Press Incorporated.

Return to footnote 65 referrer

Footnote 66

Harris, R., Larkham, P. (2004). Changing suburbs: foundation, form and function. New York: Taylor and Francis.

Return to footnote 66 referrer

Footnote 67

Organisation mondiale de la Santé (2013). Health in All Policies: Framework for Country Action. Organisation mondiale de la Santé.

Return to footnote 67 referrer

Footnote 68

St-Pierre, L., Gauvin, F.P. (2011). Intersectoral governance for Health in All Policies: an integrated framework. Government of South Australia, Health SA.

Return to footnote 68 referrer

Footnote 69

Frelier, A., Muntaner, C., Shankardass, K., Mah, C.L., Molnar, A., Renahy, E., O'Campo, P. (2013). Glossary for the implementation of Health in All Policies (HiAP). Journal of Epidemiology and Community Health, 67(12), 1068-1072.

Return to footnote 69 referrer

Footnote 70

Frank, L.D., Kavage, S. (2008). Urban planning and public health: a story of separation and reconnection. Journal of Public Health Management and Practice, 14(3), 214-220.

Return to footnote 70 referrer

Footnote 71

Sarkar, C., Webster, C. (2017). Health cities of tomorrow: the case for large scale built environment-health studies. Journal of Urban Health, 94(1), 4-19.

Return to footnote 71 referrer

Footnote 72

Fan, Y., Song, Y. (2009). Is sprawl associated with a widening urban-suburban mortality gap? Journal of Urban Health, 86(5), 708-728.

Return to footnote 72 referrer

Canadian communities

Footnote 73

Statistics Canada. Table 105-2023: Measured adult body mass index (BMI) (World Health Organization classification), by age group and sex, Canada and provinces, Canadian Community Health Survey – Nutrition (occasional). Statistics Canada.

Return to footnote 73 referrer

Footnote 74

Statistics Canada. Table 105-2024: Measured children and youth body mass index (BMI) (World Health Organization classification), by age group and sex, Canada and provinces, Canadian Community Health Survey – Nutrition (occasional). Statistics Canada.

Return to footnote 74 referrer

Footnote 75

Statistics Canada (2017). Age and sex, and type of dwelling data: key results from the 2016 Census. Statistics Canada.

Return to footnote 75 referrer

Footnote 76

Statistics Canada (2017). A portrait of the population aged 85 and older in 2016 in Canada. Census in Brief. Statistics Canada.

Return to footnote 76 referrer

Footnote 77

The World Bank (2015). Population density. The World Bank.

Return to footnote 77 referrer

Footnote 78

Statistics Canada (2017). Population size and growth rate, Canada, provinces and territories, 2006 to 2011 and 2011 to 2016. Statistics Canada.

Return to footnote 78 referrer

Footnote 79

Statistics Canada (2017). Dwellings in Canada. Census in Brief. Statistics Canada.

Return to footnote 79 referrer

Footnote 80

Alberta Health Services (2011). Towards an understanding of healthy equity: glossary. Alberta Health Services.

Return to footnote 80 referrer

Footnote 81

Public Health Agency of Canada (2005). The Rural Think Tank 2005 – understanding issues families face living in rural and remote communities. Public Health Agency of Canada.

Return to footnote 81 referrer

Footnote 82

Statistics Canada (2015). Rural area (RA). Statistics Canada.

Return to footnote 82 referrer

Footnote 83

Stout, R. (in press). The built environment: understanding how physical environments influence the health and well-being of First Nations peoples living on-reserve. National Collaborating Centre for Aboriginal Health.

Return to footnote 83 referrer

Footnote 84

Frost, S.S., Goins, R.T., Hunter, R.H., Hooker, S.P., Bryant, L.L., Kruger, J., Pluto, D. (2010). Effects of the built environment on physical activity of adults living in rural settings. American Journal of Health Promotion, 24(4), 267-283.

Return to footnote 84 referrer

Footnote 85

Hansen, A.Y., Umstattd Meyer, M.R., Lenardson, J.D., Hartley, D. (2015). Built environments and active living in rural and remote areas: a review of the literature. Current Obesity Reports, 4(4), 484-493.

Return to footnote 85 referrer

Footnote 86

Canadian Institute for Health Information (2006). How healthy are rural Canadians? An assessment of their health status and health determinants. Canadian Institute for Health Information.

Return to footnote 86 referrer

Footnote 87

Lavergne, M.R., Kephart, G. (2012). Examining variations in health within rural Canada. Rural Remote Health, 12, 1848.

Return to footnote 87 referrer

Footnote 88

Sibley, L.M., Weiner, J.P. (2011). An evaluation of access to health care services along the rural-urban continuum in Canada. BMC Health Services Research, 11, 20.

Return to footnote 88 referrer

Footnote 89

Singh, G.K., Siahpush, M. (2013). Widening rural-urban disparities in all-cause mortality and mortality from major causes of death in the USA, 1969-2009. Journal of Urban Health, 91(2), 272-292.

Return to footnote 89 referrer

Footnote 90

Song, X., MacKnight, C., Latta, R., Mithitkski, A.B., Rockwood, K. (2007). Frailty and survival of rural and urban seniors: results from the Canadian Study of Health and Aging. Aging Clinical and Experimental Research, 19(2), 145-153.

Return to footnote 90 referrer

Footnote 91

Morrison, C., Ponicki, W. R., Gruenewald, P. J., Wiebe, D. J., Smith, K. (2016). Spatial relationships between alcohol-related road crashes and retail alcohol availability. Drug & Alcohol Dependence, 162, 241-244.

Return to footnote 91 referrer

Footnote 92

Vafaei, A., Rosenberg, M.W., Pickett, W. (2010). Relationships between income inequality and health: a study on rural and urban regions of Canada. Rural Remote Health, 10(2), 1430.

Return to footnote 92 referrer

Footnote 93

Alirol, E., Getaz, L., Stoll, B., Chappuis, F., Loutan, L. (2011). Urbanisation and infectious diseases in a globalised world. The Lancet infectious diseases, 11(2), 131-141.

Return to footnote 93 referrer

Footnote 94

Berry, H.L. (2007). 'Crowded suburbs' and 'killer cities': a brief review of the relationship between urban environments and mental health. New South Whales Public Health Bulletin, 18(11-12), 222-2227.

Return to footnote 94 referrer

Footnote 95

Harner, T., Shoeib, M., Diamond, M., Stern, G., Rosenberg, B. (2004). Using passive air samplers to assess urban-rural trends for persistent organic pollutants. 1. Polychlorinated biphenyls and organochlorine pesticides. Environmental Science and Technology, 38(17), 4474-4483.

Return to footnote 95 referrer

Footnote 96

Kundu, S, Stone, E.A. (2014). Composition and sources of fine particulate matter across urban and rural sites in the Midwestern United States. Environmental Sciences: Processes & Impacts, 16, 1360-1370.

Return to footnote 96 referrer

Footnote 97

Neiderud, C.J. (2015). How urbanization affects the epidemiology of emerging infectious diseases. Infection Ecology & Epidemiology.

Return to footnote 97 referrer

Footnote 98

Pickett, K.E., Wilkonson, R.G. (2015). Income inequality and health: a causal review. Social Science & Medicine, 128, 316-326.

Return to footnote 98 referrer

Footnote 99

Wilkinson, R.G., Pickett, K.E. (2006). Income inequality and population health: a review and explanation of the evidence. Social Science & Medicine, 62(7), 1768-1784.

Return to footnote 99 referrer

Footnote 100

Macinko, J.A., Shi, L., Starfield, B., Wulu Jr., J.T., (2003). Income inequality and health: a critical review of the literature. Medical Care Research & Review, 60(4), 407-452.

Return to footnote 100 referrer

Footnote 101

Grant, T.L., Edwards, N., Sveistrup, H., Andrew, C., Egan, M. (2010). Inequitable walking conditions among older people: examining the interrelationship of neighbourhood socio-economic status and urban form using a comparative case study. BMC Public Health, 10, 677.

Return to footnote 101 referrer

Footnote 102

Larsen, K., Gilliland, J. (2008). Mapping the evolution of 'food deserts; in a Canadian city : Supermarket accessibility in London, Ontario, 1961-2005. International Journal of Health Geographics, 7, 16.

Return to footnote 102 referrer

Footnote 103

Kheirbek, I., Haney, J., Douglas, S., Ito, K., Matte, T. (2016). The contribution of motor vehicle emissions to ambient fine particulate matter public health impacts in New York City: a health burden assessment. Environmental Health, 15(1), 89.

Return to footnote 103 referrer

Footnote 104

Sugiyama, T., Howard, N.J., Paquet, C., Coffee, N.T., Taylor, A.W., Daniel, M. (2015). Do relationships between environmental attributes and recreational walking vary according to area-level socioeconomic status? Journal of Urban Health, 92(2), 253-264.

Return to footnote 104 referrer

Footnote 105

Clark, C., Myron, R., Stansfeld, S., Candy, B. (2007). A systematic review of the evidence on the built and physical environment on mental health. Journal of Public Mental Health, 6(2), 14-27.

Return to footnote 105 referrer

Footnote 106

Haddad, L., Schafer, A., Streit, F., Lederbogen, F., Grimm, O., Wust, S., Deuschle, M., Kirsch, P., Tost, H., Meyer-Lindenberg, A. (2015). Brain structure correlates with urban upbringing, an environment risk factor for schizophrenia. Schizophrenia Bulletin, 41(1), 115-122.

Return to footnote 106 referrer

Footnote 107

Hirsch, J.K. (2006). A review of the literature on rural suicide: risk and protective factors, incidence and prevention. Crisis, 27(4), 189-199.

Return to footnote 107 referrer

Footnote 108

Krabbendam, L., van Os, J. (2005). Schizophrenia and urbanicity: a major environmental influence – conditional on genetic risk. Schizophrenia Bulletin, 31(4), 795-799.

Return to footnote 108 referrer

Footnote 109

Peen, J., Schoevers, R.A., Beekman, A.T., Dekker, J. (2010). The current status of urban-rural differences in psychiatric disorders. Acta Psychiatrica Scandinavica, 121(2), 84-93.

Return to footnote 109 referrer

Footnote 110

Pedersen, C.B., Mortensen, P.B. (2001). Evidence of a dose-response relationship between urbanicity during upbringing and schizophrenia risk. Archives of General Psychiatry, 58(11), 1039-1045.

Return to footnote 110 referrer

Footnote 111

Sundquist, K., Frank, G. (2004). Urbanization and hospital admission rates for alcohol and drug abuse: a follow-up study of 4.5 million women and men in Sweden. Addiction, 99(10), 1298-1305.

Return to footnote 111 referrer

Footnote 112

Van Son, G.E., van Hoeken, D., Bartelds, A.I., van Furth, E.F., Hoek, H.W. (2006). Urbanisation and the incidence of eating disorders. British Journal of Psychiatry, 189, 562-563.

Return to footnote 112 referrer

Footnote 113

Lederbogen, F., Kirsch, P., Haddad, L., Streit, F., Tost, H. Schuch, P., Wust, S., Pruessner, J.C., Rietschel, M., Deuschel, M., Meyer-Lindenberg, A. (2011). City living and urban upbringing affect neural social stress processing in humans. Nature, 474(7352), 498-501.

Return to footnote 113 referrer

Footnote 114

Steinheuser, V., Ackermann, K., Schofeld, P., Schwabe, L. (2014). Stress and the city: impact of urban upbringing on the (re)activity of the hypothalamus-pituitary-adrenal axis. Psychosomatic Medicine, 76(9), 678-685.

Return to footnote 114 referrer

Building blocks of Canadian communities

Active neighbourhoods

Footnote 115

Statistics Canada. Table 117-0019 - Distribution of the household population meeting/not meeting the Canadian physical activity guidelines, by sex and age group (occasional (percentage)). Statistics Canada.

Return to footnote 115 referrer

Footnote 116

Kelly, P., Kahlmeier, S., Gotschi, T., Orsini, N., Richards, J., Roberts, N., Scarborough, P., Foster, C. (2014). Systematic review and meta-analysis of reduction in all-cause mortality from walking and cycling and shape of dose response relationship. International Journal of Behavioral Nutrition & Physical Activity, 11, 132.

Return to footnote 116 referrer

Footnote 117

Lee, I. M., Shiroma, E. J., Lobelo, F., Puska, P., Blair, S. N., Katzmarzyk, P. T., Lancet Physical Activity Series Working Group. (2012). Effect of physical inactivity on major non-communicable diseases worldwide: an analysis of burden of disease and life expectancy. The Lancet, 380(9838), 219-229.

Return to footnote 117 referrer

Footnote 118

Woodcock, J., Franco, O. H., Orsini, N., Roberts, I. (2011). Non-vigorous physical activity and all-cause mortality: systematic review and meta-analysis of cohort studies. International Journal of Epidemiology, 40(1), 121-138.

Return to footnote 118 referrer

Footnote 119

Bauman, A., Merom, D., Bull, F. C., Buchner, D. M., Fiatarone Singh, M. A. (2016). Updating the evidence for physical activity: summative reviews of the epidemiological evidence, prevalence, and interventions to promote "Active Aging". The Gerontologist, 56(Suppl_2), S268-S280.

Return to footnote 119 referrer

Footnote 120

Bouaziz, W., Vogel, T., Schmitt, E., Kaltenbach, G., Geny, B., Lang, P. O. (2017). Health benefits of aerobic training programs in adults aged 70 and over: a systematic review. Archives of Gerontology and Geriatrics, 69, 110-127.

Return to footnote 120 referrer

Footnote 121

Costigan, S. A., Eather, N., Plotnikoff, R. C., Taaffe, D. R., Lubans, D. R. (2015). High-intensity interval training for improving health-related fitness in adolescents: a systematic review and meta-analysis. British Journal of Sports Medicine, 39(19), 1253-1261.

Return to footnote 121 referrer

Footnote 122

García‐Hermoso, A., Cerrillo‐Urbina, A. J., Herrera‐Valenzuela, T., Cristi‐Montero, C., Saavedra, J. M., Martínez‐Vizcaíno, V. (2016). Is high‐intensity interval training more effective on improving cardiometabolic risk and aerobic capacity than other forms of exercise in overweight and obese youth? A meta‐analysis. Obesity Reviews, 17(6), 531-540.

Return to footnote 122 referrer

Footnote 123

Jelleyman, C., Yates, T., O'Donovan, G., Gray, L. J., King, J. A., Khunti, K., Davies, M. J. (2015). The effects of high‐intensity interval training on glucose regulation and insulin resistance: a meta‐analysis. Obesity Reviews, 16(11), 942-961.

Return to footnote 123 referrer

Footnote 124

Kruk, J., Czerniak, U. (2013). Physical activity and its relation to cancer risk: updating the evidence. Asian Pacific Journal of Cancer Prevention, 14(7) 399-4003.

Return to footnote 124 referrer

Footnote 125

Liou, K., Ho, S., Fildes, J., Ooi, S. Y. (2016). High intensity interval versus moderate intensity continuous training in patients with coronary artery disease: a meta-analysis of physiological and clinical parameters. Heart, Lung and Circulation, 25(2), 166-174.

Return to footnote 125 referrer

Footnote 126

Loprinzi, P. D., Cardinal, B. J., Loprinzi, K. L., Lee, H. (2012). Benefits and environmental determinants of physical activity in children and adolescents. Obesity Facts, 5(4), 597-610.

Return to footnote 126 referrer

Footnote 127

Melo, M. C. A., Daher, E. D. F., Albuquerque, S. G. C., de Bruin, V. M. S. (2016). Exercise in bipolar patients: a systematic review. Journal of Affective Disorders, 198, 32-38.

Return to footnote 127 referrer

Footnote 128

O'Donovan, G., Lee, I. M., Hamer, M., Stamatakis, E. (2017). Association of "weekend warrior" and other leisure time physical activity patterns with risks for all-cause, cardiovascular disease, and cancer mortality. JAMA Internal Medicine, 177(3), 335-342.

Return to footnote 128 referrer

Footnote 129

Petriz, B. A., Gomes, C. P., Almeida, J. A., de Oliveira, G. P., Ribeiro, F. M., Pereira, R. W., Franco, O. L. (2017). The effects of acute and chronic exercise on skeletal muscle proteome. Journal of Cellular Physiology, 232(2), 257-269.

Return to footnote 129 referrer

Footnote 130

Poitras, V. J., Gray, C. E., Borghese, M. M., Carson, V., Chaput, J. P., Janssen, I., Katzmarzyk, P.T., Pate, R.R., Connor Gorber, S., Kho, M.E., Sampson, M. (2016). Systematic review of the relationships between objectively measured physical activity and health indicators in school-aged children and youth. Applied Physiology, Nutrition, and Metabolism, 41(6), S197-S239.

Return to footnote 130 referrer

Footnote 131

Radovic, S., Gordon, M. S., Melvin, G. A. (2017). Should we recommend exercise to adolescents with depressive symptoms? A meta‐analysis. Journal of Paediatrics and Child Health, 53(3), 214-220.

Return to footnote 131 referrer

Footnote 132

Ramos, J. S., Dalleck, L. C., Tjonna, A. E., Beetham, K. S., Coombes, J. S. (2015). The impact of high-intensity interval training versus moderate-intensity continuous training on vascular function: a systematic review and meta-analysis. Sports Medicine, 45(5), 679.

Return to footnote 132 referrer

Footnote 133

Rimes, R.R., de Souza Moura, A.M., Khede Lamego, M., Souza de Sa Filho, A., Manochio, J., Paes, F., Giovanni Carta, M., Mura, G., Wegner, M., Budde, H. Barbosa Ferreira Rocha, N. (2015). Effects of exercise on physical and mental health, and cognitive and brain functions in schizophrenia: clinical and experimental evidence. CNS and Neurological Disorders-Drug Targets, 14(10), 1244-1254.

Return to footnote 133 referrer

Footnote 134

Rosenbaum, S., Tiedemann, A., Stanton, R., Parker, A., Waterreus, A., Curtis, J., Ward, P. B. (2016). Implementing evidence-based physical activity interventions for people with mental illness: an Australian perspective. Australasian Psychiatry, 24(1), 49-54.

Return to footnote 134 referrer

Footnote 135

Stubbs, B., Vancampfort, D., Rosenbaum, S., Firth, J., Cosco, T., Veronese, N., Salum, G. A., Schuch, F. B. (2017). An examination of the anxiolytic effects of exercise for people with anxiety and stress-related disorders: A meta-analysis. Psychiatry Research, 249, 102-108.

Return to footnote 135 referrer

Footnote 136

Warburton, D. E., Katzmarzyk, P. T., Rhodes, R. E., Shephard, R. J. (2007). Evidence informed physical activity guidelines for Canadian adults. Canadian Journal of Public Health, 96 (Suppl 2), S16-68.

Return to footnote 136 referrer

Footnote 137

World Cancer Research Fund/American Institute for Cancer Research. (2007). Food, nutrition, physical activity and the prevention of cancer. A global perspective. Washington DC: AICR.

Return to footnote 137 referrer

Footnote 138

Zhao, W., Ukawa, S., Kawamura, T., Wakai, K., Ando, M., Tsushita, K., Tamakoshi, A. (2015). Health benefits of daily walking on mortality among younger-elderly men with or without major critical diseases in the new integrated suburban seniority investigation project: a prospective cohort study. Journal of Epidemiology, 25(10), 609-616.

Return to footnote 138 referrer

Footnote 139

Hilfiker, R., Meichtry, A., Eicher, M., Nilsson, B. L., Knols, R. H., Verra, M. L., Taeymans, J. (2017). Exercise and other non-pharmaceutical interventions for cancer-related fatigue in patients during or after cancer treatment: a systematic review incorporating an indirect-comparisons meta-analysis. British Journal of Sports Medicine, epub.

Return to footnote 139 referrer

Footnote 140

Cormie, P., Zopf, E. M., Zhang, X., Schmitz, K. H. (2017). The impact of exercise on cancer mortality, recurrence, and treatment-related adverse effects. Epidemiologic Reviews, 39(1), 71-92.

Return to footnote 140 referrer

Footnote 141

Zanuso, S., Sacchetti, M., Sundberg, C. J., Orlando, G., Benvenuti, P., Balducci, S. (2017). Exercise in type 2 diabetes: genetic, metabolic and neuromuscular adaptations. A review of the evidence. British Journal of Sports Medicine, epub.

Return to footnote 141 referrer

Footnote 142

Baptista, L. C., Machado-Rodrigues, A. M., Martins, R. A. (2017). Exercise but not metformin improves health-related quality of life and mood states in older adults with type 2 diabetes. European Journal of Sport Science, 17(6), 794-804.

Return to footnote 142 referrer

Footnote 143

Melling, C. W. J., Grisé, K. N., Hasilo, C. P., Fier, B., Milne, K. J., Karmazyn, M., Noble, E. G. (2013). A model of poorly controlled type 1 diabetes mellitus and its treatment with aerobic exercise training. Diabetes and Metabolism, 39(3), 226-235.

Return to footnote 143 referrer

Footnote 144

O'Gorman, D. J., Krook, A. (2011). Exercise and the treatment of diabetes and obesity. Medical Clinics of North America, 95(5), 953-969.

Return to footnote 144 referrer

Footnote 145

Sanz, C., Gautier, J. F., Hanaire, H. (2010). Physical exercise for the prevention and treatment of type 2 diabetes. Diabetes and Metabolism, 36(5), 346-351.

