Hostname: page-component-586b7cd67f-l7hp2 Total loading time: 0 Render date: 2024-11-22T06:01:47.162Z Has data issue: false hasContentIssue false

Where does your food come from?

Published online by Cambridge University Press:  01 November 2010

Rights & Permissions [Opens in a new window]

Abstract

Type
Editorial
Copyright
Copyright © The Authors 2010

Linking agricultural and nutrition policy

In this issue we are pleased to have a contribution that delivers a thoughtful commentary on the disconnection between US agricultural and nutrition policy(Reference Griffin1). In his commentary, Professor Griffin, Director of the Agriculture, Food and Environment Program at Tufts University, describes the context from which current agricultural and nutrition policies emerged and the circumstances that now place them at odds with each other. He also discusses how the linkage between agricultural and nutrition policies might be strengthened at the local, regional and national levels. As Professor Griffin emphasizes, there is currently no meaningful linkage between agricultural and nutrition policy in the USA, but the means to improve this linkage are available. His examples of existing and possible linkages at the local, regional and national levels are based in a unique familiarity with both agriculture and policy environments in the USA, and are worth further discussion. Ultimately, agricultural policy governing food sources and nutrition policy guiding food consumption should not be at odds, and ideally we should all be able to receive a satisfactory answer to the question, ‘Where does your food come from?’

Where does our food come from? The case of fish

Often, the answer to that question is not a happy one, and recommendations on how to deal with it are contradictory. In waterways, atmospheric deposition of mercury emitted from the combustion of fossil fuels, particularly coal-fired power plants, has led to widespread mercury contamination of fish in some areas(Reference Pacyna, Pacyna and Steenhuisen2, Reference Scudder, Chasar and Wentz3). At the same time, interest in the potential health benefits from consuming fish and fish oils is increasing. The American Heart Association, for example, recommends at least two servings of fish each week(4). How do consumers balance discordant messages about the risks and benefits of eating fish?

In an analysis of US news media stories about fish from 1993 to 2007, Greiner et al.(Reference Greiner, Clegg Smith and Guallar5) found that messages conveying risk outweighed messages conveying health benefits by four to one, with most stories focusing on mercury contamination in fish. As a result, messages regarding potential health benefits of fish consumption may be largely lost to consumers, who mostly receive messages emphasizing potential risks of fish consumption. The authors suggest that public health practitioners should work with news media to deliver clear messages about which fish can be recommended and which should be avoided. Lists of which fish are okay to eat and which are not (in terms of contaminants as well as sustainability) are available (e.g. see references (6) to (8)), but creating simple messages out of long lists will be an ongoing challenge.

Assessing food environments

Other articles in this issue address neighbourhood food environments. In their review of the literature on GIS (Geographic Information Systems) methods used to quantify spatial accessibility of food outlets, Charreire et al.(Reference Charreire, Casey and Salze9) identified two primary concepts used to assess the food environment: (i) density, or the number of food outlets in a given area; and (ii) proximity, or the distance to a given food outlet. Laska et al.(Reference Laska, Hearst and Forsyth10) use both spatial methods – density and proximity – to show associations of the availability and proximity of food outlets around adolescents’ homes in the Minneapolis/St. Paul metropolitan region, USA, with consumption of sugar-sweetened beverages.

Charreire et al.(Reference Charreire, Casey and Salze9) also suggest that studies on accessibility of food outlets should examine not only spatial accessibility but also other such dimensions of accessibility as affordability and the availability of foods within stores. Also in this issue, Gloria et al.(Reference Gloria and Steinhardt11) describe a tool, adapted from the Nutrition Environment Measures Survey in Stores (NEMS-S), to measure the availability of healthy foods from grocery and convenience stores in Texas. Their tool demonstrates generally high inter-rater and test–retest reliability, and further provides preliminary evidence that grocery (but not convenience) stores in high-income neighbourhoods offer more healthy foods than those in low-income neighbourhoods.

While representing different aspects of ‘environment,’ what these articles and the commentary have in common is recognition of the interactions between people and their environment. The environment, whether local or global, offers the selection of foods from which to choose and hence determines what we can eat, in ways that can be positive (e.g. fresh, pesticide-free fruits) or negative (e.g. sugar-sweetened beverages in school vending machines). We, in turn, act on preferences and principles (e.g. choosing to buy only organic produce, or lobbying for food safety legislation), and our actions determine the quality of our food environment – also in ways that can be positive or negative. It is hoped that the effects of our actions on our environment can turn more towards the positive with sustained effort. The question of where our food comes from may then be answered more easily, giving consumers a greater freedom of personal choice.

References

1.Griffin, T (2010) Commentary: Linking agriculture and nutrition. Public Health Nutr 13, 19411944.CrossRefGoogle Scholar
2.Pacyna, EG, Pacyna, JM, Steenhuisen, F et al. (2006) Global anthropogenic mercury emission inventory for 2000. Atmos Environ 40, 40484063; available at doi:10.1016/j.atmosenv.2006.03.041.CrossRefGoogle Scholar
3.Scudder, BC, Chasar, LC, Wentz, DA et al. (2009) Mercury in Fish, Bed Sediment, and Water from Streams across the United States, 1998–2005. Scientific Investigations Report no. 2009–5109. Reston, VA: US Geological Survey.Google Scholar
4.American Heart Association (2010) Nutrition Center. Healthy Diet Goals. http://www.heart.org/HEARTORG/GettingHealthy/NutritionCenter/HealthyDietGoals/Healthy-Diet-Goals_UCM_310436_SubHomePage.jsp (accessed September 2010).Google Scholar
5.Greiner, A, Clegg Smith, K & Guallar, E (2010) Something fishy? News media presentation of complex health issues related to fish consumption guidelines. Public Health Nutr 13, 17861794.Google Scholar
6.Environmental Defense Fund (2010) Seafood Selector. Make Smart Choices When Eating Seafood. http://www.edf.org/page.cfm?tagID=1521 (accessed September 2010).Google Scholar
7.Monterey Bay Aquarium (2010) Seafood WATCH. http://www.montereybayaquarium.org/cr/seafoodwatch.aspx (accessed September 2010).Google Scholar
8.Marine Conservation Society (2010) FISHONLINE website. http://www.fishonline.org/ (accessed September 2010).Google Scholar
9.Charreire, H, Casey, R, Salze, P et al. (2010) Measuring the food environment using geographical information systems: a methodological review. Public Health Nutr 13, 17731785.Google Scholar
10.Laska, MN, Hearst, MO, Forsyth, A et al. (2010) Neighbourhood food environments: are they associated with adolescent dietary intake, food purchases and weight status? Public Health Nutr 13, 17571763.Google Scholar
11.Gloria, CT & Steinhardt, MA (2010) Texas nutrition environment assessment of retail food stores (TxNEA-S): development and evaluation. Public Health Nutr 13, 17641772.CrossRefGoogle ScholarPubMed