Return to footnote 145 referrer

Footnote 146

Berry, T. R., Spence, J. C., Blanchard, C., Cutumisu, N., Edwards, J., Nykiforuk, C. (2010). Changes in BMI over 6 years: the role of demographic and neighborhood characteristics. International Journal of Obesity, 34(8), 1275-1283.

Return to footnote 146 referrer

Footnote 147

Berry, T. R., Spence, J. C., Blanchard, C. M., Cutumisu, N., Edwards, J., Selfridge, G. (2010). A longitudinal and cross-sectional examination of the relationship between reasons for choosing a neighbourhood, physical activity and body mass index. International Journal of Behavioral Nutrition and Physical Activity, 7(1), 57.

Return to footnote 147 referrer

Footnote 148

Casazza, K., Brown, A., Astrup, A., Bertz, F., Baum, C., Brown, M. B., Dawson, J., Durant, N., Dutton, G., Fields, D.A., Fontaine, K. R. (2015). Weighing the evidence of common beliefs in obesity research. Critical Reviews in Food Science and Nutrition, 55(14), 2014-2053.

Return to footnote 148 referrer

Footnote 149

Ferdinand, A.O., Sen, B., Rahurkar, S., Engler, S., Menachemi, N. (2012). The relationship between built environments and physical activity: a systematic review. American Journal of Public Health, 102(10), e7-e13

Return to footnote 149 referrer

Footnote 150

Feng, J., Glass, T. A., Curriero, F. C., Stewart, W. F., Schwartz, B. S. (2010). The built environment and obesity: a systematic review of the epidemiologic evidence. Health and Place, 16(2), 175-190.

Return to footnote 150 referrer

Footnote 151

Booth, K. M., Pinkston, M. M., Poston, W. S. C. (2005). Obesity and the built environment. Journal of the American Dietetic Association, 105(5), 110-117.

Return to footnote 151 referrer

Footnote 152

Durand, C. P., Andalib, M., Dunton, G. F., Wolch, J., Pentz, M. A. (2011). A systematic review of built environment factors related to physical activity and obesity risk: implications for smart growth urban planning. Obesity Reviews, 12(5), e173-e182.

Return to footnote 152 referrer

Footnote 153

Ewing, R., Meakins, G., Hamidi, S., Nelson, A. C. (2014). Relationship between urban sprawl and physical activity, obesity, and morbidity–update and refinement. Health and Place, 26, 118-126.

Return to footnote 153 referrer

Footnote 154

Hipp, J. A., Chalise, N. (2015). Spatial analysis and correlates of county-level diabetes prevalence, 2009–2010. Preventing Chronic Disease, 12.

Return to footnote 154 referrer

Footnote 155

Malambo, P., Kengne, A. P., De Villiers, A., Lambert, E. V., Puoane, T. (2016). Built Environment, Selected Risk Factors and Major Cardiovascular Disease Outcomes: A Systematic Review. PloS One, 11(11), e0166846.

Return to footnote 155 referrer

Footnote 156

Renalds, A., Smith, T. H., Hale, P. J. (2010). A systematic review of built environment and health. Family and Community Health, 33(1), 68-78.

Return to footnote 156 referrer

Footnote 157

Zick, C. D., Hanson, H., Fan, J. X., Smith, K. R., Kowaleski-Jones, L., Brown, B. B., Yamada, I. (2013). Re-visiting the relationship between neighbourhood environment and BMI: an instrumental variables approach to correcting for residential selection bias. International Journal of Behavioral Nutrition and Physical Activity, 10(1), 27.

Return to footnote 157 referrer

Footnote 158

Kligerman, M., Sallis, J. F., Ryan, S., Frank, L. D., Nader, P. R. (2007). Association of neighborhood design and recreation environment variables with physical activity and body mass index in adolescents. American Journal of Health Promotion, 21(4), 274-277.

Return to footnote 158 referrer

Footnote 159

Saelens, B. E., Sallis, J. F., Frank, L. D., Couch, S. C., Zhou, C., Colburn, T., Cain, K.L., Chapman, J., Glanz, K. (2012). Obesogenic neighborhood environments, child and parent obesity: the Neighborhood Impact on Kids study. American Journal of Preventive Medicine, 42(5), e57-e64.

Return to footnote 159 referrer

Footnote 160

Sugiyama, T., Koohsari, M. J., Mavoa, S., Owen, N. (2014). Activity-friendly built environment attributes and adult adiposity. Current Obesity Reports, 3(2), 183-198.

Return to footnote 160 referrer

Footnote 161

Creatore, M. I., Glazier, R. H., Moineddin, R., Fazli, G. S., Johns, A., Gozdyra, P., Matheson, F.I., Kaufman-Shriqui, V., Rosella, L.C., Manuel, D.G., Booth, G. L. (2016). Association of neighborhood walkability with change in overweight, obesity, and diabetes. JAMA, 315(20), 2211-2220.

Return to footnote 161 referrer

Footnote 162

Glazier, R. H., Creatore, M. I., Weyman, J. T., Fazli, G., Matheson, F. I., Gozdyra, P., Moineddin, R., Shriqui, V.K., Booth, G. L. (2014). Density, destinations or both? A comparison of measures of walkability in relation to transportation behaviors, obesity and diabetes in Toronto, Canada. PloS One, 9(1), e85295.

Return to footnote 162 referrer

Footnote 163

Booth, G. L., Creatore, M. I., Moineddin, R., Gozdyra, P., Weyman, J. T., Matheson, F. I., Glazier, R. H. (2013). Unwalkable neighborhoods, poverty, and the risk of diabetes among recent immigrants to Canada compared with long-term residents. Diabetes Care, 36(2), 302-308.

Return to footnote 163 referrer

Footnote 164

Loo, C. J., Greiver, M., Aliarzadeh, B., Lewis, D. (2017). Association between neighbourhood walkability and metabolic risk factors influenced by physical activity: a cross-sectional study of adults in Toronto, Canada. BMJ Open, 7(4), e013889.

Return to footnote 164 referrer

Footnote 165

Booth, G.L. (2016). Built environment and health. Canada Communicable Disease Report, 42, 10.

Return to footnote 165 referrer

Footnote 166

Kaczynski, A. (2010). Neighborhood walkability perceptions: associations with amount of neighborhood-based physical activity by intensity and purpose. Journal of Physical Activity & Health, 7(1), 3-10.

Return to footnote 166 referrer

Footnote 167

Wojan, T.R., Hamrick, K.S. (2015). Can walking or biking to work really make a difference? Compact development, observed commuter choice and body mass index. PLoS One, 10(7).

Return to footnote 167 referrer

Footnote 168

Mueller, N., Rojas-Rueda, D., Cole-Hunter, T., de Nazelle, A., Dons, E., Gerike, R., Goetschi, T., Panis, L.I., Kahlmeier, S., Nieuwenhuijsen, M. (2015). Health impact assessment of active transportation: a systematic review. Preventive Medicine, 76, 103-114.

Return to footnote 168 referrer

Footnote 169

Butler, G.P., Orpana, H.M., Wiens, A.J. (2007). By your own two feet: factors associated with active transportation in Canada. Canadian Journal of Public Health, 98(4), 259-264.

Return to footnote 169 referrer

Footnote 170

Ogilvie, D., Foster, C.E., Rothnie, H., Cavill, N., Hamilton, V., Fitzsimons, C.F., Mutrie, N., Scottish Physical Activity Research Collaboration. (2007). Interventions to promote walking: systematic review. BMJ, 334(7605), 1204.

Return to footnote 170 referrer

Footnote 171

Public Health Agency of Canada (2014). What is Active Transportation? Public Health Agency of Canada.

Return to footnote 171 referrer

Footnote 172

Besser, L. M., Dannenberg, A. L. (2005). Walking to public transit: steps to help meet physical activity recommendations. American Journal of Preventive Medicine, 29(4), 273-280.

Return to footnote 172 referrer

Footnote 173

Lachapelle, U., Frank, L. D. (2009). Transit and health: mode of transport, employer-sponsored public transit pass programs, and physical activity. Journal of Public Health Policy, 30(1), S73-S94.

Return to footnote 173 referrer

Footnote 174

Chaix, B., Kestens, Y., Duncan, S., Merrien, C., Thierry, B., Pannier, B., Brondeel, R., Lewin, A., Karusisi, N., Perchoux, C., Thomas, F. (2014). Active transportation and public transportation use to achieve physical activity recommendations? A combined GPS, accelerometer, and mobility survey study. International Journal of Behavioral Nutrition and Physical Activity, 11(1), 124.

Return to footnote 174 referrer

Footnote 175

Rissel, C., Curac, N., Greenaway, M., Bauman, A. (2012). Physical activity associated with public transport use—a review and modelling of potential benefits. International Journal of Environmental Research and Public Health, 9(7), 2454-2478.

Return to footnote 175 referrer

Footnote 176

Lachapelle, U., Frank, L., Saelens, B. E., Sallis, J. F., Conway, T. L. (2011). Commuting by public transit and physical activity: where you live, where you work, and how you get there. Journal of Physical Activity and Health, 8(Suppl 1), S72-S82.

Return to footnote 176 referrer

Footnote 177

Yang, L., Sahlqvist, S., McMinn, A., Griffin, S.J., Ogilvie, D. (2010). Interventions to promote cycling : systematic review. BMJ, 341, c5293.

Return to footnote 177 referrer

Footnote 178

New York City Department of Health and Mental Hygiene. (2011). Health benefits of active transportation in New York City. NYC Vital Signs, 10(3).

Return to footnote 178 referrer

Footnote 179

Canadian Institute of Planners (2012). Active transportation, health and community design: What is the Canadian evidence saying? Canadian Institute of Planners.

Return to footnote 179 referrer

Footnote 180

Handy, S. L., Boarnet, M. G., Ewing, R., Killingsworth, R. E. (2002). How the built environment affects physical activity: views from urban planning. American Journal of Preventive Medicine, 23(2), 64-73.

Return to footnote 180 referrer

Footnote 181

Stevens, M. R. (2017). Does compact development make people drive less?. Journal of the American Planning Association, 83(1), 7-18.

Return to footnote 181 referrer

Footnote 182

Giles-Corti, B., Vernez-Moudon, A., Reis, R., Turrell, G., Dannenberg, A.L., Badland, H., Foster, S., Lowe, M., Sallis, J.F., Stevenson, M., Owen, N. (2016). City planning and population health : a global challenge. The Lancet, 388(10062), 2912-2924.

Return to footnote 182 referrer

Footnote 183

Sallis, J.F., Bull., F., Burdett, R., Frank, L.D., Griffiths, P., Giles-Corti, B., Stevenson, M. (2016 ). Use of science to guide city planning policy and practice : how to achieve healthy and sustainable future cities. The Lancet, 388(10062), 2936-2947.

Return to footnote 183 referrer

Footnote 184

Sallis, J.F., Cerin, E., Conway, T.L., Adams, M.A., Frank, L.D., Pratt, M., Salvo, D., Schipperijn, J., Smith G., Cain, K.L., Davey, R., Kerr, J., Lai, P.C., Mitas, J., Reis, R., Sarmiento, O.L., Schofield, G., Troelsen, J., Van Dyck, D., De Bourdeaudhuij, I., Owen, N. (2016). Physical activity in relation to urban environments in 14 cities worldwide: a cross-sectional study. The Lancet, 387(10034), 2207-2217.

Return to footnote 184 referrer

Footnote 185

Hajna, S., Ross, N. A., Brazeau, A. S., Bélisle, P., Joseph, L., Dasgupta, K. (2015). Associations between neighbourhood walkability and daily steps in adults: a systematic review and meta-analysis. BMC Public Health, 15(1), 768.

Return to footnote 185 referrer

Footnote 186

Kelly, C., Lian, M., Struthers, J., Kammrath, A. (2015). Walking to work: The roles of neighborhood walkability and socioeconomic deprivation. Journal of Physical Activity and Health, 12(Suppl 1), S70-S75.

Return to footnote 186 referrer

Footnote 187

Thielman, J., Manson, H., Chiu, M., Copes, R., Rosella, L. C. (2016). Residents of highly walkable neighbourhoods in Canadian urban areas do substantially more physical activity: a cross-sectional analysis. Canadian Medical Association Journal Open, 4(4), e720.

Return to footnote 187 referrer

Footnote 188

Public Health Agency of Canada (2011). Fast facts about Canada's neighbourhoods and physical activity. Public Health Agency of Canada.

Return to footnote 188 referrer

Footnote 189

Hajna, S., Ross, N. A., Joseph, L., Harper, S., Dasgupta, K. (2015). Neighbourhood walkability, daily steps and utilitarian walking in Canadian adults. BMJ Open, 5(11), e008964.

Return to footnote 189 referrer

Footnote 190

Jack, E., McCormack, G. R. (2014). The associations between objectively-determined and self-reported urban form characteristics and neighborhood-based walking in adults. International Journal of Behavioral Nutrition and Physical Activity, 11(1), 71.

Return to footnote 190 referrer

Footnote 191

Thielman, J., Rosella, L., Copes, R., Lebenbaum, M., Manson, H. (2015). Neighborhood walkability: differential associations with self-reported transport walking and leisure-time physical activity in Canadian towns and cities of all sizes. Preventive Medicine, 77, 174-180.

Return to footnote 191 referrer

Footnote 192

Wasfi, R. A., Ross, N. A., El-Geneidy, A. M. (2013). Achieving recommended daily physical activity levels through commuting by public transportation: Unpacking individual and contextual influences. Health and Place, 23, 18-25.

Return to footnote 192 referrer

Footnote 193

Winters, M., Brauer, M., Setton, E. M., Teschke, K. (2010). Built environment influences on healthy transportation choices: bicycling versus driving. Journal of Urban Health, 87(6), 969-993.

Return to footnote 193 referrer

Footnote 194

Brown, B. B., Tharp, D., Tribby, C. P., Smith, K. R., Miller, H. J., Werner, C. M. (2016). Changes in bicycling over time associated with a new bike lane: relations with kilocalories energy expenditure and body mass index. Journal of Transport and Health, 3(3), 357-365.

Return to footnote 194 referrer

Footnote 195

Fuller, D., Gauvin, L., Kestens, Y., Daniel, M., Fournier, M., Morency, P., Drouin, L. (2013). Impact evaluation of a public bicycle share program on cycling: a case example of BIXI in Montreal, Quebec. American Journal of Public Health, 103(3), e85-e92.

Return to footnote 195 referrer

Footnote 196

Goodman, A., Sahlqvist, S., Ogilvie, D., iConnect Consortium. (2014). New walking and cycling routes and increased physical activity: one-and 2-year findings from the UK iConnect Study. American Journal of Public Health, 104(9), e38-e46.

Return to footnote 196 referrer

Footnote 197

Panter, J., Ogilvie, D. (2015). Theorising and testing environmental pathways to behaviour change: natural experimental study of the perception and use of new infrastructure to promote walking and cycling in local communities. BMJ open, 5(9), e007593.

Return to footnote 197 referrer

Footnote 198

Parker, K. M., Gustat, J., Rice, J. C. (2011). Installation of bicycle lanes and increased ridership in an urban, mixed-income setting in New Orleans, Louisiana. Journal of Physical Activity and Health, 8(Suppl 1), S98-S102.

Return to footnote 198 referrer

Footnote 199

Parker, K. M., Rice, J., Gustat, J., Ruley, J., Spriggs, A., Johnson, C. (2013). Effect of bike lane infrastructure improvements on ridership in one New Orleans neighborhood. Annals of Behavioral Medicine, 45(1), 101-107.

Return to footnote 199 referrer

Footnote 200

Pucher, J., Buehler, R. (2008). Making cycling irresistible: lessons from the Netherlands, Denmark and Germany. Transport Reviews, 28(4), 495-528.

Return to footnote 200 referrer

Footnote 201

Pucher, J., Dill, J., Handy, S. (2010). Infrastructure, programs, and policies to increase bicycling: an international review. Preventive Medicine, 50, S106-S125.

Return to footnote 201 referrer

Footnote 202

Rissel, C., Greaves, S., Wen, L. M., Crane, M., Standen, C. (2015). Use of and short-term impacts of new cycling infrastructure in inner-Sydney, Australia: a quasi-experimental design. International Journal of Behavioral Nutrition and Physical Activity, 12(1), 129.

Return to footnote 202 referrer

Footnote 203

Stewart, G., Anokye, N. K., Pokhrel, S. (2015). What interventions increase commuter cycling? A systematic review. BMJ Open, 5(8), e007945.

Return to footnote 203 referrer

Footnote 204

Winters, M., Teschke, K., Brauer, M., Fuller, D. (2016). Bike Score®: Associations between urban bikeability and cycling behavior in 24 cities. International Journal of Behavioral Nutrition and Physical Activity, 13(1), 18.

Return to footnote 204 referrer

Footnote 205

Reynolds, C. C., Harris, M. A., Teschke, K., Cripton, P. A., Winters, M. (2009). The impact of transportation infrastructure on bicycling injuries and crashes: a review of the literature. Environmental Health, 8(1), 47.

Return to footnote 205 referrer

Footnote 206

Arvidsson, D., Kawakami, N., Ohlsson, H., Sundquist, K. (2012). Physical activity and concordance between objective and perceived walkability. Medicine and Science in Sports and Exercise, 44(2), 280-287.

Return to footnote 206 referrer

Footnote 207

Gebel, K., Bauman, A. E., Sugiyama, T., Owen, N. (2011). Mismatch between perceived and objectively assessed neighborhood walkability attributes: prospective relationships with walking and weight gain. Health and Place, 17(2), 519-524.

Return to footnote 207 referrer

Footnote 208

Gebel, K., Bauman, A., Owen, N. (2009). Correlates of non-concordance between perceived and objective measures of walkability. Annals of Behavioral Medicine, 37(2), 228-238.

Return to footnote 208 referrer

Footnote 209

Nieuwenhuijsen, M. J., Khreis, H. (2016). Car free cities: pathway to healthy urban living. Environment International, 94, 251-262.

Return to footnote 209 referrer

Footnote 210

Manville, M., King, D. A., Smart, M. J. (2017). The Driving Downturn: A Preliminary Assessment. Journal of the American Planning Association, 83(1), 42-55.

Return to footnote 210 referrer

Footnote 211

Coronini-Cronberg, S., Millett, C., Laverty, A. A., Webb, E. (2012). The impact of a free older persons' bus pass on active travel and regular walking in England. American Journal of Public Health, 102(11), 2141-2148.

Return to footnote 211 referrer

Footnote 212

Edwards, P., Steinbach, R., Green, J., Petticrew, M., Goodman, A., Jones, A., Roberts, H., Kelly, C., Nellthorp, J., Wilkinson, P. (2013). Health impacts of free bus travel for young people: evaluation of a natural experiment in London. Journal of Epidemiology and Community Health, jech-2012.

Return to footnote 212 referrer

Footnote 213

Green, J., Steinbach, R., Jones, A., Edwards, P., Kelly, C., Nellthorp, J., Goodman, A., Roberts, H., Petticrew, M., Wilkinson, P. (2014). On the buses: a mixed-method evaluation of the impact of free bus travel for young people on the public health. Public Health Research, 2(1).

Return to footnote 213 referrer

Footnote 214

Menai, M., Charreire, H., Feuillet, T., Salze, P., Weber, C., Enaux, C., Andreeva, V.A., Hercberg, S., Nazare, J.A., Perchoux, C., Simon, C. (2015). Walking and cycling for commuting, leisure and errands: relations with individual characteristics and leisure-time physical activity in a cross-sectional survey (the ACTI-Cités project). International Journal of Behavioral Nutrition and Physical Activity, 12(1), 150.

Return to footnote 214 referrer

Footnote 215

Stepaniuk, J. A., Tuokko, H., McGee, P., Garrett, D. D., Benner, E. L. (2008). Impact of transit training and free bus pass on public transportation use by older drivers. Preventive Medicine, 47(3), 335-337.

Return to footnote 215 referrer

Footnote 216

Webb, E., Laverty, A., Mindell, J., Millett, C. (2016). Free bus travel and physical activity, gait speed, and adiposity in the English Longitudinal Study of Ageing. American Journal of Public Health, 106(1), 136-142.

Return to footnote 216 referrer

Footnote 217

Adams, E. J., Goodman, A., Sahlqvist, S., Bull, F. C., Ogilvie, D. (2013). Correlates of walking and cycling for transport and recreation: factor structure, reliability and behavioural associations of the perceptions of the environment in the neighbourhood scale (PENS). International Journal of Behavioral Nutrition and Physical Activity, 10(1), 87.

Return to footnote 217 referrer

Footnote 218

Addy, C. L., Wilson, D. K., Kirtland, K. A., Ainsworth, B. E., Sharpe, P., Kimsey, D. (2004). Associations of perceived social and physical environmental supports with physical activity and walking behavior. American Journal of Public Health, 94(3), 440-443.

Return to footnote 218 referrer

Footnote 219

Giles-Corti, B., Bull, F., Knuiman, M., McCormack, G., Van Niel, K., Timperio, A., Christian, H., Foster, S., Divitini, M., Middleton, N., Boruff, B. (2013). The influence of urban design on neighbourhood walking following residential relocation: longitudinal results from the RESIDE study. Social Science and Medicine, 77, 20-30.

Return to footnote 219 referrer

Footnote 220

McCormack, G. R., Friedenreich, C. M., Giles-Corti, B., Doyle-Baker, P. K., Shiell, A. (2013). Do motivation-related cognitions explain the relationship between perceptions of urban form and neighborhood walking? Journal of Physical Activity and Health, 10(7), 961-973.

Return to footnote 220 referrer

Footnote 221

Merom, D., Bauman, A., Phongsavan, P., Cerin, E., Kassis, M., Brown, W., Smith, B.J. Rissel, C. (2009). Can a motivational intervention overcome an unsupportive environment for walking—findings from the Step-by-Step Study. Annals of Behavioral Medicine, 38(2), 137-146.

Return to footnote 221 referrer

Footnote 222

Perchoux, C., Kestens, Y., Brondeel, R., Chaix, B. (2015). Accounting for the daily locations visited in the study of the built environment correlates of recreational walking (the RECORD Cohort Study). Preventive Medicine, 81, 142-149.

Return to footnote 222 referrer

Footnote 223

Chaix, B., Simon, C., Charreire, H., Thomas, F., Kestens, Y., Karusisi, N., Vallée, J., Oppert, J.M., Weber, C. Pannier, B. (2014). The environmental correlates of overall and neighborhood based recreational walking (a cross-sectional analysis of the RECORD Study). International Journal of Behavioral Nutrition and Physical Activity, 11(1), 20.

Return to footnote 223 referrer

Footnote 224

Buehler, R., Pucher, J. (2012). International Overview: Cycling Trends in Western Europe, North America, and Australia. City Cycling, 9-29.

Return to footnote 224 referrer

Footnote 225

Ebert, A. K. (2004). Cycling towards the nation: The use of the bicycle in Germany and the Netherlands, 1880–1940. European Review of History, 11(3), 347-364.

Return to footnote 225 referrer

Footnote 226

Statistique Canada (2017). La pratique de la bicyclette au Canada. Rapports sur la santé. Statistique Canada.

Return to footnote 226 referrer

Footnote 227

Pucher, J., Buehler, R. (2006). Why Canadians cycle more than Americans: a comparative analysis of bicycling trends and policies. Transport Policy, 13(3), 265-279.

Return to footnote 227 referrer

Footnote 228

Pucher, J., Buehler, R., Seinen, M. (2011). Bicycling renaissance in North America? An update and re-appraisal of cycling trends and policies. Transportation Research Part A: Policy and Practice, 45(6), 451-475.

Return to footnote 228 referrer

Footnote 229

Lopez, R., Hynes, H. P. (2003). Sprawl in the 1990s: measurement, distribution, and trends. Urban Affairs Review, 38(3), 325-355.

Return to footnote 229 referrer

Footnote 230

Statistics Canada (2017). Population and dwelling count highlight tables, 2016 Census. Statistics Canada.

Return to footnote 230 referrer

Footnote 231

City of Toronto (2017). Ward Profiles.

Return to footnote 231 referrer

Footnote 232

Mueller, N., Rojas-Rueda, D., Cole-Hunter, T., De Nazelle, A., Dons, E., Gerike, R., Gotschi, T., Int Panis, L., Kahlmeier, S., Neiuwenhuijsen, M. (2015). Health impact assessment of active transportation: a systematic review. Preventative Medicine, 76, 103-104.

Return to footnote 232 referrer

Footnote 233

Cairns, J., Warren, J., Garthwaite, K., Greig, G., Bambra, C. (2015). Go slow: an umbrella review of the effects of 20 mph zones and limits on health and health inequalities. Journal of Public Health, 37(3), 515-520.

Return to footnote 233 referrer

Footnote 234

Elvik, R. (2001). Area-wide urban traffic calming schemes: a meta-analysis of safety effects. Accident Analysis and Prevention, 33(3), 327-336.

Return to footnote 234 referrer

Footnote 235

Pulugurtha, S. S., Desai, A., Pulugurtha, N. M. (2010). Are pedestrian countdown signals effective in reducing crashes?. Traffic Injury Prevention, 11(6), 632-641.

Return to footnote 235 referrer

Footnote 236

Retting, R. A., Ferguson, S. A., McCartt, A. T. (2003). A review of evidence-based traffic engineering measures designed to reduce pedestrian–motor vehicle crashes. American Journal of Public Health, 93(9), 1456-1463.

Return to footnote 236 referrer

Footnote 237

Moradi, A., Soori, H., Kavousi, A., Eshghabadi, F., Jamshidi, E. (2016). Spatial factors affecting the frequency of pedestrian traffic crashes: a systematic review. Archives of Trauma Research, 5(4).

Return to footnote 237 referrer

Footnote 238

Brown, B.B., Tharp, D., Tribby, C.P., Smith, K.R., Miller, H.J., Werner, C.M. (2016). Changes in bicycling over time associated with a new bike lane: relationship with kilocalories energy expenditure and body mass index. Journal of Transportation & Health, 3(3), 357-365.

Return to footnote 238 referrer

Footnote 239

Fuller, D., Guavin, L., Kestens, Y., Daniel, M., Fournier, M., Morency, P., Drouin, L. (2013) Impact evaluation of a public bicycle share program on cycling: a case example of BIXI in Montreal, Quebec. American Journal of Public Health, 103(3), e85-e92.

Return to footnote 239 referrer

Footnote 240

Goodman, A., Sahlqvist, S., Ogilivie, D., iConnect Consortium (2014). New walking and cycling routes and increased physical activity: one- and 2-year findings from the UK iConnect Study. Am J Public Health, 104(9), e38-e46.

Return to footnote 240 referrer

Footnote 241

Winters, M., Teschke, K., Grant, M., Setton, E., Brauer, M. (2014). How far out of the way will we travel? Built environment influences on route selection for bicycle and car travel. Transportation Research Record, 2190.

Return to footnote 241 referrer

Footnote 242

Winters, M., Brauer, M., Setton, E.M., Teschke, K. (2010). Built environment influences on healthy transportation choices : bicycling versus driving. Journal of Urban Health, 87(6), 969-993.

Return to footnote 242 referrer

Footnote 243

Winters, M., Buehler, R., Gotschi, T. (2017). Policies to promote active travel: evidence from reviews of literature. Current Environmental Health Reports, epub.

Return to footnote 243 referrer

Footnote 244

Jarjour, S., Jerrett, M., Westerdahl, D., de Nazelle, A., Hanning, C., Daly, L., Lipsitt, J., Balmes, J. (2013). Cyclist route choice, traffic-related air pollution, and lung function: a scripted exposure study. Environmental Health, 12(1), 14.

Return to footnote 244 referrer

Footnote 245

Organisation mondiale de la Santé (2016). Ambient air pollution: a global assessment of exposure and burden of disease. Organisation mondiale de la Santé.

Return to footnote 245 referrer

Footnote 246

Environment and Climate Change Canada (2016). Your Local Air Quality Health Index Conditions. Environment and Climate Change Canada.

Return to footnote 246 referrer

Footnote 247

Brook, R. D., Bard, R. L., Morishita, M., Dvonch, J. T., Wang, L., Yang, H. Y., Spino, C., Mukherjee, B., Kaplan, M.J., Yalavarthi, S., Oral, E. A. (2014). Hemodynamic, autonomic, and vascular effects of exposure to coarse particulate matter air pollution from a rural location. Environmental Health Perspectives, 122(6), 624.

Return to footnote 247 referrer

Footnote 248

Urch, B., Speck, M., Corey, P., Wasserstein, D., Manno, M., Lukic, K. Z., Brook, J.R., Liu, L., Coull, B., Schwartz, J., Gold, D. R. (2010). Concentrated ambient fine particles and not ozone induce a systemic interleukin-6 response in humans. Inhalation Toxicology, 22(3), 210-218.

Return to footnote 248 referrer

Footnote 249

Betts, K.S. (2012). Heart Disease Tradeoffs: The Built Environment, Air Pollution, and Activity. Environmental Health Perspectives, 120(2), a77.

Return to footnote 249 referrer

Footnote 250

De Nazelle, A., Rodríguez, D. A., Crawford-Brown, D. (2009). The built environment and health: impacts of pedestrian-friendly designs on air pollution exposure. Science of the Total Environment, 407(8), 2525-2535.

Return to footnote 250 referrer

Footnote 251

Hankey, S., Marshall, J. D., Brauer, M. (2012). Health impacts of the built environment: within-urban variability in physical inactivity, air pollution, and ischemic heart disease mortality. Environmental Health Perspectives, 120(2), 247.

Return to footnote 251 referrer

Footnote 252

Sattar, S. A., Wright, K. E., Zargar, B., Rubino, J. R., Ijaz, M. K. (2016). Airborne infectious agents and other pollutants in automobiles for domestic use: potential health impacts and approaches to risk mitigation. Journal of Environmental and Public Health.

Return to footnote 252 referrer

Footnote 253

Tainio, M., de Nazelle, A. J., Götschi, T., Kahlmeier, S., Rojas-Rueda, D., Nieuwenhuijsen, M. J., de Sá, T.H., Kelly, P., Woodcock, J. (2016). Can air pollution negate the health benefits of cycling and walking?. Preventive Medicine, 87, 233-236.

Return to footnote 253 referrer

Footnote 254

Giles, L. V., Koehle, M. S. (2014). The health effects of exercising in air pollution. Sports Medicine, 44(2), 223-249.

Return to footnote 254 referrer

Footnote 255

Chen, H., Kwong, J.C., Copes, R., Tu, K., Villenevue, P.J., van Donkelaar, A., Hystad, P., Martin, R.V., Murray, B.J., Jessiman, B., Wilton, A.S., Kopp, A., Burnett, R.T. (2017). Living near major roads and the incidence of dementia, Parkinson's disease and multiple sclerosis: a population-based cohort study. The Lancet, 389(10070), 718-726.

Return to footnote 255 referrer

Footnote 256

Kelly, F.J., Fussell, J.C. (2015). Air pollution and public health : emerging hazards and improved understanding risk. Environmental Geochemistry & Health, 37(4), 631-649.

Return to footnote 256 referrer

Footnote 257

Khreis, H., Kelly, C., Tate, J., Parslow, R., Lucas, K., Niewenhuijsen, M. (2017). Exposure to traffic-related air pollution and risk of development of childhood asthma: a systematic review and meta-analysis. Environment International, 100, 1-31.

Return to footnote 257 referrer

Footnote 258

Stieb, D.M., Chen, L., Eshoul, M., Judek, S. (2012). Ambient air pollution, birth weight and preterm birth: a systematic review and meta-analysis. Environmental Research, 1117, 100-111.

Return to footnote 258 referrer

Footnote 259

Stieb, D. M., Beveridge, R. C., Brook, J. R., Smith-Doiron, M. A. R. C., Burnett, R. T., Dales, R. E., Beaulieu, S., Judek, S., Mamedov, A. (2000). Air pollution, aeroallergens and cardiorespiratory emergency department visits in Saint John, Canada. Journal of Exposure Science and Environmental Epidemiology, 10(5), 461.

Return to footnote 259 referrer

Footnote 260

Beckerman, B. S., Jerrett, M., Finkelstein, M., Kanaroglou, P., Brook, J. R., Arain, M. A., Sears, M.R., Stieb, D., Balmes, J., Chapman, K. (2012). The association between chronic exposure to traffic-related air pollution and ischemic heart disease. Journal of Toxicology and Environmental Health, Part A, 75(7), 402-411.

Return to footnote 260 referrer

Footnote 261

Brook, R. D., Jerrett, M., Brook, J. R., Bard, R. L., Finkelstein, M. M. (2008). The relationship between diabetes mellitus and traffic-related air pollution. Journal of Occupational and Environmental Medicine, 50(1), 32-38.

Return to footnote 261 referrer

Footnote 262

Brook, R. D., Cakmak, S., Turner, M. C., Brook, J. R., Crouse, D. L., Peters, P. A., Van Donkelaar, A., Villeneuve, P.J., Brion, O., Jerrett, M., Martin, R. V. (2013). Long-term fine particulate matter exposure and mortality from diabetes in Canada. Diabetes Care, 36(10), 3313-3320.

Return to footnote 262 referrer

Footnote 263

Chen, H., Burnett, R. T., Kwong, J. C., Villeneuve, P. J., Goldberg, M. S., Brook, R. D., van Donkelaar, A., Jerrett, M., Martin, R.V., Brook, J.R., Copes, R. (2013). Risk of incident diabetes in relation to long-term exposure to fine particulate matter in Ontario, Canada. Environmental Health Perspectives, 121(7), 804.

Return to footnote 263 referrer

Footnote 264

Chen, H., Burnett, R. T., Kwong, J. C., Villeneuve, P. J., Goldberg, M. S., Brook, R. D., van Donkelaar, A., Jerrett, M., Martin, R.V., Kopp, A., Brook, J. R. (2014). Spatial association between ambient fine particulate matter and incident hypertension. Circulation, 129 (5), 562-569.

Return to footnote 264 referrer

Footnote 265

Chen, H., Burnett, R. T., Copes, R., Kwong, J. C., Villeneuve, P. J., Goldberg, M. S., Brook, R.D., van Donkelaar, A., Jerrett, M., Martin, R.V., Brook, J. R. (2016). Ambient fine particulate matter and mortality among survivors of myocardial infarction: population-based cohort study. Environmental Health Perspectives, 124(9), 1421.

Return to footnote 265 referrer

Footnote 266

Crouse, D. L., Peters, P. A., van Donkelaar, A., Goldberg, M. S., Villeneuve, P. J., Brion, O., Khan, S., Atari, D.O., Jerrett, M., Pope III, C.A., Brauer, M. (2012). Risk of nonaccidental and cardiovascular mortality in relation to long-term exposure to low concentrations of fine particulate matter: a Canadian national-level cohort study. Environmental Health Perspectives, 120(5), 708.

Return to footnote 266 referrer

Footnote 267

Crouse, D. L., Peters, P. A., Hystad, P., Brook, J. R., van Donkelaar, A., Martin, R. V., Villeneuve, P.J., Jerrett, M., Goldberg, M.S., Pope III, C.A., Brauer, M. (2015). Ambient PM2. 5, O3, and NO2 exposures and associations with mortality over 16 years of follow-up in the Canadian Census Health and Environment Cohort (CanCHEC). Environmental Health Perspectives, 123(11), 1180.

Return to footnote 267 referrer

Footnote 268

Crouse, D. L., Peters, P. A., Villeneuve, P. J., Proux, M. O., Shin, H. H., Goldberg, M. S., Johnson, M., Wheeler, A.J., Allen, R.W., Atari, D.O., Jerrett, M. (2015). Within-and between-city contrasts in nitrogen dioxide and mortality in 10 Canadian cities; a subset of the Canadian Census Health and Environment Cohort (CanCHEC). Journal of Exposure Science and Environmental Epidemiology, 25(5), 482.

Return to footnote 268 referrer

Footnote 269

Dales, R., Burnett, R. T., Smith-Doiron, M., Stieb, D. M., Brook, J. R. (2004). Air pollution and sudden infant death syndrome. Pediatrics, 113(6), e628-e631.

Return to footnote 269 referrer

Footnote 270

Lavigne, E., Yasseen, A. S., Stieb, D. M., Hystad, P., Van Donkelaar, A., Martin, R. V., Brook, J.R., Crouse, D.L., Burnett, R.T., Chen, H., Weichenthal, S. (2016). Ambient air pollution and adverse birth outcomes: Differences by maternal comorbidities. Environmental Research, 148, 457-466.

Return to footnote 270 referrer

Footnote 271

Giles L.V., Barn P., Künzli N., Romieu I., Mittleman M.A., van Eeden S., Allen R., Carlsten C., Stieb D., Noonan C., Smargiassi A, Kaufman J.D., Hajat S., Kosatsky T., Brauer M. (2011). From good intentions to proven interventions: effectiveness of actions to reduce the health impacts of air pollution. Environmental Health Perspectives, 119(1), 29.

Return to footnote 271 referrer

Footnote 272

Laumbach, R., Meng, Q., Kipen, H. (2015). What can individuals do to reduce personal health risks from air pollution?. Journal of Thoracic Disease, 7(1), 96.

Return to footnote 272 referrer

Footnote 273

Böcker, L., Dijst, M., Prillwitz, J. (2013). Impact of everyday weather on individual daily travel behaviours in perspective: a literature review. Transport Reviews, 33(1), 71-91.

Return to footnote 273 referrer

Footnote 274

Bopp, M., Gayah, V. V., Campbell, M. E. (2015). Examining the link between public transit use and active commuting. International Journal of Environmental Research and Public Health, 12(4), 4256-4274.

Return to footnote 274 referrer

Footnote 275

Chan, C. B., Ryan, D. A. (2009). Assessing the effects of weather conditions on physical activity participation using objective measures. International Journal of Environmental Research and Public Health, 6(10), 2639-2654.

Return to footnote 275 referrer

Footnote 276

Dill, J., McNeil, N., Broach, J., Ma, L. (2014). Bicycle boulevards and changes in physical activity and active transportation: Findings from a natural experiment. Preventive Medicine, 69, S74-S78.

Return to footnote 276 referrer

Footnote 277

Fishman, E., Böcker, L., Helbich, M. (2015). Adult active transport in the Netherlands: An analysis of its contribution to physical activity requirements. PloS One, 10(4), e0121871.

Return to footnote 277 referrer

Footnote 278

Gebhart, K., Noland, R. B. (2014). The impact of weather conditions on bike share trips in Washington, DC. Transportation, 41(6), 1205-1225.

Return to footnote 278 referrer

Footnote 279

Miranda-Moreno, L. F., Lahti, A. C. (2013). Temporal trends and the effect of weather on pedestrian volumes: A case study of Montreal, Canada. Transportation Research Part D: Transport and Environment, 22, 54-59.

Return to footnote 279 referrer

Footnote 280

Owen, N., Humpel, N., Leslie, E., Bauman, A., Sallis, J. F. (2004). Understanding environmental influences on walking: review and research agenda. American Journal of Preventive Medicine, 27(1), 67-76.

Return to footnote 280 referrer

Footnote 281

Tucker, P., Gilliland, J. (2007). The effect of season and weather on physical activity: a systematic review. Public Health, 121(12), 909-922.

Return to footnote 281 referrer

Footnote 282

Winters, M., Friesen, M. C., Koehoorn, M., Teschke, K. (2007). Utilitarian bicycling: a multilevel analysis of climate and personal influences. American Journal of Preventive Medicine, 32(1), 52-58.

Return to footnote 282 referrer

Footnote 283

Wolff, D., Fitzhugh, E. C. (2011). The relationships between weather-related factors and daily outdoor physical activity counts on an urban greenway. International Journal of Environmental Research and Public Health, 8(2), 579-589.

Return to footnote 283 referrer

Footnote 284

Collins, P. A., Mayer, D. (2015). Active transportation in Kingston, Ontario: an analysis of mode, destination, duration, and season among walkers and cyclists. Journal of Physical Activity and Health, 12(Suppl 1), S76-S83.

Return to footnote 284 referrer

Footnote 285

Dalton, M. A., Longacre, M. R., Drake, K. M., Gibson, L., Adachi-Mejia, A. M., Swain, K., Xie, H., Owens, P. M. (2011). Built environment predictors of active travel to school among rural adolescents. American Journal of Preventive Medicine, 40(3), 312-319.

Return to footnote 285 referrer

Footnote 286

Katapally, T. R., Rainham, D., Muhajarine, N. (2016). A methodology to leverage cross-sectional accelerometry to capture weather's influence in active living research. Canadian Journal of Public Health, 107(1), 30-36.

Return to footnote 286 referrer

Footnote 287

Merchant, A. T., Dehghan, M., Akhtar-Danesh, N. (2007). Seasonal variation in leisure time physical activity among Canadians. Canadian Journal of Public Health, 203-208.

Return to footnote 287 referrer

Footnote 288

Winters, M., Davidson, G., Kao, D., Teschke, K. (2011). Motivators and deterrents of bicycling: comparing influences on decisions to ride. Transportation, 38(1), 153-168.

Return to footnote 288 referrer

Footnote 289

Winters, M., Friesen, M. C., Koehoorn, M., Teschke, K. (2007). Utilitarian bicycling: a multilevel analysis of climate and personal influences. American Journal of Preventive Medicine, 32(1), 52-58.

Return to footnote 289 referrer

Footnote 290

Helbich, M., Böcker, L., Dijst, M. (2014). Geographic heterogeneity in cycling under various weather conditions: Evidence from Greater Rotterdam. Journal of Transport Geography, 38, 38-47.

Return to footnote 290 referrer

Footnote 291

Witham, M. D., Donnan, P. T., Vadiveloo, T., Sniehotta, F. F., Crombie, I. K., Feng, Z., McMurdo, M. E. (2014). Association of day length and weather conditions with physical activity levels in older community dwelling people. PloS One, 9(1), e85331.

Return to footnote 291 referrer

Footnote 292

Goodman, A., Page, A. S., Cooper, A. R. (2014). Daylight saving time as a potential public health intervention: an observational study of evening daylight and objectively-measured physical activity among 23,000 children from 9 countries. International Journal of Behavioral Nutrition & Physical Activity, 11(1), 84.

Return to footnote 292 referrer

Footnote 293

Kallio, J., Turpeinen, S., Hakonen, H., Tammelin, T. (2016). Active commuting to school in Finland, the potential for physical activity increase in different seasons. International Journal of Circumpolar Health, 75(1), 33319.

Return to footnote 293 referrer

Footnote 294

Reynolds, K.D., Wolch, J., Byrne, J., Chou, C.P., Feng, G., Weaver, S., Jerrett, M. (2007). Trail characteristics as correlates of urban trail use. American Journal of Health Promotion, 21(4_suppl), 335-345.

Return to footnote 294 referrer

Footnote 295

Wilson, L.A.M., Giles-Corti, B., Burton, N.W., Giskes, K., Haynes, M., Turrell, G. (2011). The association between objectively measured neighborhood features and walking in middle-aged adults. American Journal of Health Promotion, 25(4), e12-e21.

Return to footnote 295 referrer

Healthy food options

Footnote 296

Garriguet, D. (2009). Diet quality in Canada. Health Reports, 20(3), 41.

Return to footnote 296 referrer

Footnote 297

Health Canada (2012). Do Canadian adults meet their nutrient requirements through food intake alone? Health Canada.

Return to footnote 297 referrer

Footnote 298

Brisbois, T.D., Marsden, S.L., Anderson, G.H., Sievenpiper, J.L. (2014). Estimated intakes and sources of total and added sugars in the Canadian diet. Nutrients, 6(5), 1899-1912.

Return to footnote 298 referrer

Footnote 299

Langlois, K., Garriguet, D. (2011). Sugar consumption among Canadians of all ages. Health Reports, 22(3), 23-27.

Return to footnote 299 referrer

Footnote 300

Canada's Food Guides (2016).

Return to footnote 300 referrer

Footnote 301

Strickland, J.R., Pizzorno, G., Kinghorn, A.M., Evanoff, B.A. (2015). Worksite influences on obesogenic behaviors in low-wage workers in St Louis, Missouri, 2013-2014. Preventing Chronic Disease, 12, epub.

Return to footnote 301 referrer

Footnote 302

Linde, J.A., Nygaard, K.E., MacLehose, R.F., Mitchell, N.R., Harnack, L.J., Cousins, J.M., Graham, D.J., Jeffery, R.W. (2012). HealthWorks: results of a multi-component group-randomized worksite environmental intervention trial for weight gain prevention. International Journal of Behavioral Nutrition & Physical Activity, 9, 14.

Return to footnote 302 referrer

Footnote 303

Thornton, L.E., Lamb, K.E., Ball, K. (2013). Employment status, residential and workplace food environments: associations with women's eating behaviours. Health and Place, 24, 80-89.

Return to footnote 303 referrer

Footnote 304

Backman, D., Gonzaga, G., Sugerman, S., Francis, D., Cook, S. (2011). Effect of fresh fruit availability at worksites on fruit and vegetable consumption of low-wage employees. Journal of Nutrition Education & Behavior, 43(4 Suppl 2), S113-S121.

Return to footnote 304 referrer

Footnote 305

Escovvery, C., Kegler, M.C., Alcantara, I., Wilson, M., Glanz, K. (2011). A qualitative examination of the role of small, rural worksites in obesity prevention. Preventing Chronic Disease, 8(4), A75.

Return to footnote 305 referrer

Footnote 306

Health Canada (2016). Healthy eating strategy. Health Canada.

Return to footnote 306 referrer

Footnote 307

Shoaie, S., Ghaffari, P., Kovatcheva-Datchary, P., Mardinoglu, A., Sen, P., Pujos-Guillot, E., de Wouters, T., Juste, C., Rizkalla, S., Chilloux, J., Hoyles, L. (2015). Quantifying diet-induced metabolic changes of the human gut microbiome. Cell Metabolism, 22(2), 320-331.

Return to footnote 307 referrer

Footnote 308

Zeevi, D., Korem, T., Zmora, N., Israeli, D., Rothschild, D., Weinberger, A., Ben-Yacov, O., Lador, D., Avnit-Sagi, T., Lotan-Pompan, M., Suez, J. (2015). Personalized nutrition by prediction of glycemic responses. Cell, 163(5), 1079-1094.

Return to footnote 308 referrer

Footnote 309

Celis-Morales, C., Livingstone, K. M., Marsaux, C. F., Macready, A. L., Fallaize, R., O'Donovan, C. B., Woolhead, C., Forster, H., Walsh, M.C., Navas-Carretero, S., San-Cristobal, R. (2017). Effect of personalized nutrition on health-related behaviour change: evidence from the Food4me European randomized controlled trial. International Journal of Epidemiology, 46(2).

Return to footnote 309 referrer

Footnote 310

Nielsen, D. E., El-Sohemy, A. (2014). Disclosure of genetic information and change in dietary intake: a randomized controlled trial. PloS One, 9(11), e112665.

Return to footnote 310 referrer

Footnote 311

Townshend, T., Lake, A. (2017). Obesogenic environments: current evidence of the built and food environments. Perspectives in Public Health, 137(1), 38-44.

Return to footnote 311 referrer

Footnote 312

Lipek, T., Igel, U., Gausche, R., Kiess, W., Grande, G. (2015). Obesogenic environments: environmental approaches to obesity prevention. Journal of Pediatric Endocrinology and Metabolism, 28(5-6), 485-495.

Return to footnote 312 referrer

Footnote 313

Caspi, C. E., Sorensen, G., Subramanian, S. V., Kawachi, I. (2012). The local food environment and diet: a systematic review. Health and Place, 18(5), 1172-1187.

Return to footnote 313 referrer

Footnote 314

Roberto, C. A., Swinburn, B., Hawkes, C., Huang, T. T., Costa, S. A., Ashe, M., Zwicker, L., Cawley, J.H., Brownell, K. D. (2015). Patchy progress on obesity prevention: emerging examples, entrenched barriers, and new thinking. The Lancet, 385(9985), 2400-2409.

Return to footnote 314 referrer

Footnote 315

Block, J. P., Subramanian, S. V. (2015). Moving beyond "food deserts": reorienting United States policies to reduce disparities in diet quality. PLoS Medicine, 12(12), e1001914.

Return to footnote 315 referrer

Footnote 316

Clary, C., Matthews, S. A., Kestens, Y. (2017). Between exposure, access and use: Reconsidering foodscape influences on dietary behaviours. Health and Place, 44, 1-7.

Return to footnote 316 referrer

Footnote 317

Brown, D. R., Brewster, L. G. (2015). The food environment is a complex social network. Social Science and Medicine, 133, 202-204.

Return to footnote 317 referrer

Footnote 318

Dubowitz, T., Zenk, S. N., Ghosh-Dastidar, B., Cohen, D. A., Beckman, R., Hunter, G., Steiner, E.D., Collins, R. L. (2015). Healthy food access for urban food desert residents: examination of the food environment, food purchasing practices, diet and BMI. Public Health Nutrition, 18(12), pp.2220-2230.

Return to footnote 318 referrer

Footnote 319

Ghosh-Dastidar, B., Cohen, D., Hunter, G., Zenk, S. N., Huang, C., Beckman, R., Dubowitz, T. (2014). Distance to store, food prices, and obesity in urban food deserts. American Journal of Preventive Medicine, 47(5), 587-595.

Return to footnote 319 referrer

Footnote 320

Lebel, A., Noreau, D., Tremblay, L., Oberlé, C., Girard-Gadreau, M., Duquay, M., Block, J. P. (2016). Identifying rural food deserts: Methodological considerations for food environment interventions. Canadian Journal of Public Health, 107(1), e521.

Return to footnote 320 referrer

Footnote 321

Mejia, N., Lightstone, A. S., Basurto-Davila, R., Morales, D. M., Sturm, R. (2015). Neighborhood Food Environment, Diet, and Obesity Among Los Angeles County Adults, 2011. Preventing Chronic Disease, 12, e143.

Return to footnote 321 referrer

Footnote 322

Minaker, L. M., Olstad, D. L., Thompson, M. E., Raine, K. D., Fisher, P., Frank, L. D. (2016). Associations between frequency of food shopping at different store types and diet and weight outcomes: findings from the NEWPATH study. Public Health Nutrition, 19(12), 2268-2277.

Return to footnote 322 referrer

Footnote 323

Sadler, R. C., Gilliland, J. A., Arku, G. (2011). An application of the edge effect in measuring accessibility to multiple food retailer types in Southwestern Ontario, Canada. International Journal of Health Geographics, 10(1), 34.

Return to footnote 323 referrer

Footnote 324

Glanz, K., Sallis, J.F., Saelens, B.E., Frank, L.D. (2005). Healthy nutrition environments : concepts and measures. American Journal of Health Promotion, 19(5), 330-333

Return to footnote 324 referrer

Footnote 325

Health Canada (2013). Measuring the food environment in Canada. Health Canada.

Return to footnote 325 referrer

Footnote 326

Cobb, L. K., Appel, L. J., Franco, M., Jones‐Smith, J. C., Nur, A., Anderson, C. (2015). The relationship of the local food environment with obesity: a systematic review of methods, study quality, and results. Obesity, 23(7), 1331-1344.A.

Return to footnote 326 referrer

Footnote 327

Zenk, S.N., Tarlov, E., Wing, C., Matthews, S.A., Jones, K., Tong, H., Powell, L.M. (2017). Geographic accessibility of food outlets not associated with body mass index change among veterans, 2009-2014. Health Affairs, 36(8), 1433.

Return to footnote 327 referrer

Footnote 328

Rahman, T., Cushing, R. A., Jackson, R. J. (2011). Contributions of built environment to childhood obesity. Mount Sinai Journal of Medicine: A Journal of Translational and Personalized Medicine, 78(1), 49-57.

Return to footnote 328 referrer

Footnote 329

Thornton, L. E., Kavanagh, A. M. (2012). Association between fast food purchasing and the local food environment. Nutrition and Diabetes, 2(12), e53.

Return to footnote 329 referrer

Footnote 330

Zenk, S. N., Thatcher, E., Reina, M., Odoms-Young, A. (2015). 6 Local Food Environments and Diet-Related Health Outcomes. Local Food Environments: Food Access in America, 167.

Return to footnote 330 referrer

Footnote 331

Daniel, M., Paquet, C., Auger, N., Zang, G., Kestens, Y. (2010). Association of fast-food restaurant and fruit and vegetables tore densities with cardiovascular mortality in a metropolitan population. European Journal of Epidemiology, 25(10), 711-719.

Return to footnote 331 referrer

Footnote 332

Prince, S. A., Kristjansson, E. A., Russell, K., Billette, J. M., Sawada, M. C., Ali, A.,Tremblay, M.S., Prud'homme, D. (2012). Relationships between neighborhoods, physical activity, and obesity: a multilevel analysis of a large Canadian city. Obesity, 20(10), 2093-2100.

Return to footnote 332 referrer

Footnote 333

Minaker, L. M., Raine, K. D., Wild, T. C., Nykiforuk, C. I., Thompson, M. E., Frank, L. D. (2013). Objective food environments and health outcomes. American Journal of Preventive Medicine, 45(3), 289-296.

Return to footnote 333 referrer

Footnote 334

Prince, S. A., Kristjansson, E. A., Russell, K., Billette, J. M., Sawada, M., Ali, A.,Tremblay, M.S., Prud'homme, D. (2011). A multilevel analysis of neighbourhood built and social environments and adult self-reported physical activity and body mass index in Ottawa, Canada. International Journal of Environmental Research and Public Health, 8(10), 3953-3978.

Return to footnote 334 referrer

Footnote 335

Kruger, D. J., Greenberg, E., Murphy, J. B., DiFazio, L. A., Youra, K. R. (2014). Local concentration of fast-food outlets is associated with poor nutrition and obesity. American Journal of Health Promotion, 28(5), 340-343.

Return to footnote 335 referrer

Footnote 336

Fraser, L. K., Edwards, K. L., Cade, J., Clarke, G. P. (2010). The geography of fast food outlets: a review. International Journal of Environmental Research and Public Health, 7(5), 2290-2308.

Return to footnote 336 referrer

Footnote 337

Dubowitz, T., Ghosh‐Dastidar, M. B., Steiner, E., Escarce, J. J., Collins, R. L. (2013). Are our actions aligned with our evidence? The skinny on changing the landscape of obesity. Obesity, 21(3), 419-420.

Return to footnote 337 referrer

Footnote 338

Chen, D., Jaenicke, E. C., Volpe, R. J. (2016). Food environments and obesity: household diet expenditure versus food deserts. American Journal of Public Health, 106(5), 881-888.

Return to footnote 338 referrer

Footnote 339

Widener, M. J., Shannon, J. (2014). When are food deserts? Integrating time into research on food accessibility. Health and Place, 30, 1-3.

Return to footnote 339 referrer

Footnote 340

Fitterer, J.L., Nelson, T.A., Stockwell, T. (2015). A review of existing studies reporting the negative effects of alcohol access and positive effects of alcohol control policies on interpersonal violence. Front Public Health, 3, 253.

Return to footnote 340 referrer

Footnote 341

Badland, H., Mavoa, S., Linvingston, M., David, S., Giles-Corti, B. (2016). Testing spatial measures of alcohol outlet density with self-rated health in the Australian context: implications for policy and practice. Drug & Alcohol Review, 35(3), 298-306.

Return to footnote 341 referrer

Footnote 342

Fone, D., Morgan, J., Fry, R., Rodgers, S., Orford, S., Farewell, D., Dunstan, F., White, J., Sivarajasingam, V., Trefan, L., Brennan, I., Lee, S., Shiode, N., Weightman, A., Webster, C., Lyons, R. (2016). Change in alcohol outlet density and alcohol-related harm to population health (CHALICE): a comprehensive record-linked database study in Wales. NIHB Journal Library.

Return to footnote 342 referrer

Footnote 343

Morrison, C., Smith, K., Gruenewald, P.J., Ponicki, W.R., Lee, J.P., Cameron, P. (2015). Relating off-premises alcohol outlet density to intentional and unintentional injuries. Addiction, 111(1), 56-64.

Return to footnote 343 referrer

Footnote 344

Morrison, C.N., Dong, B., BRanas, C.C., Richmond, T.S., Wiebe, D.J. (2017). A momentary exposures analysis of proximity to alcohol outlets and risk for assault. Addiction, 112(2), 269-278.

Return to footnote 344 referrer

Footnote 345

Snowden, A.J. (2016). Alcohol outlet density and intimate partner violence in a nonmetropolitan college town: accounting for neighborhood characteristics and alcohol outlet types. Violence & Victims, 31(1), 111-123.

Return to footnote 345 referrer

Footnote 346

Ahem, J., Balzer, L., Galea, S. (2015). The roles of outlet density and norms in alcohol use disorder. Drug & Alcohol Dependence, 151, 144-150.

Return to footnote 346 referrer

Footnote 347

Bryden, A. Roberts, B., McKee, M., Petticrew, M. (2012). A systematic review of the influence on alcohol use of community level availability and marketing of alcohol, Health and Place, 18(2), 349-357.

Return to footnote 347 referrer

Footnote 348

Stockwell, T., Zhao, J., Martin, G., Macdonald, S., Vallance, K., Treno, A., Ponicki, W., Tu, A., Buxton, J. (2013). Minimum alcohol prices and outlet densities in British Columbia, Canada: estimated impacts on alcohol-attributable hospital admissions. American Journal of Public Health, 103(11), 2014-2020.

Return to footnote 348 referrer

Footnote 349

Pereira, G., Wood, L., Foster, S., Haggar, F. (2013). Access to alcohol outlets, alcohol consumption and mental health. PLoS One, 8(1), e53461.

Return to footnote 349 referrer

Footnote 350

Popova, S., Giesbrecht, N., Bekmuradov, D., Patra, J. (2009). Hours and days of sale and density of alcohol outlets: impacts on alcohol consumption and damage: a systematic review. Alcohol & Alcoholism, 44(5), 500-516.

Return to footnote 350 referrer

Footnote 351

Treno, A.J., Ponicki, W.R., Stockwell, T., Macdonald, S., Gruenewald, P.J., Zhao, J., Martin, G., Greer, A. (2013). Alcohol outlet densities and alcohol price: the British Columbia experiment in the partial privatization of alcohol sales off-premise. Alcoholism: Clinical & Experimental Research, 37(5), 854-859.

Return to footnote 351 referrer

Footnote 352

Gilliland, J. A., Rangel, C. Y., Healy, M. A., Tucker, P., Loebach, J. E., Hess, P. M., He, M., Irwin, J.D., Wilk, P. (2012). Linking childhood obesity to the built environment: a multi-level analysis of home and school neighbourhood factors associated with body mass index. Canadian Journal of Public Health, 103(9), 15-21.

Return to footnote 352 referrer

Footnote 353

Hollands, S., Campbell, M. K., Gilliland, J., Sarma, S. (2013). A spatial analysis of the association between restaurant density and body mass index in Canadian adults. Preventive Medicine, 57(4), 258-264.

Return to footnote 353 referrer

Footnote 354

Hollands, S., Campbell, M. K., Gilliland, J., Sarma, S. (2014). Association between neighbourhood fast-food and full-service restaurant density and body mass index: a cross-sectional study of Canadian adults. Canadian Journal of Public Health, 105(3), 172-178.

Return to footnote 354 referrer

Footnote 355

Polsky, J.Y, Moineddin R., Glazier, R. H., Dunn J.R., Booth, G. L. (2016). Relative and absolute availability of fast-food restaurants in relation to the development of diabetes: A population-based cohort study. Canadian Journal of Public Health, 107(1), e527.

Return to footnote 355 referrer

Footnote 356

Polsky, J. Y., Moineddin, R., Dunn, J. R., Glazier, R. H., Booth, G. L. (2016). Absolute and relative densities of fast-food versus other restaurants in relation to weight status: Does restaurant mix matter? Preventive Medicine, 82, 28-34.

Return to footnote 356 referrer

Footnote 357

Boone-Heinonen, J., Gordon-Larsen, P., Kiefe, C. I., Shikany, J. M., Lewis, C. E., Popkin, B. M. (2011). Fast food restaurants and food stores: longitudinal associations with diet in young to middle-aged adults: the CARDIA study. Archives of Internal Medicine, 171(13), 1162-1170.

Return to footnote 357 referrer

Footnote 358

Hager, E. R., Cockerham, A., O'Reilly, N., Harrington, D., Harding, J., Hurley, K. M., Black, M. M. (2016). Food swamps and food deserts in Baltimore City, MD, USA: associations with dietary behaviours among urban adolescent girls. Public Health Nutrition, 1-10.

Return to footnote 358 referrer

Footnote 359

Hollands, S., Campbell, M. K., Gilliland, J., Sarma, S. (2014). Association between neighbourhood fast-food and full-service restaurant density and body mass index: a cross-sectional study of Canadian adults. Canadian Journal of Public Health, 105(3), 172-178.

Return to footnote 359 referrer

Footnote 360

Mezuk, B., Li, X., Cederin, K., Rice, K., Sundquist, J., Sundquist, K. (2016). Beyond Access: Characteristics of the Food Environment and Risk of Diabetes. American Journal of Epidemiology, 183(12), 1129-1137.

Return to footnote 360 referrer

Footnote 361

Minaker, L. M., Raine, K. D., Wild, T. C., Nykiforuk, C. I., Thompson, M. E., Frank, L. D. (2013). Objective food environments and health outcomes. American Journal of Preventive Medicine, 45(3), 289-296.

Return to footnote 361 referrer

Footnote 362

Luan, H., Law, J., Quick, M. (2015). Identifying food deserts and swamps based on relative healthy food access: a spatio-temporal Bayesian approach. International Journal of Health Geographics, 14(1), 37.

Return to footnote 362 referrer

Footnote 363

Centers for Disease Control and Prevention (2010). Healthy Places: Zoning. Centers for Disease Control and Prevention.

Return to footnote 363 referrer

Footnote 364

Raine, K. D., Muhajarine, N., Spence, J. C., Neary, N. E., Nykiforuk, C. I. (2012). Coming to consensus on policy to create supportive built environments and community design. Canadian Journal of Public Health, 103(Suppl 3), S5-S8.

Return to footnote 364 referrer

Footnote 365

Quebec en Forme (2012). Modifying the built environment to promote healthy eating among youth. Highlights of Research, 2011-2012.

Return to footnote 365 referrer

Footnote 366

Mayo, M. L., Pitts, S. B. J., Chriqui, J. F. (2013). Associations between county and municipality zoning ordinances and access to fruit and vegetable outlets in rural North Carolina, 2012. Preventing Chronic Disease, 10, e203.

Return to footnote 366 referrer

Footnote 367

McCormack, L. A., Laska, M. N., Larson, N. I., Story, M. (2010). Review of the nutritional implications of farmers' markets and community gardens: a call for evaluation and research efforts. Journal of the American Dietetic Association, 110(3), 399-408.

Return to footnote 367 referrer

Footnote 368

Jilcott Pitts, S. B., Wu, Q., Demarest, C. L., Dixon, C. E., Dortche, C. J., Bullock, S. L., McGuirt, J., Ward, R., Ammerman, A. S. (2015). Farmers' market shopping and dietary behaviours among Supplemental Nutrition Assistance Program participants. Public Health Nutrition, 18(13), 2407-2414.

Return to footnote 368 referrer

Footnote 369

Leone, L. A., Beth, D., Ickes, S. B., MacGuire, K., Nelson, E., Smith, R. A., Tate, D.F., Ammerman, A. S. (2012). Attitudes toward fruit and vegetable consumption and farmers' market usage among low-income North Carolinians. Journal of Hunger and Environmental Nutrition, 7(1), 64-76.

Return to footnote 369 referrer

Footnote 370

McGuirt, J. T., Pitts, S. B. J., Ward, R., Crawford, T. W., Keyserling, T. C., Ammerman, A. S. (2014). Examining the influence of price and accessibility on willingness to shop at farmers' markets among low-income eastern North Carolina women. Journal of Nutrition Education and Behavior, 46(1), 26-33.

Return to footnote 370 referrer

Footnote 371

Wang, H., Qiu, F., Swallow, B. (2014). Can community gardens and farmers' markets relieve food desert problems? A study of Edmonton, Canada. Applied Geography, 55, 127-137.

Return to footnote 371 referrer

Footnote 372

Bowling, A. B., Moretti, M., Ringelheim, K., Tran, A., Davison, K. (2016). Healthy Foods, Healthy Families: combining incentives and exposure interventions at urban farmers' markets to improve nutrition among recipients of US federal food assistance. Health Promotion Perspectives, 6(1), 10.

Return to footnote 372 referrer

Footnote 373

Jilcott Pitts, S. B., Wu, Q., McGuirt, J. T., Crawford, T. W., Keyserling, T. C., Ammerman, A. S. (2013). Associations between access to farmers' markets and supermarkets, shopping patterns, fruit and vegetable consumption and health indicators among women of reproductive age in eastern North Carolina, USA. Public Health Nutrition, 16(11), 1944-1952.

Return to footnote 373 referrer

Footnote 374

Jilcott Pitts, S. B., Gustafson, A., Wu, Q., Mayo, M. L., Ward, R. K., McGuirt, J. T., Rafferty, A.P., Lancaster, M.F., Evenson, K.R., Keyserling, T.C., Ammerman, A. S. (2014). Farmers' market use is associated with fruit and vegetable consumption in diverse southern rural communities. Nutrition Journal, 13(1), 1.

Return to footnote 374 referrer

Footnote 375

Jilcott Pitts, S. B., Acheson, M. L. M., Ward, R. K., Wu, Q., McGuirt, J. T., Bullock, S. L., Lancaster, M.F., Raines, J., Ammerman, A. S. (2015). Disparities in healthy food zoning, farmers' market availability, and fruit and vegetable consumption among North Carolina residents. Archives of Public Health, 73(1), 35.

Return to footnote 375 referrer

Footnote 376

Jilcott Pitts, S. B., Hinkley, J., Wu, Q., McGuirt, J. T., Lyonnais, M. J., Rafferty, A. P., Whitt, O.R., Winterbauer, N., Phillips, L. (2017). A possible dose–response association between distance to farmers' markets and roadside produce stands, frequency of shopping, fruit and vegetable consumption, and body mass index among customers in the Southern United States. BMC Public Health, 17(1), 65.

Return to footnote 376 referrer

Footnote 377

Payne, G. H., Wethington, H., Olsho, L., Jernigan, J., Farris, R., Walker, D. K. (2013). Implementing a Farmers' Market Incentive Program: Perspectives on the New York City Health Bucks Program. Preventing Chronic Disease, 10, e145.

Return to footnote 377 referrer

Footnote 378

Robles, B., Montes, C. E., Nobari, T. Z., Wang, M. C., Kuo, T. (2017). Dietary Behaviors among Public Health Center Clients with Electronic Benefit Transfer Access at Farmers' Markets. Journal of the Academy of Nutrition and Dietetics, 117(1), 58-68.

Return to footnote 378 referrer

Footnote 379

Lucan, S. C., Maroko, A. R., Sanon, O., Frias, R., Schechter, C. B. (2015). Urban farmers' markets: Accessibility, offerings, and produce variety, quality, and price compared to nearby stores. Appetite, 90, 23-30.

Return to footnote 379 referrer

Footnote 380

Alaimo, K., Beavers, A. W., Crawford, C., Snyder, E. H., Litt, J. S. (2016). Amplifying health through community gardens: A framework for advancing multicomponent, behaviorally based neighborhood interventions. Current Environmental Health Reports, 3(3), 302-312.

Return to footnote 380 referrer

Footnote 381

Alaimo, K., Packnett, E., Miles, R.A., Kruger, D.J. (2008). Fruit and vegetable intake among urban community gardeners. Journal of Nutrition Education & Behavior, 40(2), 94-101.

Return to footnote 381 referrer

Footnote 382

Barnidge, E. K., Baker, E. A., Schootman, M., Motton, F., Sawicki, M., Rose, F. (2015). The effect of education plus access on perceived fruit and vegetable consumption in a rural African American community intervention. Health Education Research, 30(5), 773-785.

Return to footnote 382 referrer

Footnote 383

Carney, P. A., Hamada, J. L., Rdesinski, R., Sprager, L., Nichols, K. R., Liu, B. Y., Pelayo, J., Sanchez, M.A., Shannon, J. (2012). Impact of a community gardening project on vegetable intake, food security and family relationships: a community-based participatory research study. Journal of Community Health, 37(4), 874-881.

Return to footnote 383 referrer

Footnote 384

Castro, D. C., Samuels, M., Harman, A. E. (2013). Growing healthy kids: a community garden–based obesity prevention program. American Journal of Preventive Medicine, 44(3), S193-S199.

Return to footnote 384 referrer

Footnote 385

Egli, V., Oliver, M., Tautolo, E. S. (2016). The development of a model of community garden benefits to wellbeing. Preventive Medicine Reports, 3, 348-352.

Return to footnote 385 referrer

Footnote 386

Litt, J. S., Soobader, M. J., Turbin, M. S., Hale, J. W., Buchenau, M., Marshall, J. A. (2011). The influence of social involvement, neighborhood aesthetics, and community garden participation on fruit and vegetable consumption. American Journal of Public Health, 101(8), 1466-1473.

Return to footnote 386 referrer

Footnote 387

Soga, M., Gaston, K. J., Yamaura, Y. (2016). Gardening is beneficial for health: A meta-analysis. Preventive Medicine Reports. 5, 92-99.

Return to footnote 387 referrer

Footnote 388

Alaimo, K., Reischl, T.M., Allen, J.O. (2010). Community gardening, neighborhood meetings, and social capital. Journal of Community Psychology, 38(4), 497-514.

Return to footnote 388 referrer

Footnote 389

Teig, E., Amulya, J., Bardwell, L., Buchenau, M., Marshall, J.A., Litt, J.S. (2009). Collective efficacy in Denver, Colorado: Strengthening neighborhoods and health through community gardens. Health and Place, 15(4), 1155-1122.

Return to footnote 389 referrer

Footnote 390

Statistics Canada. Table 326-0012: Average retail prices for food and other selected items (monthly (dollars)). Statistics Canada.

Return to footnote 390 referrer

Footnote 391

Statistics Canada (2014). The changing face of the Canadian fruit and vegetable sector: 1941 to 2011. Statistics Canada.

Return to footnote 391 referrer

Footnote 392

Statistics Canada (2017). Fruit and vegetable production, 2016. Statistics Canada.

Return to footnote 392 referrer

Footnote 393

Tarasuk, V. (2010). Policy directions to promote healthy dietary patterns in Canada. Applied Physiology Nutrition & Metabolism, 35, 229-233.

Return to footnote 393 referrer

Footnote 394

Tarasuk, V., Mitchell, A., Dachner, N. (2014). Household food insecurity in Canada, 2014. PROOF: Food insecurity policy research.

Return to footnote 394 referrer

Footnote 395

Food and Agriculture Organization of the United Nations. (2017). Food security statistics. Food and Agriculture Organization of the United Nations.

Return to footnote 395 referrer

Footnote 396

Carter, M. A., Dubois, L., Tremblay, M. S. (2014). Place and food insecurity: a critical review and synthesis of the literature. Public Health Nutrition, 17(1), 94-112.

Return to footnote 396 referrer

Footnote 397

Kirkpatrick, S. I., Tarasuk, V. (2010). Assessing the relevance of neighbourhood characteristics to the household food security of low-income Toronto families. Public Health Nutrition, 13(7), 1139-1148.

Return to footnote 397 referrer

Footnote 398

Guo, Y., Berrang-Ford, L., Ford, J., Lardeau, M. P., Edge, V., Patterson, K., IHACC Research Team, Harper, S. L. (2015). Seasonal prevalence and determinants of food insecurity in Iqaluit, Nunavut. International Journal of Circumpolar Health, 74(1), 27284.

Return to footnote 398 referrer

Footnote 399

Collings, P., Marten, M. G., Pearce, T., Young, A. G. (2016). Country food sharing networks, household structure, and implications for understanding food insecurity in Arctic Canada. Ecology of Food and Nutrition, 55(1), 30-49.

Return to footnote 399 referrer

Footnote 400

Skinner, K., Hanning, R. M., Metatawabin, J., Tsuji, L. J. (2014). Implementation of a community greenhouse in a remote, sub-Arctic First Nations community in Ontario, Canada: a descriptive case study. Rural and Remote Health, 14(2), 2545.

Return to footnote 400 referrer

Supportive environments

Footnote 401

Ozbay, F., Johnson, D. C., Dimoulas, E., Morgan III, C. A., Charney, D., Southwick, S. (2007). Social support and resilience to stress: from neurobiology to clinical practice. Psychiatry (Edgmont), 4(5), 35-40.

Return to footnote 401 referrer

Footnote 402

Reblin, M., Uchino, B. N. (2008). Social and emotional support and its implication for health. Current Opinion in Psychiatry, 21(2), 201.

Return to footnote 402 referrer

Footnote 403

Uchino, B. N. (2006). Social support and health: a review of physiological processes potentially underlying links to disease outcomes. Journal of Behavioral Medicine, 29(4), 377-387.

Return to footnote 403 referrer

Footnote 404

Sinha, M. (2015). Canadians' connections with family and friends. Statistics Canada.

Return to footnote 404 referrer

Footnote 405

Turcotte, M. (2015). Trends in social capital in Canada. Statistics Canada.

Return to footnote 405 referrer

Footnote 406

Cacioppo, J. T., Cacioppo, S., Capitanio, J. P., Cole, S. W. (2015). The neuroendocrinology of social isolation. Annual Review of Psychology, 66, 733-767.

Return to footnote 406 referrer

Footnote 407

Cacioppo, J. T., Cacioppo, S., Cole, S. W., Capitanio, J. P., Goossens, L., Boomsma, D. I. (2015). Loneliness across phylogeny and a call for comparative studies and animal models. Perspectives on Psychological Science, 10(2), 202-212.

Return to footnote 407 referrer

Footnote 408

Hawkley, L. C., Capitanio, J. P. (2015). Perceived social isolation, evolutionary fitness and health outcomes: a lifespan approach. Philosophical Transactions of the Royal Society of London: Series B, Biological Sciences, 370(1669).

Return to footnote 408 referrer

Footnote 409

Masi, C. M., Chen, H. Y., Hawkley, L. C., Cacioppo, J. T. (2011). A meta-analysis of interventions to reduce loneliness. Personality and Social Psychology Review, 15(3), 219-266.

Return to footnote 409 referrer

Footnote 410

Shields, M. (2008). Community belonging and self-perceived health. Statistics Canada: Catalogue no. 82-003-X Health Reports.

Return to footnote 410 referrer

Footnote 411

Statistics Canada (2002). Community belonging and health. Statistics Canada.

Return to footnote 411 referrer

Footnote 412

Statistics Canada. Table 105-0501 - Health indicator profile, annual estimates, by age group and sex, Canada, provinces, territories, health regions (2013 boundaries) and peer groups, occasional. Statistics Canada.

Return to footnote 412 referrer

Footnote 413

Brosschot, J. F., Gerin, W., Thayer, J. F. (2006). The perseverative cognition hypothesis: A review of worry, prolonged stress-related physiological activation, and health. Journal of Psychosomatic Research, 60(2), 113-124.

Return to footnote 413 referrer

Footnote 414

Glaser, R., Kiecolt-Glaser, J. K. (2005). Stress-induced immune dysfunction: implications for health. Nature Reviews Immunology, 5(3), 243-251.

Return to footnote 414 referrer

Footnote 415

Juster, R. P., McEwen, B. S., Lupien, S. J. (2010). Allostatic load biomarkers of chronic stress and impact on health and cognition. Neuroscience and Biobehavioral Reviews, 35(1), 2-16.

Return to footnote 415 referrer

Footnote 416

Marin, M. F., Lord, C., Andrews, J., Juster, R. P., Sindi, S., Arsenault-Lapierre, G., Fiocco, A.J., Lupien, S. J. (2011). Chronic stress, cognitive functioning and mental health. Neurobiology of Learning and Memory, 96(4), 583-595.

Return to footnote 416 referrer

Footnote 417

Qualter, P., Vanhalst, J., Harris, R., Van Roekel, E., Lodder, G., Bangee, M., Maes, M., Verhagen, M. (2015). Loneliness across the life span. Perspectives on Psychological Science, 10(2), 250-264.

Return to footnote 417 referrer

Footnote 418

Child, S. T., Schoffman, D. E., Kaczynski, A. T., Forthofer, M., Wilcox, S., Baruth, M. (2016). Neighborhood attributes associated with the social environment. American Journal of Health Promotion, 30(8), 634-637.

Return to footnote 418 referrer

Footnote 419

Wood, L., Frank, L. D., Giles-Corti, B. (2010). Sense of community and its relationship with walking and neighborhood design. Social Science and Medicine, 70(9), 1381-1390.

Return to footnote 419 referrer

Footnote 420

Brown, S.C., Mason, C.A., Lombard, J.L., Martinez, F., Plater-Zyberk, E., Spokane, A.R., Newman, F.L., Pantin, H., Szapocznik, J. (2009). The relationships of built environment to perceived social support and psychological distress in Hispanic elders: the role of "eyes on the street". Journal of Gerontology: series B Psychological Sciences & Social Sciences, 64B(2), 234-246.

Return to footnote 420 referrer

Footnote 421

Brown, B. B., Cropper, V. L. (2001). New urban and standard suburban subdivisions: Evaluating psychological and social goals. Journal of the American Planning Association, 67(4), 402-419.

Return to footnote 421 referrer

Footnote 422

Cabrera, J.F. (2013). New urbanism and selection bias in the formation of social capital. Housing Policy Debate, 23(2), 376-394.

Return to footnote 422 referrer

Footnote 423

Cabrera, J. F., Najarian, J. C. (2015). How the built environment shapes spatial bridging ties and social capital. Environment and Behavior, 47(3), 239-267.

Return to footnote 423 referrer

Footnote 424

Hassen, N., Kaufman, P. (2016). Examining the role of urban street design in enhancing community engagement: A literature review. Health and Place, 41, 119-132.

Return to footnote 424 referrer

Footnote 425

Kim, J., Kaplan, R. (2004). Physical and psychological factors in sense of community: New urbanist Kentlands and nearby Orchard Village. Environment and Behavior, 36(3), 313-340.

Return to footnote 425 referrer

Footnote 426

Mazumdar, S., Learnihan, V., Cochrane, T., Davey, R. (2017). The Built Environment and Social Capital: A Systematic Review. Environment and Behavior.

Return to footnote 426 referrer

Footnote 427

Leyden, K. M. (2003). Social capital and the built environment: the importance of walkable neighborhoods. American Journal of Public Health, 93(9), 1546-1551.

Return to footnote 427 referrer

Footnote 428

Lund, H. (2002). Pedestrian environments and sense of community. Journal of Planning Education and Research, 21(3), 301-312.

Return to footnote 428 referrer

Footnote 429

Mazumdar, S., Learnihan, V., Cochrane, T., Davey, R. (2017). The Built Environment and Social Capital: A Systematic Review. Environment and Behavior.

Return to footnote 429 referrer

Footnote 430

Podobnik 2002; Podobnik, B. 2002. New urbanism and the generation of social capital: Evidence from Orenco station. National Civic Review, 91(3), 245–255.

Return to footnote 430 referrer

Footnote 431

Rogers, G. O., Sukolratanametee, S. (2009). Neighborhood design and sense of community: Comparing suburban neighborhoods in Houston Texas. Landscape and Urban Planning, 92(3), 325-334.

Return to footnote 431 referrer

Footnote 432

Torres, A., Sarmiento, O. L., Stauber, C., Zarama, R. (2013). The Ciclovia and Cicloruta programs: promising interventions to promote physical activity and social capital in Bogotá, Colombia. American Journal of Public Health, 103(2), e23-e30.

Return to footnote 432 referrer

Footnote 433

Wilkerson, A., Carlson, N. E., Yen, I. H., Michael, Y. L. (2012). Neighborhood physical features and relationships with neighbors: does positive physical environment increase neighborliness?. Environment and Behavior, 44(5), 595-615.

Return to footnote 433 referrer

Footnote 434

Audirac, I. (1999). Stated preference for pedestrian proximity: an assessment of new urbanist sense of community. Journal of Planning Education and Research, 19(1), 53-66.

Return to footnote 434 referrer

Footnote 435

Grant, J., Perrott, K. (2009). Producing diversity in a new urbanism community: Policy and practice. Town Planning Review, 80(3), 267-289.

Return to footnote 435 referrer

Footnote 436

Talen, E. (1999). Sense of community and neighbourhood form: An assessment of the social doctrine of new urbanism. Urban Studies, 36(8), 1361-1379.

Return to footnote 436 referrer

Footnote 437

Talen, E. (2005). Land use zoning and human diversity: Exploring the connection. Journal of Urban Planning and Development, 131(4), 214-232.

Return to footnote 437 referrer

Footnote 438

Talen, E. (2010). Affordability in new urbanist development: Principle, practice, and strategy. Journal of Urban Affairs, 32(4), 489-510.

Return to footnote 438 referrer

Footnote 439

Tu, C. C., Eppli, M. J. (1999). Valuing new urbanism: The case of Kentlands. Real Estate Economics, 27(3), 425-451.

Return to footnote 439 referrer

Footnote 440

Tu, C. C., Eppli, M. J. (2001). An empirical examination of traditional neighborhood development. Real Estate Economics, 29(3), 485-501.

Return to footnote 440 referrer

Footnote 441

Dreger, S., Buck, C., Bolte, G. (2014). Material, psychosocial and sociodemographic determinants are associated with positive mental health in Europe: a cross-sectional study. BMJ Open, 4(5), e005095.

Return to footnote 441 referrer

Footnote 442

Evans, G. W. (2003). The built environment and mental health. Journal of Urban Health, 80(4), 536-555.

Return to footnote 442 referrer

Footnote 443

Francis, J., Wood, L. J., Knuiman, M., Giles-Corti, B. (2012). Quality or quantity? Exploring the relationship between Public Open Space attributes and mental health in Perth, Western Australia. Social Science and Medicine, 74(10), 1570-1577.

Return to footnote 443 referrer

Footnote 444

Guite, H. F., Clark, C., Ackrill, G. (2006). The impact of the physical and urban environment on mental well-being. Public Health, 120(12), 1117-1126.

Return to footnote 444 referrer

Footnote 445

Mair, C. F., Roux, A. V. D., Galea, S. (2008). Are neighborhood characteristics associated with depressive symptoms? A critical review. Journal of Epidemiology and Community Health, 62(11), 940-946.

Return to footnote 445 referrer

Footnote 446

Roe, J. J., Thompson, C. W., Aspinall, P. A., Brewer, M. J., Duff, E. I., Miller, D., Mitchell, R. Clow, A. (2013). Green space and stress: evidence from cortisol measures in deprived urban communities. International Journal of Environmental Research and Public Health, 10(9), 4086-4103.

Return to footnote 446 referrer

Footnote 447

Sugiyama, T., Leslie, E., Giles-Corti, B., Owen, N. (2008). Associations of neighbourhood greenness with physical and mental health: do walking, social coherence and local social interaction explain the relationships?. Journal of Epidemiology and Community Health, 62(5), e9.

Return to footnote 447 referrer

Footnote 448

Gariepy, G., Kaufman, J. S., Blair, A., Kestens, Y., Schmitz, N. (2015). Place and health in diabetes: the neighbourhood environment and risk of depression in adults with Type 2 diabetes. Diabetic Medicine, 32(7), 944-950.

Return to footnote 448 referrer

Footnote 449

Gariepy, G., Thombs, B. D., Kestens, Y., Kaufman, J. S., Blair, A., Schmitz, N. (2015). The neighbourhood built environment and trajectories of depression symptom episodes in adults: A latent class growth analysis. PloS One, 10(7), e0133603.

Return to footnote 449 referrer

Footnote 450

Gariepy, G., Blair, A., Kestens, Y., Schmitz, N. (2014). Neighbourhood characteristics and 10-year risk of depression in Canadian adults with and without a chronic illness. Health and Place, 30, 279-286.

Return to footnote 450 referrer

Footnote 451

Statistics Canada (2011). Commuting to work. NHS in Brief. Statistics Canada.

Return to footnote 451 referrer

Footnote 452

Cassidy, T. (1992). Commuting-relating stress: consequences and implications. Employee Counselling Today, 4(2), 15-21.

Return to footnote 452 referrer

Footnote 453

Costa, G., Pickup, L., Di Martino, V. (1988). Commuting – a further stress factor for working people : evidence from the European community. I. A review. International Archives of Occupational and Environmental Health, 60(5), 371-376.

Return to footnote 453 referrer

Footnote 454

Costa, G., Pickup, L., Di Martino, V. (1988). Commuting – a further stress factor for working people : evidence from the European Community. II. An empirical study. International Archives of Occupational and Environmental Health, 60(5), 377-385.

Return to footnote 454 referrer

Footnote 455

Evans, G.W., Wener, R.E., Phillips, D. (2002). The morning rush hour: predictability and commuter stress. Environment and Behavior, 34(4).

Return to footnote 455 referrer

Footnote 456

Gottholmseder, G., Nowotny, K., Pruckner, G.J., Theurl, E. (2008). Stress perception and commuting. Health Economics, 18(5), 559-576.

Return to footnote 456 referrer

Footnote 457

Lucas, J.L., Heady, R.B. (2002). Flextime commuters and their driver stress, feelings of time urgency, and commute satisfaction. Journal of Business and Psychology, 16(4), 565-571.

Return to footnote 457 referrer

Footnote 458

Milner, A., Badland, H., Kavanagh, A., LaMontagne, A.D. (2017). Time spent commuting to work and mental health: evidence from 13 waves of an Australian cohort study. American Journal of Epidemiology, 27, 1-9.

Return to footnote 458 referrer

Footnote 459

Novaco, R.W., Stokols, D., Campbell, J., Stokols, J. (1979). Transportation, stress and community psychology. American Journal of Community Psychology, 7(4), 361-380.

Return to footnote 459 referrer

Footnote 460

Novaco, R.W., Stokols, D., Milanesi, L. (1990). Objective and subjective dimensions of travel impedance as determinants of commuting stress. American Journal of Community Psychology, 18(2), 231-257.

Return to footnote 460 referrer

Footnote 461

Schaeffer, M.H., Street, S.W., Singer, J.E., Baum, A. (1988). Effects of control on the stress reaction of commuters. Journal of Applied Social Psychology, 18(11), 944-957.

Return to footnote 461 referrer

Footnote 462

Cantwell, M., Caulfield, B., O'Mahony, M. (2009). Examining the factors that impact public transport commuting satisfaction. Journal of Public Transportation, 12(2).

Return to footnote 462 referrer

Footnote 463

Lundberg, U. (2010). Urban commuting : crowdedness and catecholamine excretion. Journal of Human Stress, 2(3), 26-32.

Return to footnote 463 referrer

Footnote 464

Wener, R., Evans, G., Boately, P. (2014). Commuting stress: psychophysiological effects of a trip and spillover into the workplace. Transportation Research Record, 1924.

Return to footnote 464 referrer

Footnote 465

Wener, R.E., Evans, G.W., Phillips, D., Nadler, N. (2003). Running for the 7:45: the effects of public transit improvements on commuter stress. Transportation, 30(2), 203-220.

Return to footnote 465 referrer

Footnote 466

Olsson, L.E., Garling, T., Ettema, D., Friman, M., Fujii, S. (2013). Happiness and satisfaction with work commute. Social Indicators Research, 111(1), 255-263.

Return to footnote 466 referrer

Footnote 467

Van Hooff, M.L. (2015). The daily commute from work to home: examining employees' experiences in relation to their recovery status. Stress Health, 31(2), 124-137.

Return to footnote 467 referrer

Footnote 468

Gascon, M., Triguero-Mas, M., Martínez, D., Dadvand, P., Rojas-Rueda, D., Plasència, A., Nieuwenhuijsen, M. J. (2016). Residential green spaces and mortality: a systematic review. Environment International, 86, 60-67.

Return to footnote 468 referrer

Footnote 469

Kabisch, N., Qureshi, S., Haase, D. (2015). Human–environment interactions in urban green spaces—A systematic review of contemporary issues and prospects for future research. Environmental Impact Assessment Review, 50, 25-34.

Return to footnote 469 referrer

Footnote 470

Maas, J., Verheij, R. A., de Vries, S., Spreeuwenberg, P., Schellevis, F. G., Groenewegen, P. P. (2008). Morbidity is related to a green living environment. Journal of Epidemiology and Community Health, 63(12), 967-973.

Return to footnote 470 referrer

Footnote 471

Van den Berg, A. E., Maas, J., Verheij, R. A., Groenewegen, P. P. (2010). Green space as a buffer between stressful life events and health. Social Science and Medicine, 70(8), 1203-1210.

Return to footnote 471 referrer

Footnote 472

van den Berg, M., Wendel-Vos, W., van Poppel, M., Kemper, H., van Mechelen, W., Maas, J. (2015). Health benefits of green spaces in the living environment: A systematic review of epidemiological studies. Urban Forestry and Urban Greening, 14(4), 806-816.

Return to footnote 472 referrer

Footnote 473

Villeneuve, P. J., Jerrett, M., Su, J. G., Burnett, R. T., Chen, H., Wheeler, A. J., Goldberg, M. S. (2012). A cohort study relating urban green space with mortality in Ontario, Canada. Environmental Research, 115, 51-58.

Return to footnote 473 referrer

Footnote 474

Dadvand, P., de Nazelle, A., Triguero-Mas, M., Schembari, A., Cirach, M., Amoly, E., Figueras, F., Basagaña, X., Ostro, B., Nieuwenhuijsen, M. (2012). Surrounding greenness and exposure to air pollution during pregnancy: an analysis of personal monitoring data. Environmental Health Perspectives, 120(9), 1286.

Return to footnote 474 referrer

Footnote 475

Demoury, C., Thierry, B., Richard, H., Sigler, B., Kestens, Y., Parent, M. E. (2017). Residential greenness and risk of prostate cancer: A case-control study in Montreal, Canada. Environment International, 98, 129-136.

Return to footnote 475 referrer

Footnote 476

Hystad, P., Davies, H. W., Frank, L., Van Loon, J., Gehring, U., Tamburic, L., Brauer, M. (2014). Residential greenness and birth outcomes: evaluating the influence of spatially correlated built-environment factors. Environmental Health Perspectives, 122(10), 1095.

Return to footnote 476 referrer

Footnote 477

Laurent, O., Wu, J., Li, L., Milesi, C. (2013). Green spaces and pregnancy outcomes in Southern California. Health and Place, 24, 190-195.

Return to footnote 477 referrer

Footnote 478

Markevych, I., Thiering, E., Fuertes, E., Sugiri, D., Berdel, D., Koletzko, S., von Berg, A., Bauer, C.P., Heinrich, J. (2014). A cross-sectional analysis of the effects of residential greenness on blood pressure in 10-year old children: results from the GINIplus and LISAplus studies. BMC Public Health, 14(1), 477.

Return to footnote 478 referrer

Footnote 479

Markevych, I., Fuertes, E., Tiesler, C. M., Birk, M., Bauer, C. P., Koletzko, S., von Berg, A., Berdel, D., Heinrich, J. (2014). Surrounding greenness and birth weight: results from the GINIplus and LISAplus birth cohorts in Munich. Health and Place, 26, 39-46.

Return to footnote 479 referrer

Footnote 480

McMorris, O., Villeneuve, P. J., Su, J., Jerrett, M. (2015). Urban greenness and physical activity in a national survey of Canadians. Environmental Research, 137, 94-100.

Return to footnote 480 referrer

Footnote 481

Pereira, G., Foster, S., Martin, K., Christian, H., Boruff, B. J., Knuiman, M., Giles-Corti, B. (2012). The association between neighborhood greenness and cardiovascular disease: an observational study. BMC Public Health, 12, 466.

Return to footnote 481 referrer

Footnote 482

Bell, S. L., Phoenix, C., Lovell, R., Wheeler, B. W. (2014). Green space, health and wellbeing: Making space for individual agency. Health and Place, 30, 287-292.

Return to footnote 482 referrer

Footnote 483

Maas, J., van Dillen, S.M.E., Verheij, R.A., Groenewegen, P.P. (2009). Social contacts as a possible mechanism behind the relation between green space and health. Health and Place, 15(2), 586-595.

Return to footnote 483 referrer

Footnote 484

Astell-Burt, T., Mitchell, R., Hartig, T. (2014). The association between green space and mental health varies across the lifecourse. A longitudinal study. Journal of Epidemiology and Community Health, 68(6), 578-583.

Return to footnote 484 referrer

Footnote 485

Organisation mondiale de la Santé (2011). Burden of disease from environmental noise. Organisation mondiale de la Santé, Bureau régional de l'Europe.

Return to footnote 485 referrer

Footnote 486

Clark, C., Crombie, R., Head, J., Van Kamp, I., Van Kempen, E., Stansfeld, S. A. (2012). Does traffic-related air pollution explain associations of aircraft and road traffic noise exposure on children's health and cognition? A secondary analysis of the United Kingdom sample from the RANCH project. American Journal of Epidemiology, 176(4), 327-337.

Return to footnote 486 referrer

Footnote 487

Hammer, M. S., Swinburn, T. K., Neitzel, R. L. (2014). Environmental noise pollution in the United States: developing an effective public health response. Environmental Health Perspectives, 122(2), 115.

Return to footnote 487 referrer

Footnote 488

Holzman, D.C. (2014). Fighting noise pollution: a public health strategy. Environmental Health Perspectives, 122(2), A58.

Return to footnote 488 referrer

Footnote 489

Stansfeld, S.A., Matheson, M.P. (2003). Noise pollution: non-auditory effects on health. British Medical Bulletin, 68, 243-257.

Return to footnote 489 referrer

Footnote 490

Tétreault, L. F., Perron, S., Smargiassi, A. (2013). Cardiovascular health, traffic-related air pollution and noise: are associations mutually confounded? A systematic review. International Journal of Public Health, 58(5), 649-666.

Return to footnote 490 referrer

Footnote 491

Vienneau, D., Perez, L., Schindler, C., Lieb, C., Sommer, H., Probst-Hensch, N., Künzli, N., Röösli, M. (2015). Years of life lost and morbidity cases attributable to transportation noise and air pollution: A comparative health risk assessment for Switzerland in 2010. International Journal of Hygiene and Environmental Health, 218(6), 514-521.

Return to footnote 491 referrer

Footnote 492

Nanda, U., Eisen, S., Zadeh, R. S., Owen, D. (2011). Effect of visual art on patient anxiety and agitation in a mental health facility and implications for the business case. Journal of Psychiatric and Mental Health Nursing, 18(5), 386-393.

Return to footnote 492 referrer

Footnote 493

Nanda, U., Chanaud, C., Nelson, M., Zhu, X., Bajema, R., Jansen, B. H. (2012). Impact of visual art on patient behavior in the emergency department waiting room. The Journal of Emergency Medicine, 43(1), 172-181.

Return to footnote 493 referrer

Footnote 494

Nanda, U., Pati, D., McCurry, K. (2009). Neuroesthetics and healthcare design. HERD: Health Environments Research and Design Journal, 2(2), 116-133.

Return to footnote 494 referrer

Footnote 495

Clift, S. (2012). Creative arts as a public health resource: moving from practice-based research to evidence-based practice. Perspectives in Public Health, 132(3), 120-127.

Return to footnote 495 referrer

Footnote 496

Cameron, M., Crane, N., Ings, R., Taylor, K. (2013). Promoting well-being through creativity: how arts and public health can learn from each other. Perspectives in Public Health, 133(1), 52-59.

Return to footnote 496 referrer

Footnote 497

Mohatt, N. V., Singer, J. B., Evans, A. C., Matlin, S. L., Golden, J., Harris, C., Burns, J., Siciliano, C., Kiernan, G., Pelleritti, M., Tebes, J. K. (2013). A community's response to suicide through public art: Stakeholder perspectives from the Finding the Light Within project. American Journal of Community Psychology, 52(1-2), 197-209.

Return to footnote 497 referrer

Footnote 498

Mohatt, N. V., Hunter, B. A., Matlin, S. L., Golden, J., Evans, A. C., Tebes, J. K. (2015). From recovery-oriented care to public health: Case studies of participatory public art as a pathway to wellness for persons with behavioral health challenges. Journal of Psychosocial Rehabilitation and Mental Health, 2(1), 9-18.

Return to footnote 498 referrer

Footnote 499

Semenza, J. C. (2003). The intersection of urban planning, art and public health : the Sunnyside Piazza. AJPH, 93(9), 1439-1441.

Return to footnote 499 referrer

Footnote 500

Dempsey, N. (2008). Quality of the built environment in urban neighbourhoods. Planning, Practice and Research, 23(2), 249-264.

Return to footnote 500 referrer

Footnote 501

Ivey, S. L., Kealey, M., Kurtovich, E., Hunter, R. H., Prohaska, T. R., Bayles, C. M., Satariano, W. A. (2015). Neighborhood characteristics and depressive symptoms in an older population. Aging and Mental Health, 19(8), 713-722.

Return to footnote 501 referrer

Footnote 502

Stafford, M., Chandola T., Marmot M. (2007). Association between fear of crime and mental health and physical functioning. American Journal of Public Health, 97 (11), 2076-2018.

Return to footnote 502 referrer

Footnote 503

Foster, S., Hooper, P., Knuiman, M., Giles-Corti, B. (2016). Does heightened fear of crime lead to poorer mental health in new suburbs, or vice versa?. Social Science and Medicine, 168, 30-34.

Return to footnote 503 referrer

Footnote 504

Lorenc, T., Clayton, S., Neary, D., Whitehead, M., Petticrew, M., Thomson, H., Cummins, S., Sowden, A., Renton, A. (2012). Crime, fear of crime, environment, and mental health and wellbeing: mapping review of theories and causal pathways. Health and Place, 18(4), 757-765.

Return to footnote 504 referrer

Footnote 505

Lorenc, T., Petticrew, M., Whitehead, M., Neary, D., Clayton, S., Wright, K., Thomson, H., Cummins, S., Sowden, A., Renton, A. (2014). Crime, fear of crime and mental health: synthesis of theory and systematic reviews of interventions and qualitative evidence. Public Health Research, 2(2).

Return to footnote 505 referrer

Footnote 506

Foster, S., Giles-Corti, B. (2008). The built environment, neighborhood crime and constrained physical activity: an exploration of inconsistent findings. Preventive Medicine, 47(3), 241-251.

Return to footnote 506 referrer

Footnote 507

Ross, C. E., Jang, S. J. (2000). Neighborhood disorder, fear, and mistrust: The buffering role of social ties with neighbors. American Journal of Community Psychology, 28(4), 401-420.

Return to footnote 507 referrer

Footnote 508

Cozens, P. M. (2011). Urban planning and environmental criminology: Towards a new perspective for safer cities. Planning Practice and Research, 26(4), 481-508.

Return to footnote 508 referrer

Footnote 509

Statistics Canada (2015). Self-reported victimization, 2014. The Daily. Statistics Canada.

Return to footnote 509 referrer

Footnote 510

Cozens, P., Love, T. (2015). A review and current status of Crime Prevention through Environmental Design (CPTED). Journal of Planning Literature, 30(4).

Return to footnote 510 referrer

Footnote 511

Shariati, A., Guerette, R. T. (2017). Situational Crime Prevention. In Preventing Crime and Violence (pp. 261-268). Springer International Publishing.

Return to footnote 511 referrer

Footnote 512

Cozens, P. (2007). Public health and the potential benefits of crime prevention through environmental design. New South Wales Public Health Bulletin, 18(12), 232-237.

Return to footnote 512 referrer

Footnote 513

Cozens, P.M. (2008). New urbanism, crime and the suburbs: A review of the evidence. Urban Policy and Research, 26(4), 429-444.

Return to footnote 513 referrer

Footnote 514

Carter, S. P., Carter, S. L., Dannenberg, A. L. (2003). Zoning out crime and improving community health in Sarasota, Florida:"crime prevention through environmental design". American Journal of Public Health, 93(9), 1442-1445.

Return to footnote 514 referrer

Footnote 515

Casteel, C., Peek-Asa, C., Howard, J., Kraus, J. F. (2004). Effectiveness of crime prevention through environmental design in reducing criminal activity in liquor stores: a pilot study. Journal of Occupational and Environmental Medicine, 46(5), 450-458.

Return to footnote 515 referrer

Footnote 516

Casteel, C., Peek-Asa, C. (2000). Effectiveness of crime prevention through environmental design (CPTED) in reducing robberies. American Journal of Preventive Medicine, 18(4), 99-115.

Return to footnote 516 referrer

Footnote 517

Freilich, J.D. (2014). Beccaria and situational crime prevention. Criminal Justice Review, 40(2), 131-150.

Return to footnote 517 referrer

Footnote 518

Huisman, W., van Erp, J. (2013). Opportunities for environmental crime: A test of situational crime prevention theory. British Journal of Criminology, 53(6), 1178-1200.

Return to footnote 518 referrer

Footnote 519

Lorenc, T., Petticrew, M., Whitehead, M., Neary, D., Clayton, S., Wright, K., Thomson, H., Cummins, S., Sowden, A., Renton, A. (2013). Environmental interventions to reduce fear of crime: systematic review of effectiveness. Systematic Reviews, 2(1), 30.

Return to footnote 519 referrer

Design features for specific populations

Footnote 520

Durand, C.P., Andalib, M., Dunton, G.F. , Wolch, J., Pentz, M.A. (2011). A systematic review of built environment factors related to physical activity and obesity risk: implications for smart growth urban planning. Obesity Reviews, 12(501), e173-e182.

Return to footnote 520 referrer

Footnote 521

Public Health Agency of Canada (2015). Health behaviour in school-aged children in Canada: focus on relationships. Public Health Agency of Canada.

Return to footnote 521 referrer

Footnote 522

Freeman, J.G., King, M., Pickett, W., Craig, W., Elgar, F., Janssen, I., Klinger, D. (2011). The health of Canada's young people: a mental health focus. Public Health Agency of Canada.

Return to footnote 522 referrer

Footnote 523

Janssen, I., Rosu, A. (2015). Undeveloped green space and free-time physical activity in 11 to 13-year-old children. International Journal of Behavioral Nutrition & Physical Activity, 12, 26.

Return to footnote 523 referrer

Footnote 524

McGrath, L. J., Hopkins, W. G., Hinckson, E. A. (2015). Associations of objectively measured built-environment attributes with youth moderate–vigorous physical activity: a systematic review and meta-analysis. Sports Medicine, 45(6), 841-865.

Return to footnote 524 referrer

Footnote 525

Janssen, I., King, N. (2015). Walkable school neighborhoods are not playable neighborhoods. Health and Place, 35, 66-69.

Return to footnote 525 referrer

Footnote 526

Brussoni, M., Olsen, L.L., Pike, I., Sleet, D.A. (2012). Risky play and children's safety: balancing priorities for optimal child development. International Journal of Environmental Research & Public Health, 9(9), 3134-3148.

Return to footnote 526 referrer

Footnote 527

Brussoni, M., Gibbons, R., Gray, C., Ishikawa, T., Sandseter, E.B., Bienenstock, A., Chabot, G., Fuselli, P., Herrington, S., Janssen, I., Pickett, W., Power, M., Sanger, N., Sampson, M., Tremblay M.S. (2015). What is the relationship between risky outdoor play and health in children? A systematic review. International Journal of Environmental Research & Public Health, 12(6), 6423-6454.

Return to footnote 527 referrer

Footnote 528

Sandercock, G., Angus, C., Barton, J. (2010). Physical activity levels of children living in different built environments. Preventive Medicine, 50(4), 193-198.

Return to footnote 528 referrer

Footnote 529

Esteban-Cornejo, I., Carlson, J. A., Conway, T. L., Cain, K. L., Saelens, B. E., Frank, L. D., Glanz, K., Roman, C.G., Sallis, J. F. (2016). Parental and adolescent perceptions of neighborhood safety related to adolescents' physical activity in their neighborhood. Research Quarterly for Exercise and Sport, 87(2), 191-199.

Return to footnote 529 referrer

Footnote 530

Carver, A., Timperio, A., Hesketh, K., Crawford, D. (2010). Are children and adolescents less active if parents restrict their physical activity and active transport due to perceived risk?. Social Science and Medicine, 70(11), 1799-1805.

Return to footnote 530 referrer

Footnote 531

Cutumisu, N., Bélanger-Gravel, A., Laferté, M., Lagarde, F., Lemay, J. F., Gauvin, L. (2014). Influence of area deprivation and perceived neighbourhood safety on active transport to school among urban Quebec preadolescents. Canadian Journal of Public Health, 105(5), e376-e382.

Return to footnote 531 referrer

Footnote 532

Giles-Corti, B., Kelty, S. F., Zubrick, S. R., Villanueva, K. P. (2009). Encouraging walking for transport and physical activity in children and adolescents. Sports Medicine, 39(12), 995-1009.

Return to footnote 532 referrer

Footnote 533

Loptson, K., Ridalls, T. (2012). Walkable for whom? Examining the role of the built environment on the neighbourhood-based physical activity of children. Canadian Journal of Public Health, 103(Suppl 3), S29.

Return to footnote 533 referrer

Footnote 534

Tappe, K. A., Glanz, K., Sallis, J. F., Zhou, C., Saelens, B. E. (2013). Children's physical activity and parents' perception of the neighborhood environment: neighborhood impact on kids study. International Journal of Behavioral Nutrition and Physical Activity, 10(1), 39.

Return to footnote 534 referrer

Footnote 535

Lavoie, M., Burigusa, G., Maurice, P., Hamel, D., Turmel, É. (2014). Active and safe transportation of elementary-school students: comparative analysis of the risks of injury associated with children travelling by car, walking and cycling between home and school. Chronic Diseases and Injuries in Canada, 34(4), 195-202.

Return to footnote 535 referrer

Footnote 536

van Loon, J., Frank, L. D., Nettlefold, L., Naylor, P. J. (2014). Youth physical activity and the neighbourhood environment: examining correlates and the role of neighbourhood definition. Social Science and Medicine, 104, 107-115.

Return to footnote 536 referrer

Footnote 537

Audrey, S., Batista-Ferrer, H. (2015). Healthy urban environments for children and young people: a systematic review of intervention studies. Health and Place, 36, 97-117.

Return to footnote 537 referrer

Footnote 538

Carver, A., Timperio, A., Hesketh, K., Crawford, D. (2010). Are safety-related features of the road environment associated with smaller declines in physical activity among youth?. Journal of Urban Health, 87(1), 29-43.

Return to footnote 538 referrer

Footnote 539

Rothman, L., Buliung, R., Macarthur, C., To, T., Howard, A. (2014). Walking and child pedestrian injury: a systematic review of built environment correlates of safe walking. Injury Prevention, 20(1), 41-49.

Return to footnote 539 referrer

Footnote 540

Kneeshaw-Price, S. H., Saelens, B. E., Sallis, J. F., Frank, L. D., Grembowski, D. E., Hannon, P. A., Smith, N.L., Chan, K. G. (2015). Neighborhood crime-related safety and its relation to children's physical activity. Journal of Urban Health, 92(3), 472-489.

Return to footnote 540 referrer

Footnote 541

Barnes, J. D., Cameron, C., Carson, V., Chaput, J. P., Faulkner, G. E., Janson, K., Kramers, R., LeBlanc, A.G., Spence, J.C., Tremblay, M. S. (2016). Results from Canada's 2016 ParticipACTION report card on physical activity for children and youth. Journal of Physical Activity and Health, 13(11 Suppl 2), S110-S116.

Return to footnote 541 referrer

Footnote 542

Faulkner, G. E., Buliung, R. N., Flora, P. K., Fusco, C. (2009). Active school transport, physical activity levels and body weight of children and youth: a systematic review. Preventive Medicine, 48(1), 3-8.

Return to footnote 542 referrer

Footnote 543

Lee, M. C., Orenstein, M. R., Richardson, M. J. (2008). Systematic review of active commuting to school and children's physical activity and weight. Journal of Physical Activity and Health, 5(6), 930-949.

Return to footnote 543 referrer

Footnote 544

Voss, C., Winters, M., Frazer, A., and McKay, H. (2015). School-travel by public transit: rethinking active transportation. Preventive Medicine Reports, 2, 65-70.

Return to footnote 544 referrer

Footnote 545

Coalitions Linking Action and Science for Prevention (2012). Children's Mobility, Health and Happiness: a Canadian School Travel Planning Model: 2012 national results – executive summary. Coalitions Linking Action and Science for Prevention.

Return to footnote 545 referrer

Footnote 546

Larouche, R. (2015). Built environment features that promote cycling in school-aged children. Current Obesity Reports, 4(4), 494-503.

Return to footnote 546 referrer

Footnote 547

Larouche, R., Barnes, J., Tremblay, M. S. (2013). Too far to walk or bike?. Canadian Journal of Public Health, 104(7), 487-489.

Return to footnote 547 referrer

Footnote 548

Larouche, R., Chaput, J. P., Leduc, G., Boyer, C., Bélanger, P., LeBlanc, A. G., Borghese, M.M., Tremblay, M. S. (2014). A cross-sectional examination of socio-demographic and school-level correlates of children's school travel mode in Ottawa, Canada. BMC Public Health, 14(1), 497.

Return to footnote 548 referrer

Footnote 549

Faulkner, G. E., Richichi, V., Buliung, R. N., Fusco, C., Moola, F. (2010). What's "quickest and easiest?": parental decision making about school trip mode. International Journal of Behavioral Nutrition and Physical Activity, 7(1), 62.

Return to footnote 549 referrer

Footnote 550

Gropp, K. M., Pickett, W., Janssen, I. (2012). Multi-level examination of correlates of active transportation to school among youth living within 1 mile of their school. International Journal of Behavioral Nutrition and Physical Activity, 9(1), 124.

Return to footnote 550 referrer

Footnote 551

Gropp, K., Janssen, I., Pickett, W. (2013). Active transportation to school in Canadian youth: should injury be a concern?. Injury Prevention, 19(1), 64-67.

Return to footnote 551 referrer

Footnote 552

Larsen, K., Gilliland, J., Hess, P. M. (2011). Route-based analysis to capture the environmental influences on a child's mode of travel between home and school. Annals of the Association of American Geographers, 102(6), 1348-1365.

Return to footnote 552 referrer

Footnote 553

Mitra, R., Buliung, R. N. (2012). Built environment correlates of active school transportation: neighborhood and the modifiable areal unit problem. Journal of Transport Geography, 20(1), 51-61.

Return to footnote 553 referrer

Footnote 554

Oliver, M., Badland, H., Mavoa, S., Witten, K., Kearns, R., Ellaway, A., Hinckson, E., Mackay, L., Schluter, P. J. (2014). Environmental and socio-demographic associates of children's active transport to school: a cross-sectional investigation from the URBAN Study. International Journal of Behavioral Nutrition and Physical Activity, 11(1), 70.

Return to footnote 554 referrer

Footnote 555

Trapp, G. S., Giles-Corti, B., Christian, H. E., Bulsara, M., Timperio, A. F., McCormack, G. R., Villaneuva, K. P. (2011). On your bike! a cross-sectional study of the individual, social and environmental correlates of cycling to school. International Journal of Behavioral Nutrition and Physical Activity, 8(1), 123.

Return to footnote 555 referrer

Footnote 556

Wong, B. Y. M., Faulkner, G., Buliung, R. (2011). GIS measured environmental correlates of active school transport: a systematic review of 14 studies. International Journal of Behavioral Nutrition and Physical Activity, 8(1), 39.

Return to footnote 556 referrer

Footnote 557

Seliske, L., Pickett, W., Janssen, I. (2012). Urban sprawl and its relationship with active transportation, physical activity and obesity in Canadian youth. Health Reports, 23(2), 17-25.

Return to footnote 557 referrer

Footnote 558

Garriguet, D., Colley, R., Bushnik, T. (2017). Parent-child association in physical activity and sedentary behaviour. Health Reports. Statistics Canada.

Return to footnote 558 referrer

Footnote 559

Carlson, J. A., Sallis, J. F., Kerr, J., Conway, T. L., Cain, K., Frank, L. D., Saelens, B. E. (2014). Built environment characteristics and parent active transportation are associated with active travel to school in youth age 12–15. British Journal of Sports Medicine, 48(22), 1634-1639.

Return to footnote 559 referrer

Footnote 560

Henne, H. M., Tandon, P. S., Frank, L. D., Saelens, B. E. (2014). Parental factors in children's active transport to school. Public Health, 128(7), 643-646.

Return to footnote 560 referrer

Footnote 561

Cutumisu, N., Traoré, I., Paquette, M. C., Cazale, L., Camirand, H., Lalonde, B., Robitaille, E. (2017). Association between junk food consumption and fast-food outlet access near school among Quebec secondary-school children: findings from the Quebec Health Survey of High School Students (QHSHSS) 2010–11. Public Health Nutrition, 20(5), 927-937.

Return to footnote 561 referrer

Footnote 562

Van Hulst, A., Barnett, T. A., Gauvin, L., Daniel, M., Kestens, Y., Bird, M., Gray-Donald, K., Lambert, M. (2012). Associations between children's diets and features of their residential and school neighbourhood food environments. Canadian Journal of Public Health, 103(9), 48-54.

Return to footnote 562 referrer

Footnote 563

He, M., Tucker, P., Irwin, J. D., Gilliland, J., Larsen, K., Hess, P. (2012). Obesogenic neighbourhoods: the impact of neighbourhood restaurants and convenience stores on adolescents' food consumption behaviours. Public Health Nutrition, 15(12), 2331-2339.

Return to footnote 563 referrer

Footnote 564

He, M., Tucker, P., Gilliland, J., Irwin, J. D., Larsen, K., Hess, P. (2012). The influence of local food environments on adolescents' food purchasing behaviors. International Journal of Environmental Research and Public Health, 9(4), 1458-1471.

Return to footnote 564 referrer

Footnote 565

Sadler, R. C., Clark, A. F., Wilk, P., O'Connor, C., Gilliland, J. A. (2016). Using GPS and activity tracking to reveal the influence of adolescents' food environment exposure on junk food purchasing. Canadian Journal of Public Health, 107, 14-20.

Return to footnote 565 referrer

Footnote 566

Christian, H., Zubrick, S. R., Foster, S., Giles-Corti, B., Bull, F., Wood, L., Knuiman, M., Brinkman, S., Houghton, S., Boruff, B. (2015). The influence of the neighborhood physical environment on early child health and development: A review and call for research. Health and Place, 33, 25-36.

Return to footnote 566 referrer

Footnote 567

Villanueva, K., Badland, H., Kvalsvig, A., O'Connor, M., Christian, H., Woolcock, G., Giles-Corti, B., Goldfeld, S. (2016). Can the neighborhood built environment make a difference in children's development? Building the research agenda to create evidence for place-based children's policy. Academic Pediatrics, 16(1), 10-19.

Return to footnote 567 referrer

Footnote 568

Agay-Shay, K., Peled, A., Crespo, A. V., Peretz, C., Amitai, Y., Linn, S., Friger, M., Nieuwenhuijsen, M. J. (2014). Green spaces and adverse pregnancy outcomes. Occupational and Environmental Medicine, 71(8), 562-569.

Return to footnote 568 referrer

Footnote 569

Ebisu, K., Holford, T. R., Bell, M. L. (2016). Association between greenness, urbanicity, and birth weight. Science of The Total Environment, 542, 750-756.

Return to footnote 569 referrer

Footnote 570

Mitchell, C. A., Clark, A. F., Gilliland, J. A. (2016). Built environment influences of children's physical activity: examining differences by neighbourhood size and sex. International Journal of Environmental Research and Public Health, 13(1), 130.

Return to footnote 570 referrer

Footnote 571

Larouche, R., Garriguet, D., Gunnell, K.E., Goldfield, G.S., Tremblay, M.S. (2016). Outdoor time, physical activity, sedentary time, and health indicators at ages 7 to 14: 2012/2013 Canadian Health Measures Survey. Health Reports. Statistics Canada.

Return to footnote 571 referrer

Footnote 572

International Weight Management in Pregnancy Collaborative Group (2017). Effect of diet and physical activity based interventions in pregnancy on gestational weight gain and pregnancy outcomes: meta-analysis of individual participant data from randomised trials. BMJ, 358, j3119.

Return to footnote 572 referrer

Footnote 573

Ruifrok, A.E., van Poppel, M.N., van Wely, M., Rogozinska, E., Khan, K.S., de Groot, C.J., Thangaratinam, S., Mol, B.W. (2014). Association between weight gain during pregnancy and pregnancy outcomes after dietary and lifestyle interventions: a meta-analysis. American Journal of Perinatology, 31(5), 353-364.

Return to footnote 573 referrer

Footnote 574

Margerison Zilko, C.E., Rehkopf, D., Arbams, B. (2010). Association of maternal gestational weight gain with short- and long-term maternal and child health outcomes. American Journal of Obstetrics & Gynecology, 202(6), 574.

Return to footnote 574 referrer

Footnote 575

Siega-Riz, A.M., Viswanathan, M., Moos, M.K., Deierlein, A., Mumford, S., Knaack, J., Thieda, P., Lux, L.J., Lohr, K.N. (2009). A systematic review of outcomes of maternal weight gain according to the Institute of Medicine recommendations: birthweight, fetal growth, and postpartum weight retention. American Journal of Obstetrics & Gynecology, 201(4), 339.

Return to footnote 575 referrer

Footnote 576

Lau, E.Y., Liu, J., Archer, E., McDonald, S.M., Liu, J. (2014). Maternal weight gain in pregnancy and risk of obesity among offspring: a systematic review. Journal of Obesity, 524939.

Return to footnote 576 referrer

Footnote 577

Saligheh, M., Hackett, D., Boyce, P. Cobley, S. (2017). Can exercise or physical activity help improve postnatal depression and weight loss? A systematic review. Archives of Women's Mental Health, epub.

Return to footnote 577 referrer

Footnote 578

Poyatos-Leon, R., Garcia-Hermoso, A., Sanabria-Martinez, G., Alvarez-Bueno, C., Cavero-Redondo, I., Martinez-Vizcaino, V. (2017). Effects of exercise-based interventions on postpartum depression: a meta-analysis of randomized controlled trials. Birth, epub.

Return to footnote 578 referrer

Footnote 579

McCurdy, A.P., Boule, N.G., Sivak, A., Davenport, M.H. (2017). Effects of exercise on mild-to-moderate depressive symptoms in the postpartum period: a meta-analysis. Obstetrics & Gynecology, 129(6), 1087-1097.

Return to footnote 579 referrer

Footnote 580

Lim, S., O'Reilly, S., Behrens, J., Skinner, T., Ellis, I., Dunbar, J.A. (2015). Effective strategies for weight loss in post-partum women: a systematic review and meta-analysis. Obesity Reviews, 16(11), 972-987.

Return to footnote 580 referrer

Footnote 581

Baskin, R., Hill, B., Jacka, F.N., O'Neil, A. Skouteris, H. (2015). The association between diet quality and mental health during the perinatal period. a systematic review. Appetite, 91, 41-47.

Return to footnote 581 referrer

Footnote 582

Endres, L.K., Straub, H., McKinney, C., Plunkett, B., Minkovitz, C.S., Schetter, C.D., Ramey, S., Wang, C., Hobel, C., Raju, T., Shalowitz, M.U. (2015). Postpartum weight retention risk factors and relationship to obesity at one year. Obstetrics & Gynecology, 125(1), 144-152.

Return to footnote 582 referrer

Footnote 583

Nehring, I., Schmoll, S., Beyerlein, A., Hauner, H., von Kries, R. (2011). Gestational weight gain and long-term postpartum weight retention: a meta-analysis. American Journal of Clinical Nutrition, 94(5), 1225-1231.

Return to footnote 583 referrer

Footnote 584

Lord, S., Luxembourg, N. (2008). The mobility of elderly residents living in suburban territories: mobility experiences in Canada and France. Journal of Housing for the Elderly, 20(4), 103-121.

Return to footnote 584 referrer

Footnote 585

McPhee, J. S., French, D. P., Jackson, D., Nazroo, J., Pendleton, N., Degens, H. (2016). Physical activity in older age: perspectives for healthy ageing and frailty. Biogerontology, 17(3), 567-580.

Return to footnote 585 referrer

Footnote 586

Vogel, T., Brechat, P. H., Leprêtre, P. M., Kaltenbach, G., Berthel, M., Lonsdorfer, J. (2009). Health benefits of physical activity in older patients: a review. International Journal of Clinical Practice, 63(2), 303-320.

Return to footnote 586 referrer

Footnote 587

Yen, I. H., Michael, Y. L., Perdue, L. (2009). Neighborhood environment in studies of health of older adults: a systematic review. American Journal of Preventive Medicine, 37(5), 455-463.

Return to footnote 587 referrer

Footnote 588

Yen, I. H., Fandel Flood, J., Thompson, H., Anderson, L. A., Wong, G. (2014). How design of places promotes or inhibits mobility of older adults: Realist synthesis of 20 years of research. Journal of Aging and Health, 26(8), 1340-1372.

Return to footnote 588 referrer

Footnote 589

Rosso, A. L., Auchincloss, A. H., Michael, Y. L. (2011). The urban built environment and mobility in older adults: a comprehensive review. Journal of Aging Research.

Return to footnote 589 referrer

Footnote 590

Frank, L., Kerr, J., Rosenberg, D., King, A. (2010). Healthy aging and where you live: community design relationships with physical activity and body weight in older Americans. Journal of Physical Activity and Health, 7(Suppl 1), S82-S90.

Return to footnote 590 referrer

Footnote 591

Adams, M. A., Sallis, J. F., Conway, T. L., Frank, L. D., Saelens, B. E., Kerr, J., Cain, K.L., King, A. C. (2012). Neighborhood environment profiles for physical activity among older adults. American Journal of Health Behavior, 36(6), 757-769.

Return to footnote 591 referrer

Footnote 592

Chudyk, A. M., Winters, M., Moniruzzaman, M., Ashe, M. C., Gould, J. S., McKay, H. (2015). Destinations matter: The association between where older adults live and their travel behavior. Journal of Transport and Health, 2(1), 50-57.

Return to footnote 592 referrer

Footnote 593

King, A. C., Sallis, J. F., Frank, L. D., Saelens, B. E., Cain, K., Conway, T. L., Chapman, J.E., Ahn, D.K., Kerr, J. (2011). Aging in neighborhoods differing in walkability and income: associations with physical activity and obesity in older adults. Social Science and Medicine, 73(10), 1525-1533.

Return to footnote 593 referrer

Footnote 594

Levasseur, M., Généreux, M., Bruneau, J. F., Vanasse, A., Chabot, É., Beaulac, C., Bédard, M. M. (2015). Importance of proximity to resources, social support, transportation and neighborhood security for mobility and social participation in older adults: results from a scoping study. BMC Public Health, 15(1), 503.

Return to footnote 594 referrer

Footnote 595

Mitra, R., Siva, H., Kehler, M. (2015). Walk-friendly suburbs for older adults? Exploring the enablers and barriers to walking in a large suburban municipality in Canada. Journal of Aging Studies, 35, 10-19.

Return to footnote 595 referrer

Footnote 596

Thornton, C. M., Kerr, J., Conway, T. L., Saelens, B. E., Sallis, J. F., Ahn, D. K., Frank, L.D., Cain, K.L., King, A. C. (2016). Physical activity in older adults: An ecological approach. Annals of Behavioral Medicine, 51(2), 159-169.

Return to footnote 596 referrer

Footnote 597

Todd, M., Adams, M. A., Kurka, J., Conway, T. L., Cain, K. L., Buman, M. P., Frank, L.D., Sallis, J.F., King, A. C. (2016). GIS-measured walkability, transit, and recreation environments in relation to older Adults' physical activity: a latent profile analysis. Preventive Medicine, 93, 57-63.

Return to footnote 597 referrer

Footnote 598

Van Holle, V., Van Cauwenberg, J., Van Dyck, D., Deforche, B., Van de Weghe, N., De Bourdeaudhuij, I. (2014). Relationship between neighborhood walkability and older adults' physical activity: results from the Belgian Environmental Physical Activity Study in Seniors (BEPAS Seniors). International Journal of Behavioral Nutrition and Physical Activity, 11(1), 110.

Return to footnote 598 referrer

Footnote 599

Van Holle, V., Van Cauwenberg, J., Gheysen, F., Van Dyck, D., Deforche, B., Van de Weghe, N., De Bourdeaudhuij, I. (2016). The association between Belgian older adults' physical functioning and physical activity: what is the moderating role of the physical environment?. PLoS One, 11(2), e0148398.

Return to footnote 599 referrer

Footnote 600

Winters, M., Voss, C., Ashe, M. C., Gutteridge, K., McKay, H., Sims-Gould, J. (2015). Where do they go and how do they get there? Older adults' travel behaviour in a highly walkable environment. Social Science and Medicine, 133, 304-312.

Return to footnote 600 referrer

Footnote 601

Chudyk, A. M., Winters, M., Moniruzzaman, M., Ashe, M. C., Gould, J. S., McKay, H. (2015). Destinations matter: The association between where older adults live and their travel behavior. Journal of Transport and Health, 2(1), 50-57.

Return to footnote 601 referrer

Footnote 602

Chudyk, A. M., McKay, H. A., Winters, M., Sims-Gould, J., Ashe, M. C. (2017). Neighborhood walkability, physical activity, and walking for transportation: A cross-sectional study of older adults living on low income. BMC Geriatrics, 17(1), 82.

Return to footnote 602 referrer

Footnote 603

Frank, L., Kerr, J., Rosenberg, D., King, A. (2010). Healthy aging and where you live: community design relationships with physical activity and body weight in older Americans. Journal of Physical Activity and Health, 7(Suppl 1), S82-S90.

Return to footnote 603 referrer

Footnote 604

Gauvin, L., Richard, L., Kestens, Y., Shatenstein, B., Daniel, M., Moore, S. D., Mercille, G., Payette, H. (2012). Living in a well-serviced urban area is associated with maintenance of frequent walking among seniors in the VoisiNuAge study. Journals of Gerontology Series B: Psychological Sciences and Social Sciences, 67(1), 76-88.

Return to footnote 604 referrer

Footnote 605

Gell, N. M., Rosenberg, D. E., Carlson, J., Kerr, J., Belza, B. (2015). Built environment attributes related to GPS measured active trips in mid-life and older adults with mobility disabilities. Disability and Health Journal, 8(2), 290-295.

Return to footnote 605 referrer

Footnote 606

Marquet, O., Miralles-Guasch, C. (2015). Neighbourhood vitality and physical activity among the elderly: The role of walkable environments on active ageing in Barcelona, Spain. Social Science and Medicine, 135, 24-30.

Return to footnote 606 referrer

Footnote 607

Rosso, A. L., Auchincloss, A. H., Michael, Y. L. (2011). The urban built environment and mobility in older adults: a comprehensive review. Journal of Aging Research, 2011.

Return to footnote 607 referrer

Footnote 608

Public Health Agency of Canada. (2014). Seniors' Falls in Canada: Second Report. Public Health Agency of Canada.

Return to footnote 608 referrer

Footnote 609

Canadian Institute for Health Information. National Trauma Registry Metadata.

Return to footnote 609 referrer

Footnote 610

Nicklett, E. J., Lohman, M. C., Smith, M. L. (2017). Neighborhood environment and falls among community-dwelling older adults. International Journal of Environmental Research and Public Health, 14(2), 175.

Return to footnote 610 referrer

Footnote 611

Chippendale, T., Boltz, M. (2015). The neighborhood environment: Perceived fall risk, resources, and strategies for fall prevention. The Gerontologist, 55(4), 575-583.

Return to footnote 611 referrer

Footnote 612

Li, W., Keegan, T. H., Sternfeld, B., Sidney, S., Quesenberry Jr, C. P., Kelsey, J. L. (2006). Outdoor falls among middle-aged and older adults: a neglected public health problem. American Journal of Public Health, 96(7), 1192-1200.

Return to footnote 612 referrer

Footnote 613

Clarke, P., Gallagher, N.A. (2013). Optimizing mobility in later life: the role of the urban built environment for older adults aging in place. Journal of Urban Health, 90(6), 997-1009.

Return to footnote 613 referrer

Footnote 614

Hanson, H. M., Ashe, M., McKay, H. A., Winters, M. (2012). Intersection between the built and social environments and older adults' mobility: an evidence review. National Collaborating Centre for Environmental Health.

Return to footnote 614 referrer

Footnote 615

Clarke, P., Hirsch, J. A., Melendez, R., Winters, M., Gould, J. S., Ashe, M., Furst, S., McKay, H. (2017). Snow and Rain Modify Neighbourhood Walkability for Older Adults. Canadian Journal on Aging, 36(2), 159-169.

Return to footnote 615 referrer

Footnote 616

Ottoni, C. A., Sims-Gould, J., Winters, M., Heijnen, M., McKay, H. A. (2016). "Benches become like porches": Built and social environment influences on older adults' experiences of mobility and well-being. Social Science and Medicine, 169, 33-41.

Return to footnote 616 referrer

Footnote 617

Emerson, K.G., Jayawardhana, J. (2016). Risk factors for loneliness in elderly adults. Journal of American Geriatrics Society, 64(4), 886-887.

Return to footnote 617 referrer

Footnote 618

Richard, L., Gauvin, L., Kestens, Y., Shatenstein, B., Payette, H., Daniel, M., Moore, S., Levasseur, M., Mercille, G. (2013). Neighborhood resouces and social participation among older adults: results from the VoisiNuage study. Journal of Aging & Health, 25(2), 296-318.

Return to footnote 618 referrer

Footnote 619

Gray, J.A., Zimmerman, J.L., Rimmer, J.H. (2012). Built environment instruments for walkability, bikeability and recreation: disability and universal design relevant? Disability & Health Journal, 5(2), 87-101.

Return to footnote 619 referrer

Footnote 620

Morales, E., Lindsay, S., Edwards, G., Howell, L., Vincent, C., Yantzi, N., Gauthier, V. (2016). Addressing challenges for youths with mobility devices in winter conditions. Disability & Rehabilitation, 7, 1-7.

Return to footnote 620 referrer

Footnote 621

Spivock, M., Gauvin, L., Brodeur, J.M. (2007). Neighborhood-level active living buoys for individuals with physical disabilities. American Journal of Preventive Medicine, 32(3), 224-230.

Return to footnote 621 referrer

Footnote 622

Spivock, M., Gauvin, L., Riva, M., Brodeur, J.M. (2008). Promoting active living among people with physical disabilities. American Journal of Preventive Medicine, 34(4), 291-298.

Return to footnote 622 referrer

Footnote 623

Statistics Canada (2015). A profile of persons with disabilities among Canadians aged 15 years or older, 2012. Canadian Survey on Disability, 2012. Statistics Canada.

Return to footnote 623 referrer

Footnote 624

Botticello, A.L., Rohorbach, T., Cobbold, N. (2014). Disability and the built environment: an investigation of community and neighborhood land uses and participation for physically impaired adults. Annals of Epidemiology, 24(7), 545-550.

Return to footnote 624 referrer

Footnote 625

Clarke, P. Aiolshire, J.A., Bader, M., Morenoff, J.D., House, J.S. (2008). Mobility disability and the urban built environment. American Journal of Epidemiology, 168(5), 506-513.

Return to footnote 625 referrer

Footnote 626

Shumway-Cook, A., Patla, A., Stewart, A., Ferrucci, L., Ciol, M.A., Guralnik, J.M. (2003). Environmental components of mobility disability in community-living older persons. Journal of the American Geriatrics Society, 51(3), 393-398.

Return to footnote 626 referrer

Footnote 627

Lindsay, S., Morales, E., Yantzi, N., Vincent, C., Howell, L., Edwards, G. (2015). The experiences of participating in winter among youths with a physical disability compared with their typically developing peers. Child: Care, Health & Development, 41(6), 980-988.

Return to footnote 627 referrer

Footnote 628

Lindsay, S., Yantzi, N. (2014). Weather, disability, vulnerability, and resilience: exploring how youth with physical disabilities experience winter. Disability & Rehabilitation, 36(26), 2195-2204.

Return to footnote 628 referrer

Footnote 629

Ripat, J., Colatruglio, A. (2016). Exploring winter community participation among wheelchair users : an online focus group. Occupational Therapy in Health Care, 30(1), 95-106.

Return to footnote 629 referrer

Footnote 630

Ripat, J.D., Brown, C.L., Ethans, K.D. (2015). Barriers to wheelchair use in the winter. Archives of Physical Medicine & Rehabilitation, 96(6), 1117-1122.

Return to footnote 630 referrer

Footnote 631

Friel, S., Akerman, M., Hancock, T., Kumaresan, J., Marmot, M., Melin, T., Valhov, D., GRNUHE members (2011). Addressing the social and environmental determinants of urban health equity: evidence for action and a research agenda. Journal of Urban Health, 88(5), 860-874.

Return to footnote 631 referrer

Footnote 632

Hutch, D.J., Bouye, K.E., Skillen, E. Lee, C., Whitehead, L., Rashid, J.R. (2011). Potential strategies to eliminate built environment disparities for disadvantaged and vulnerable communities. American Journal of Public Health, 101(4), 587-595.

Return to footnote 632 referrer

Footnote 633

Badland, H., Foster, S., Bentley, R., Higgs, C., Roberts, R., Pettit, C., Giles-Corti, B. (2017). Examining associations between aera-level spatial measures of housing with selected health and wellbeing behaviours and outcomes in an urban context. Health and Place, 43, 17-24.

Return to footnote 633 referrer

Footnote 634

Downing, J. (2016). The health effects of the foreclosure crisis and unaffordable housing: a systematic review and explanation of evidence. Social Science and Medicine, 162, 88-96.

Return to footnote 634 referrer

Footnote 635

Maqbool, N., Viveiros, J., Ault, M. (2015). The impacts of affordable housing on health : a research summary. Insights from Housing Policy Research. Center for Housing Policy.

Return to footnote 635 referrer

Footnote 636

Mason, K.E., Baker, E., Blakely, T., Bentley, R.J. (2013). Housing affordability and mental health: does the relationship differ for renters and home purchasers? Social Science and Medicine, 94, 91-97.

Return to footnote 636 referrer

Footnote 637

Meltzer, R., Schwartz, A. (2015). Housing affordability and health: evidence from New York City. Housing Policy Debate, 26(1), 80-104.

Return to footnote 637 referrer

Footnote 638

Novoa, A.M., Ward, J., Malmusi, D., Diaz, F., Darnell, M., Trilla, C., Bosch, J. Borrell, C. (2015). How substandard dwellings and housing affordability problems are associated with poor health in a vulnerable population during the economic recession of the late 2000s. International Journal for Equity in Health, 14, 120.

Return to footnote 638 referrer

Footnote 639

Vasquez-Vera, H., Palencia, L., Magna, I., Mena, C., Neira, J., Borrell, C. (2017). The threat of home eviction and its effects on health through the equity lens : a systematic review. Social Science and Medicine, 175, 188-208.

Return to footnote 639 referrer

Footnote 640

Atkinson, R. (2010). The evidence on the impact of gentrification: new lessons for the urban renaissance? International Journal of Housing Policy, 4(1), 107-131.

Return to footnote 640 referrer

Footnote 641

Shaw, K.S., Hagemans, I.W. (2015). "Gentrification without displacement" and the consequent loss of place: the effects of class transition on low-income residents of secure housing in gentrifying areas. International Journal of Urban and Regional Research, 39(2), 323-341.

Return to footnote 641 referrer

Footnote 642

Indigenous and Northern Affairs Canada (2010). Fact sheet – Urban Aboriginal population in Canada. Indigenous and Northern Affairs Canada.

Return to footnote 642 referrer

Footnote 643

Gionet, L. (2009). Métis in Canada: selected findings of the 2006 Census. Statistics Canada.

Return to footnote 643 referrer

Footnote 644

Statistics Canada (2010). 2006 Census: Aboriginal Peoples in Canada in 2006: Inuit Métis and First Nations, 2006 Census: First Nations people. Statistics Canada.

Return to footnote 644 referrer

Footnote 645

Statistics Canada (2016). Aboriginal Peoples in Canada: First Nations People, Métis and Inuit. Statistics Canada.

Return to footnote 645 referrer

Footnote 646

Brown, B., Wachowiak-Smolíková, R., Spence, N. D., Wachowiak, M. P., Walters, D. F. (2016). Why Do Some First Nations Communities Have Safe Water and Others Not? Socioeconomic Determinants of Drinking Water Risk. Global Journal of Health Science, 8(9), 99.

Return to footnote 646 referrer

Footnote 647

Galway, L.P. (2016). Boiling over: A Descriptive Analysis of Drinking Water Advisories in First Nations Communities in Ontario, Canada. International Journal of Environmental Research and Public Health, 13(5), 505.

Return to footnote 647 referrer

Footnote 648

Patrick, R.J. (2011). Uneven access to safe drinking water for First Nations in Canada: Connecting health and place through source water protection. Health and Place, 17(1), 386-389.

Return to footnote 648 referrer

Footnote 649

Sarkar, A., Hanrahan, M., Hudson, A. (2015). Water insecurity in Canadian Indigenous communities: some inconvenient truths. Rural and Remote Health, 15(3354), 1-14.

Return to footnote 649 referrer

Footnote 650

Donaldson, S. G., Van Oostdam, J., Tikhonov, C., Feeley, M., Armstrong, B., Ayotte, P., Boucher, O., Bowers, W., Chan, L., Dallaire, F., Dallaire, R. (2010). Environmental contaminants and human health in the Canadian Arctic. Science of the Total Environment, 408(22), 5165-5234.

Return to footnote 650 referrer

Footnote 651

Hlimi, T., Skinner, K., Hanning, R., Martin, I. D., Tsuji, L. S. (2012). Traditional food consumption behaviour and concern with environmental contaminants among Cree schoolchildren of the Mushkegowuk territory. International Journal of Circumpolar Health, 71(1), 17344.

Return to footnote 651 referrer

Footnote 652

Johnson-Down, L., Egeland, G. M. (2010). Adequate nutrient intakes are associated with traditional food consumption in Nunavut Inuit children aged 3–5 years. The Journal of Nutrition, 140(7), 1311-1316.

Return to footnote 652 referrer

Footnote 653

Reading, J., Halseth, R. (2013). Pathways to Improving Well-Being for Indigenous Peoples: How Living Conditions Decide Health. Prince George, BC: National Collaborating Centre for Aboriginal Health.

Return to footnote 653 referrer

Footnote 654

Akande, V. O., Hendriks, A. M., Ruiter, R. A., Kremers, S. P. (2015). Determinants of dietary behavior and physical activity among Canadian Inuit: a systematic review. International Journal of Behavioral Nutrition and Physical Activity, 12(1), 84.

Return to footnote 654 referrer

Footnote 655

Bruner, B., Chad, K. (2013). Physical activity attitudes, beliefs, and practices among women in a Woodland Cree community. Journal of Physical Activity and Health, 10(8), 1119-1127.

Return to footnote 655 referrer

Footnote 656

Gates, M., Hanning, R., Gates, A., Stephen, J., Fehst, A., Tsuji, L. (2016). Physical activity and fitness of First Nations youth in a remote and isolated northern Ontario community: a needs assessment. Journal of Community Health, 41(1), 46.

Return to footnote 656 referrer

Footnote 657

Lévesque, L., Janssen, I., Xu, F. (2015). Correlates of physical activity in First Nations youth residing in First Nations and northern communities in Canada. Canadian Journal of Public Health, 106(2), 29-35.

Return to footnote 657 referrer

Footnote 658

Parks, M.W. (2010). Ecohealth and Aboriginal Health: A Review of Common Ground. National Collaborating Centre for Aboriginal Health.

Return to footnote 658 referrer

Designing Canadian communities for healthy living

Footnote 659

Politis, C.E., Mowat, D., Keen, D. (2017). Pathways to policy: lessons learned in multisecctoral collaboration for physical activity and built environment policy development from the Coalitions Linking Action and Science for Prevention (CLASP) initiative. Canadian Journal of Public Health, 108(2), e192-e198.

Return to footnote 659 referrer

Footnote 660

Kishchuk, N. (2014). "Taking the Pulse 2": Comparative analysis: planning for healthier communities. Questionnaire results, June 2014. Institut canadien des urbanistes.

Return to footnote 660 referrer

Footnote 661

Centre de collaboration nationale sur les politiques publique et la santé (2012). Health authorities and the built environment: actions to influence public policies: interview report, November 2012. Centre de collaboration nationale sur les politiques publique et la santé.

Return to footnote 661 referrer

Footnote 662

de Leeuw, E., Simos, J. (eds.). (2017). Healthy Cities: The Theory, Policy, and Practice of Value-Based Urban Planning. Springer.

Return to footnote 662 referrer

Footnote 663

Macfarlane, R. G., Wood, L. P., Campbell, M. E. (2015). Healthy Toronto by Design: Promoting a healthier built environment. Canadian Journal of Public Health, 106(1), 5-8.

Return to footnote 663 referrer

Footnote 664

Dube, A. S., Beausoleil, M., Gosselin, C., Beaulne, G., Paquin, S., Pelletier, A., Goudreau, S., Poirier, M. H., Drouin, L., Gauvin, Li. (2014). Grassroots projects aimed at the built environment: Association with neighbourhood deprivation, land-use mix and injury risk to road users. Canadian Journal of Public Health, 106(1), e521.

Return to footnote 664 referrer

Footnote 665

Plan Canada (2013). Indigenizing Planning/Planning to Indigenize. Canadian Institute of Planners.

Return to footnote 665 referrer

Footnote 666

Walker, R., Jojola, T., Natcher, N. (eds.). (2013). Reclaiming indigenous planning (Vol. 70). McGill-Queen's Press-MQUP.

Return to footnote 666 referrer

Footnote 667

Plan Canada (2008). Indigenizing Planning/Planning to Indigenize. Canadian Institute of Planners.

Return to footnote 667 referrer

Footnote 668

Federation of Canadian Municipalities. First Nation-Municipal land use planning tool. Federation of Canadian Municipalities.

Return to footnote 668 referrer

Footnote 669

Federation of Canadian Municipalities (2015). Stronger together toolkit. Federation of Canadian Municipalities.

Return to footnote 669 referrer

Footnote 670

National Collaborating Centre for Environment Health (2016). Integrating Indigenous community planning into a healthy built environment. National Collaborating Centre for Environment Health.

Return to footnote 670 referrer

Footnote 671

Canadian Institute of Planners (2013). Healthy communities: Legislative comparison survey report. Canadian Institute of Planners.

Return to footnote 671 referrer

Footnote 672

BC Healthy Communities, Mouvement Acadien des communautés en santé du Nouveau-Brunswick, Ontario Healthy Communities Coalition, Réseau Québecois de villes et villages en santé. The Healthy Communities approach : a framework for action on the determinants of health. Communautés en santé du Canada.

Return to footnote 672 referrer

Footnote 673

Canadian Healthy Communities. A survey of Canadian Healthy Communities initiatives. Canadian Healthy Communities.

Return to footnote 673 referrer

Footnote 674

Miro, A., Kishchuk, N. A., Perrotta, K., & Swinkels, H. M. (2015). Healthy Canada by Design CLASP: Lessons learned from the first phase of an intersectoral, cross-provincial, built environment initiative. Canadian Journal of Public Health, 106(1), 50-58.

Return to footnote 674 referrer

Footnote 675

Perrotta, K. (2015). Building a community of practice: Healthy Canada by Design CLASP Renewal–Postscript. Canadian Journal of Public Health, 106(1), 59-61.

Return to footnote 675 referrer

Footnote 676

World Health Organization. Healthy Cities. World Health Organization, Regional Office for Europe.

Return to footnote 676 referrer

Footnote 677

Canadian Healthy Communities. An integrated approach for chronic disease prevention. Canadian Healthy Communities.

Return to footnote 677 referrer

Footnote 678

Jeste, D. V., Blazer, D. G., Buckwalter, K. C., Cassidy, K. L. K., Fishman, L., Gwyther, L. P., Levin, S.M., Phillipson, C., Rao, R.R., Schmeding, E., Vega, W. A. (2016). Age-friendly communities initiative: public health approach to promoting successful aging. The American Journal of Geriatric Psychiatry, 24(12), 1158-1170.

Return to footnote 678 referrer

Footnote 679

Plouffe, L. A., Kalache, A. (2011). Making communities age friendly: state and municipal initiatives in Canada and other countries. Gaceta Sanitaria, 25, 131-137.

Return to footnote 679 referrer

Footnote 680

Orpana, H., Chawla, M., Gallagher, E., Escaravage, E. (2016). Developing indicators for evaluation of age-friendly communities in Canada: process and results. Health Promotion and Chronic Disease Prevention in Canada: Research, Policy and Practice, 36(10), 214.

Return to footnote 680 referrer

Footnote 681

World Health Organization. (2015). Measuring the age-friendliness of cities: A guide to using core indicators. World Health Organization.

Return to footnote 681 referrer

Footnote 682

Keating, N., Eales, J., Phillips, J. E. (2013). Age-friendly rural communities: Conceptualizing 'best-fit'. Canadian Journal on Aging, 32(4), 319-332.

Return to footnote 682 referrer

Footnote 683

Menec, V., Bell, S., Novek, S., Minnigaleeva, G. A., Morales, E., Ouma, T., Parodi, J.F., Winterton, R. (2015). Making rural and remote communities more age-friendly: experts' perspectives on issues, challenges, and priorities. Journal of Aging & Social Policy, 27(2), 173-191.

Return to footnote 683 referrer

Footnote 684

Neville, S., Napier, S., Adams, J., Wham, C., Jackson, D. (2016). An integrative review of the factors related to building age‐friendly rural communities. Journal of Clinical Nursing, 25(17-18), 2402-2412.

Return to footnote 684 referrer

Footnote 685

Spina, J., Menec, V. H. (2015). What community characteristics help or hinder rural communities in becoming age-friendly? Perspectives from a Canadian prairie province. Journal of Applied Gerontology, 34(4), 444-464.

Return to footnote 685 referrer

Footnote 686

Gagnon, F., Bellefleur, O. (2015). Influencing public policies: Two (very good) reasons to look toward scientific knowledge in public policy. Canadian Journal of Public Health, 106(1), 9-11.

Return to footnote 686 referrer

Footnote 687

Raine, K. D., Muhajarine, N., Spence, J. C., Neary, N. E., Nykiforuk, C. I. (2012). Coming to consensus on policy to create supportive built environments and community design. Canadian Journal of Public Health, 103(Suppl 3), S5-S8.

Return to footnote 687 referrer

Footnote 688

Sallis, J. F., Bull, F., Burdett, R., Frank, L. D., Griffiths, P., Giles-Corti, B., Stevenson, M. (2016). Use of science to guide city planning policy and practice: how to achieve healthy and sustainable future cities. The Lancet, 388(10062), 2936-2947.

Return to footnote 688 referrer

Footnote 689

Fazli, G.S., Creatore, M.I., Matheson, F.I., Guilcher, S., Kaufman-Shriqui, V., Manson, H., Johns, A., Booth, G.L. (2017). Identifying mechanisms for facilitating knowledge to action strategies targeting the built environment. BMC Public Health, 17(1), 1.

Return to footnote 689 referrer

Footnote 690

Kovacic, J. C., Castellano, J. M., Farkouh, M. E., Fuster, V. (2014). The relationships between cardiovascular disease and diabetes: focus on pathogenesis. Endocrinology and Metabolism Clinics of North America, 43(1), 41-57.

Return to footnote 690 referrer

Footnote 691

Rössner, S. (2002). Obesity: the disease of the twenty-first century. International Journal of Obesity, 26(S4), S2.

Return to footnote 691 referrer

Footnote 692

McCloughen, A., Foster, K., Huws Thomas, M., Delgado, C. (2012). Physical health and wellbeing of emerging and young adults with mental illness: An integrative review of international literature. International Journal of Mental Health Nursing, 21(3), 274-288.

Return to footnote 692 referrer

Page details

Date modified: