Appendix E-2.37 Evidence Portfolio

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Part D. Chapter 5: Food Sustainability and Safety

What is the relationship between population-level dietary patterns and food sustainability and related food security?

Conclusion Statement: Consistent evidence indicates that, in general, a dietary pattern that is higher in plant-based foods, such as vegetables, fruits, whole grains, legumes, nuts, and seeds, and lower in animal-based foods is more health promoting and is associated with lesser environmental impact (GHG emissions and energy, land, and water use) than is the current average U.S. diet. A diet that is more environmentally sustainable than the average U.S. diet can be achieved without excluding any food groups. The evidence consists primarily of Life Cycle Assessment (LCA) modeling studies or land-use studies from highly developed countries, including the United States.

DGAC Grade: Moderate

Key Findings

• The studies were consistent in showing that higher consumption of animal-based foods was associated with a greater impact on the environment and higher consumption of plant-based foods was associated with lower impact.
• The studies were consistent in showing that dietary patterns that promote health also promote sustainability.
• The studies were consistent in showing that healthier dietary patterns that adhered to dietary guidelines were more environmentally sustainable than diets typically consumed by the respective populations.
• The evidence supports that a sustainable diet can be achieved by following dietary guidance in the U.S. and national dietary guidance in other countries, without eliminating any food groups completely.
• The evidence supports the consumption of current dietary guidelines by increasing consumption of plant-based foods and modestly decreasing animal-based foods.
• Limited evidence showed that just lowering the snacks/sweets component of a dietary pattern benefits health and improves the environmental footprint.
• Overall, there was agreement across the studies regarding environmental footprints of different dietary patterns, despite varied methods of assessing environmental impact and differences in components of environmental impact assessed, e.g. GHG emissions or land use.
• There was limited and inconsistent evidence to indicate whether sustainable diets were more or less expensive than typically consumed diets in some locations.

Methodology

This topic is novel for a DGAC review and involves an emerging area of scientific investigation that is not readily addressed by study designs such as randomized controlled trials. The state-of-the-art of the literature related to sustainable diets and dietary patterns involves a unique combination of food pattern modeling, Life Cycle Assessment (LCA) methodology (examines all processes in the life cycle of each food component - from farm to plate to waste), and determination of the environmental outcomes of the full LCA inventory. Because of the unique nature of these studies, a modified NEL systematic review was conducted for the question on dietary patterns and sustainability. Databases included PubMed, Cochrane, Navigator, and Embase and the search covered from January 2000 to March 2014. For this topic and question, it was necessary to use different methods from those described in an original NEL protocol because not all methods in the protocol could be applied. This is sometimes necessary, according to the Cochrane Collaboration, but requires that methods from the original protocol that could not be implemented in the current review be summarized (Higgins 2011). In the standard NEL six-step protocol, step 3 to extract data and assess the risk of bias was modified. A new data extraction grid was developed with emphasis on modeling studies, LCA methodology, and environmental outcomes. The LCA is a standardized methodological framework for assessing the environmental impact (or load) attributable to the life cycle of a food product. The customized grid was then used by NEL abstractors to extract data from the included articles. In addition, NEL abstractors used a different tool to assess individual study quality or risk of bias, not the NEL Bias Assessment Tool (BAT). This alternative tool, the Critical Appraisal Checklist used by the British Medical Journal, was appropriate for studies that used a modeling design. This checklist assesses studies that use modeling to extrapolate progression of clinical outcomes, transform final outcomes from intermediate measures, examine relation between inputs and outputs to apportion resource use, and extrapolate findings from one clinical setting or population to another. To attain a high score, studies must report the variables that have been modeled rather than directly observed; what additional variables have been included or excluded; what statistical relations have been assumed; and what evidence supports these assumptions (Drummond 1996; Eddy 1985; Stevenson 2012). The checklist included key components of the British Medical Journal checklist for economic evaluations, together with the Eddy checklist on mathematical models. This Critical Appraisal Checklist was reviewed and tested for applicability by two sustainability experts who served as consultants to the DGAC.

Description of the Evidence

A total of 15 studies met the inclusion criteria for this systematic review. The body of evidence consisted primarily of dietary pattern modeling studies that assessed related environmental outcomes. These studies were conducted between the years 2003 and 2014 in the US (Pimentel & Pimental, 2003, Peters 2014), the UK (Aston 2012, Macdiarmid 2012, Scarborough 2012), Germany (Meier & Christen 2013), the Netherlands (van Doreen 2014), France (Vieux 2013), Spain (Sáez-Almendros 2013), Italy (Baroni 2007), Australia (Barosh 2014, Hendrie 2014), Brazil (de Carvalho 2013), New Zealand (Wilson 2013), and worldwide (Pradhan 2013). Dietary patterns that were examined included vegetarian, lacto-ovo vegetarian, and vegan dietary patterns; the average and dietary guidelines-related dietary patterns of respective countries examined; Mediterranean-style dietary patterns; and sustainable diets. The most frequent comparison diet was the average dietary pattern of the country, although numerous studies made additional comparisons across many of the above dietary patterns. Another approach was to examine diet “scenarios” that modeled different percentage replacements of meat and dairy foods with plant-based foods. The modeling studies used cross-sectional assessment of dietary intake from national nutrition surveys of representative adult populations; for example, the British National Diet and Nutrition Survey (NDNS) from studies in the UK (Aston 2012; Macdiarmid 2012), the National Nutrition Surveys (NNS) in Germany (Meier & Christen 2013), or the Australian National Nutrition Survey (Hendrie 2014) were used to determine the observed average dietary patterns. The average dietary patterns were then compared with other modeled dietary patterns, such as vegetarian or Mediterranean- style patterns, as described in detail below. All of the countries were highly developed countries with dietary guidelines and, therefore, generalizable to the U.S. population. The study quality for the body of evidence ranged from scores of 7/12 to 12/12 (indicating the evidence was of high quality) using the modified critical appraisal checklist.

Health outcomes associated with the dietary patterns were most often documented based on adherence to dietary guidelines-related patterns, variations on vegetarian dietary patterns, or Mediterranean-style dietary patterns. Diet quality was assessed in some studies using an a priori index, such as the Healthy Eating Index (HEI) or the WHO Index. In some studies, health outcomes also were modeled. For example Scarborough et al. used the DIETRON model to estimate deaths delayed or averted for each diet pattern. One study assessed the synergy between health and sustainability scores using the WHO Index and the LCA sustainability score to assess combined nutritional and ecological value (van Dooren 2014).

The environmental impacts that were most commonly modeled were GHG emissions and use of resources such as agricultural land, energy, and water. In many studies, the environmental impact for each food/food category was obtained using the LCA method. The LCA is a standardized methodological framework for assessing the environmental impact (or load) attributable to the life cycle of a food product. The life cycle for a food typically includes agricultural production, processing and packaging, transportation, retail, use, and waste disposal. An inventory of all stages of the life cycle is determined for each food product and a “weight” or number of points is then attributed to each food or food category, based on environmental impacts such as resource extraction, land use, and relevant emissions. These environmental impact results can be translated into measures of damage done to human health, ecosystem quality, and energy resources using programs such as Eco-Indicator (Goedkoop 2000). In addition to the health assessment approaches listed above, some studies used LCA analysis with a standardized approach to determine damages from GHG emissions and use of resources; these damage outcomes included human health as an environmental damage component, such as the number and duration of diseases and life years lost due to premature death from environmental causes.

Few studies assessed food security. These studies assessed food security in terms of the cost difference between an average dietary pattern for the country studied and a sustainable dietary pattern for that population (Barosh 2014, Macdiarmid 2012, Wilson 2013). The basic food basket concept was used in some studies, representing household costs for a two-adult/two-child household.

Evidence Synthesis

Themes and Key Findings

Identified Dietary Patterns and Health and Sustainability Outcomes

Vegetarian and Meat-based Diets
Several studies examined variations on vegetarian diets, or a spectrum from vegan to omnivorous dietary patterns, and associated environmental outcomes (Aston 2012; Baroni 2007; de Carvalho 2013; Peters 2007). Peters et al. examined 42 different dietary patterns and land use in New York, with patterns ranging from low-fat, lacto-ovo vegetarian diets to high fat, meat-rich omnivorous diets; across this range, the diets met U.S. dietary guidelines when possible. They found that, overall, increasing meat in the diet increased per capita land requirements; however, increasing total dietary fat content of low-meat diets (i.e. vegetarian alternatives) increased the land requirements compared to high-meat diets. In other words, although meat increased land requirements, diets including meat could feed more people than some higher fat vegetarian-style diets. Aston et al. assessed a pattern that was modeled on a feasible UK population in which the proportion of vegetarians in the survey was doubled, and the remainder adopted a diet pattern consistent with the lowest category of red and processed meat (RPM) consumers. They found the combination of low RPM + vegetarian diet had health benefits of lowering the risk of diabetes and colorectal cancer, determined from risk relationships for RPM and CHD, diabetes, and colorectal cancer from published meta-analyses. Furthermore, the expected reduction in GHG for this diet was ~3 percent of current total carbon dioxide (CO₂) emissions for agriculture. De Carvalho et al. also examined a high RPM dietary pattern with diet quality assessed using the Brazilian Healthy Eating Index. They found that excessive meat intake was associated not only with poorer diet quality but also with increased projected GHG emissions (~ 4 percent total CO₂ emitted by agriculture). Taken together, the results on RPM intake indicate that reduced consumption is expected to improve some health outcomes and decrease GHG emissions, as well as land use compared to “current RPM consumption.” Baroni et al. examined vegan, vegetarian, and omnivorous diets, both organically and conventionally grown, and found that the organically grown vegan diet had the most potential health benefits; whereas, the conventionally grown average Italian diet had the least. The organically grown vegan diet also had the lowest estimated impact on resources and ecosystem quality, and the average Italian diet had the greatest projected impact. Beef was the single food with the greatest projected impact on the environment; other foods estimated to have high impact included cheese, milk, and fish.

Vegetarian diets, dietary guidelines-related diets, and Mediterranean-style diets were variously compared with the average dietary patterns in selected countries (Hendrie 2014; Meier & Christen 2013; Pimentel & Pimental 2003; van Dooren 2014). Overall, the estimated greater environmental benefits, including reduced projected GHG emissions and land use, resulted from vegan, lacto-ovo vegetarian, and pesco-vegetarian diets, as well as dietary guidelines-related and Mediterranean-style dietary patterns. These diets had higher overall predicted health scores than the average diet patterns. Moreover, for the most part, the high health scores of these dietary patterns were paralleled by high combined estimated sustainability scores. According to van Doreen et al., the synergy measured across vegetarian, Mediterranean-style, and dietary guidelines-related scores could be explained by a reduction in consumption of meat, dairy, extras (i.e., snacks and sweets), and beverages, as well as a reduction in overall food consumption.

Mediterranean-Style Dietary Patterns
The Mediterranean-style dietary pattern was examined in both Mediterranean and non-Mediterranean countries (Saez-Almendros 2013; van Dooren 2014). In all cases, adherence to a Mediterranean-style dietary pattern—compared to usual intake—reduced the environmental footprint, including improved GHG emissions, agricultural land use, and energy and water consumption. Both studies limited either red and processed meat (Saez-Almendros 2013) or meat and poultry (van Dooren 2014) to less than 1 serving per week, and increased fish intake. The authors concluded that adherence to a Mediterranean-style dietary pattern would make a significant contribution to increasing food sustainability, as well as increasing the health benefits that are well-documented for this type of diet.

Diet Scenarios
Other studies examined different diet “scenarios” that generally replaced animal foods in various ways with plant foods (Scarborough 2012; Pradham 2013; Vieux 2013). Scarborough et al. found that a diet with 50 percent reduced total meat and dairy replaced by fruit, vegetables, and cereals contributed the most to estimated reduced risk of total mortality and also had the largest potential positive environmental impact. This diet scenario increased fruit and vegetable consumption by 63 percent and decreased saturated fat and salt consumption; micronutrient intake was generally similar with the exception of a drop in vitamin B12.

Pradham et al. examined 16 global dietary patterns that differed by food and energy content, grouped into four categories with per capita intake of low, moderate, high, and very high kcal diets. They assessed the relationship of these patterns to GHG emissions. Low-energy diets had < 2,100 kcal/cap/day and were composed of more than 50 percent cereals or more than 70 percent starchy roots, cereals, and pulses. Animal products were minor in this group (<10 percent). Moderate, high, and very high energy diets had 2,100-2,400, 2,400-2,800, and > 2,800 kcal/cap/day, respectively. Very high calorie diets had high amounts of meat and alcoholic beverages. Overall, very high calorie diets, common in the developed world, exhibited high total per capita CO_2eq emissions due to high carbon intensity and high intake of animal products; the low-energy diets, on the other hand, had the lowest total per capita CO_2eq emissions.

Lastly, Vieux et al. examined dietary patterns with different indicators of nutritional quality and found that despite containing large amounts of plant foods, not all diets of the highest nutritional quality were those with the lowest GHG emissions. For this study, the diet pattern was assessed by using nutrient-based indicators; high quality diets had energy density below the median, mean adequacy ratio above the median, and a mean excess ratio (percentage of maximum recommended for nutrients that should be limited – saturated fat, sodium, and free sugars) below the median. Four diet patterns were identified based on compliance with these properties to generate one high quality diet, two intermediate quality diets, and one low quality diet. In this study, the high quality diets had higher GHG emissions than did the low quality diets. Regarding the food groups, a higher consumption of starches, sweets and salted snacks, and fats was associated with lower diet-related GHG emissions and an increased intake of fruit and vegetables, was associated with increased diet-related GHG emissions. However, the strongest positive association with GHG emissions was still for the ruminant meat group. Overall, this study used a different approach from the other studies in this review, as nutritional quality determined the formation of dietary pattern categories.

Sustainable Diets and Costs 
Three studies examined sustainable diets and related costs (Barosh 2014; Macdiarmid 2012; Wilson 2013). Barosh et al. examined food availability and cost of a health and sustainability (H&S) food basket, developed according to the principles of the Australian dietary guidelines as well as environmental impact. The food basket approach is a commonly used method for assessing and monitoring food availability and cost. The typical food basket was based on average weekly food purchases of a reference household made up of two adults and two children. For the H&S basket, food choices were based on health principles and environmental impact. The H&S basket was compared to the typical Australian basket and it was determined that the cost of the H&S basket was more than the typical basket in five socioeconomic areas; the most disadvantaged spent 30 percent more for the H&S basket. The authors concluded that the most disadvantaged groups at both neighborhood and household levels experienced the greatest inequality in accessing an affordable H&S basket. Macdiarmid et al. examined a sustainable diet (met all energy and nutrient needs and maximally decreased GHG emissions), a “sustainable with acceptability constraints” diet (added foods commonly consumed in the UK; met energy, nutrient, and fish recommendations as well as recommended minimum intakes for fruits and vegetables and did not exceed the maximum recommended for red and processed meat), and the average UK diet.They found that the sustainable diet that was generated would decrease GHG emissions from primary production (up to distribution) by 90 percent, but consisted of only seven foods. The acceptability constraints diet included 52 foods and was projected to reduce GHG emissions by 36 percent. This diet included meat and dairy but less than the average UK diet. The cost of the sustainable + acceptability diet was comparable to that of the average UK diet. These results showed that a sustainable diet that meets dietary requirements and has lower GHG can be achieved without eliminating meat or dairy products completely, or increasing the cost to the consumer. Lastly, Wilson et al. examined 16 dietary patterns modeled to determine which patterns would minimize estimated risk of chronic disease, cost, and GHG emissions. These patterns included low-cost and low-cost + low GHG diet patterns, as well as healthy patterns with high vegetable intakes including Mediterranean or Asian patterns, as well as the average New Zealand pattern. The authors found that diets that aimed to minimize cost and estimated GHG emissions also had health advantages, such as the simplified low-cost Mediterranean-style and simplified Asian-style diets, both of which would lower cardiovascular disease and cancer risk, compared to the average New Zealand diet. However, dietary variety was limited and further optimization to lower GHG emissions increased cost.

Overall, the studies were consistent in showing that higher consumption of animal-based foods was associated with higher estimated environmental impact, whereas consumption of more plant-based foods as part of a lower meat-based or vegetarian-style dietary pattern was associated with estimated lower environmental impact compared to higher meat or non-plant-based dietary patterns. Related to this, the total energy content of the diet was also associated with estimated environmental impact and higher energy diets had a larger estimated impact. For example, for fossil fuel alone, one calorie from beef or milk requires 40 or 14 calories of fuel, respectively, whereas one calorie from grains can be obtained from 2.2 calories of fuel (Pimental & Pimental 2003). Additionally, the evidence showed that dietary patterns that promote health also promote sustainability; dietary patterns that adhered to dietary guidelines were more environmentally sustainable than the population’s current average level of intake or pattern. Taken together, the studies agreed on the environmental impact of different dietary patterns, despite varied methods of assessing environmental impact and differences in components of environmental impact assessed (e.g. GHG emissions or land use). The evidence on whether sustainable diets were more or less expensive than typically consumed diets in some locations was limited and inconsistent.

Qualitative Assessment of the Collected Evidence:

Quality and Quantity
This was a reasonable body of consistent evidence with studies that directly addressed the question. The study quality for the body of evidence ranged from 7/12 to 12/12, using the critical appraisal checklist for economic evaluations (including key components of the British Medical Journal checklist for economic evaluations, together with the Eddy checklist on mathematical models (NIHR Evaluation, Trials and Studies Coordinating Centre (UK)).

Consistency
There was remarkable agreement between the fifteen studies regarding environmental footprints of different dietary patterns, despite varied methods and designs to answer the question.

Impact
The evidence supports Americans consuming the current Dietary Guidelines by increasing consumption of plant-based foods, modestly decreasing animal-based foods and decreasing excessive snacks/sweets. Promoting sustainable diets will contribute to food security for present and future generations by conserving valuable resources. Moving forward, care and attention will be needed to be sure that Americans have access to and can afford a sustainable pattern of eating.

Generalizability/External Validity
Studies were conducted in the US, the UK, Germany, the Netherlands, France, Spain, Italy, Australia, Brazil, and New Zealand. These are all high HDI countries with systems of national dietary guidance similar to the US. Most of the studies based their modeling on assumed average adult diets with average caloric intake to meet energy needs, i.e. general populations of healthy adults. Taken together, the evidence from the general healthy populations in the U.S. and primarily European countries is highly generalizable to the U.S. population.

Limitations
A limitation that was common to most of the studies was that health outcomes were not assessed in the available study, but were based on earlier work on specific dietary patterns, e.g. vegetarian, Mediterranean, Western, etc. There are also known limitations to the complex process of assessing the environmental impact of foods using the Life Cycle Assessments method.

Research Recommendations

1. Develop and test communication strategies to help motivate people of all ages to consume increasingly sustainable diets. This strategy will provide further rationale for the U.S. population to consume a dietary pattern closer to the Dietary Guidelines for Americans than is currently being consumed.
2. Develop and test systems to ensure that sustainable diets are affordable and available to all sectors of the population.
3. Develop more in-depth analysis of U.S. domestic dietary patterns and enhanced environmental sustainability with different production regimens for animal products, especially dairy and beef.
4. Develop updated analysis of environmental sustainability of dietary patterns with respect to fish consumption, nutrient profiles, and different production regimens (e.g. wild caught versus farm raised).

Table 1. Summary of Studies on Dietary Patterns and Sustainability

References

1. Aston LM, Smith JN, Powles JW. Impact of a reduced red and processed meat dietary pattern on disease risks and greenhouse gas emissions in the UK: a modelling study. BMJ Open. 2012;2(5). PMID: 22964113. http://www.ncbi.nlm.nih.gov/pubmed/22964113.
2. Baroni L, Cenci L, Tettamanti M, Berati M. Evaluating the environmental impact of various dietary patterns combined with different food production systems. Eur J Clin Nutr. 2007;61(2):279-86. PMID: 17035955. http://www.ncbi.nlm.nih.gov/pubmed/17035955.
3. Barosh L, Friel S, Engelhardt K, Chan L. The cost of a healthy and sustainable diet--who can afford it? Aust N Z J Public Health. 2014;38(1):7-12. PMID: 24494938. http://www.ncbi.nlm.nih.gov/pubmed/24494938.
4. de Carvalho AM, Cesar CL, Fisberg RM, Marchioni DM. Excessive meat consumption in Brazil: diet quality and environmental impacts. Public Health Nutr. 2013;16(10):1893-9. PMID: 22894818. http://www.ncbi.nlm.nih.gov/pubmed/22894818.
5. Hendrie GA, Ridoutt BG, Wiedmann TO, Noakes M. Greenhouse gas emissions and the Australian diet--comparing dietary recommendations with average intakes. Nutrients. 2014;6(1):289-303. PMID: 24406846. http://www.ncbi.nlm.nih.gov/pubmed/24406846.
6. Macdiarmid JI, Kyle J, Horgan GW, Loe J, Fyfe C, Johnstone A, et al. Sustainable diets for the future: Can we contribute to reducing greenhouse gas emissions by eating a healthy diet? Am J Clin Nutr. 2012;96(3):632-9. PMID: 22854399. http://www.ncbi.nlm.nih.gov/pubmed/22854399.
7. Meier T, Christen O. Environmental impacts of dietary recommendations and dietary styles: Germany as an example. Environ Sci Technol. 2013;47(2):877-88. PMID: 23189920. http://www.ncbi.nlm.nih.gov/pubmed/23189920.
8. Peters CJ, Wilkins JL, Fick GW. Testing a complete-diet model for estimating the land resource requirements of food consumption and agricultural carrying capacity: The New York State example. Renewable agriculture and food systems. 2007;22(2):145-53. http://journals.cambridge.org/action/displayAbstract?fromPage=online&aid=1091328&fileId=S1742170507001767.
9. Pimentel D, Pimentel M. Sustainability of meat-based and plant-based diets and the environment. Am J Clin Nutr. 2003;78(3 Suppl):660S-3S. PMID: 12936963. http://www.ncbi.nlm.nih.gov/pubmed/12936963.
10. Pradhan P, Reusser DE, Kropp JP. Embodied greenhouse gas emissions in diets. PLoS One. 2013;8(5):e62228. PMID: 23700408. http://www.ncbi.nlm.nih.gov/pubmed/23700408.
11. Saez-Almendros S, Obrador B, Bach-Faig A, Serra-Majem L. Environmental footprints of Mediterranean versus Western dietary patterns: beyond the health benefits of the Mediterranean diet. Environ Health. 2013;12:118. PMID: 24378069. http://www.ncbi.nlm.nih.gov/pubmed/24378069.
12. Scarborough P, Allender S, Clarke D, Wickramasinghe K, Rayner M. Modelling the health impact of environmentally sustainable dietary scenarios in the UK. Eur J Clin Nutr. 2012;66(6):710-5. PMID: 22491494. http://www.ncbi.nlm.nih.gov/pubmed/22491494.
13. van Dooren C, Marinussen M, Blonk H, Aiking H, Vellinga P. Exploring dietary guidelines based on ecological and nutritional values: A comparison of six dietary patterns. Food Policy. 2014;44(0):36-46. http://www.sciencedirect.com/science/article/pii/S0306919213001620.
14. Vieux F, Soler LG, Touazi D, Darmon N. High nutritional quality is not associated with low greenhouse gas emissions in self-selected diets of French adults. Am J Clin Nutr. 2013;97(3):569-83. PMID: 23364012. http://www.ncbi.nlm.nih.gov/pubmed/23364012.
15. Wilson N, Nghiem N, Ni Mhurchu C, Eyles H, Baker MG, Blakely T. Foods and dietary patterns that are healthy, low-cost, and environmentally sustainable: a case study of optimization modeling for New Zealand. PLoS One. 2013;8(3):e59648. PMID: 23544082. http://www.ncbi.nlm.nih.gov/pubmed/23544082

References not included in the review:

1. Higgins JPT GSe. Cochrane Handbook for Systematic Reviews of Interventions Version 5.1.0: The Cochrane Collaboration; 2011. Available from: www.cochrane-handbook.org.
2. Drummond MF, Jefferson TO. Guidelines for authors and peer reviewers of economic submissions to the BMJ. The BMJ Economic Evaluation Working Party. BMJ. 1996;313(7052):275-83. PMID: 8704542. http://www.ncbi.nlm.nih.gov/pubmed/8704542.
3. Eddy D. The role of mathematical modelling in Assessing medical technology,. Technology Assessment. 1985:144-54.
4. Stevenson M, Lloyd-Jones M, Morgan MY, Wong R. Non-invasive diagnostic assessment tools for the detection of liver fibrosis in patients with suspected alcohol-related liver disease: a systematic review and economic evaluation. Health Technol Assess. 2012;16(4):1-174. PMID: 22333291. http://www.ncbi.nlm.nih.gov/pubmed/22333291.
5. Goedkoop M SR. The Eco-Indicator 99, A Damage Oriented Method for Life Cycle Assessment Methodology Report 2000. Available from: https://www.researchgate.net/publication/285641235_The_ecoindicator-99_A_damage_oriented_method_for_life_cycle_impact_assessment_Methodology_annex.

Supplementary Material: Food Components/Individual Foods for Sustainability Studies

High vs Low Sustainable Diets
(Individual foods provided when reported)

^‡Red meat as beef, veal, pork, lamb, mutton and goat, either fresh, minced (including hamburgers) or frozen, but unprocessed other than by cooking with heat. Although processed meats were primarily red meats, the term ‘red meat’ was used to refer to ‘unprocessed red meat’. White meat as meat from poultry, fresh, minced or frozen, but unprocessed other than by cooking with heat. Processed meat as meat preserved by smoking, curing, salting or addition of nitrates, nitrites or other preservatives. Under this definition, processed meats were primarily red, but included white meats, and included ham, bacon, pastrami, salami, sausages and processed deli or luncheon meats.

^§ The H&S diet was based on three overarching principles: (i) any food that is consumed above a person's energy requirement represents an avoidable environmental burden in the form of greenhouse gas emissions, use of natural resources and pressure on biodiversity; (ii) reducing the consumption of discretionary food choices, which are energy-dense and highly processed and packaged, reduces both the risk of dietary imbalances and the use of environmental resources; and (iii) a diet comprising less animal- and more plant-derived foods delivers both health and ecological benefits.

^¶Countries characterized by high calorie diets exhibit a production mode that needs high fossil energy inputs (1,800– 3,500 kcal/cap/day). In countries with low calorie diets, the energy input can be as low as 80–150 kcal/cap/day. But non-CO₂ GHG emission intensities are relatively high for low and the moderate calorie diets. Therefore, total GHG emissions are only slightly higher for high and very high calorie diets (2.48–6.10 kg CO₂ eq./cap/day) compared to low and moderate calorie diets (1.43–4.48 kg CO₂ eq/cap/day).

^∞Obtained data on a wide range of individual food items and optimized towards a diet meeting nutritional requirements ("bottom-up" approach).

Supplementary Material: Search Plan and Results—Dietary Patterns & Sustainability

Search Strategy

Dates Searched: 02/20/2014 – 02/21/2014

Databases: Pubmed, Embase, Cochrane, Navigator

Year Range: 01/2000 – 02/2014

Search Terms and Dates): Total: 1685 (+ 5 dupes = 1690)

PubMed 1449 hits; 2/20/2014
(environmental footprint* OR Carbon Footprint*[tiab] OR environmental impact* OR food security* OR food insecurity* OR "Conservation of Natural Resources"[Mesh] OR "Greenhouse Effect"[Mesh] OR "Carbon Footprint"[Mesh] OR "Environmental Monitoring"[Mesh] OR ((environment*[tiab] OR food[major:noexp] OR food[ti] OR diet[major]) AND sustainab*[tiab])) OR ("Conservation of Natural Resources"[major:noexp] OR "Greenhouse Effect"[major:noexp] OR "Carbon Footprint"[major:noexp] OR

"Environmental Monitoring"[major:noexp]) OR ("Ecosystem"[Mesh] OR ecological system*[tiab] OR greenhouse*[tiab] OR "Ecosystem"[major] OR ecological system*[tiab] OR greenhouse*[tiab] OR “land use”[tiab] OR “water use”[tiab])

Eng/hum AND ("Study Characteristics" [Publication Type] OR “clinical trial”[ptyp] OR "Epidemiologic Studies"[Mesh] OR "Support of Research"[ptyp]) NOT (editorial[ptyp] OR comment[ptyp] OR news[ptyp] OR letter[ptyp] OR review[ptyp]) 

Embase 170; 2/20/2014

(MedDietScore OR adequacy index* OR kidmed OR “healthy eating index”) OR

((index OR score OR scoring) NEAR/3 ('diet quality' OR dietary OR nutrient* OR eating OR food OR dieti)):ti,ab

OR

(‘diet quality’ OR 'eating habit'/exp OR 'Mediterranean diet'/exp OR nordiet:ti,ab OR ‘nordic diet’:ti,ab OR DASH:ti,ab OR ‘dietary approaches to stop hypertension’:ti,ab OR vegan*:ab,ti  OR vegetarian*:ab,ti  OR 'vegetarian diet'/exp OR  'vegetarian'/exp OR ‘prudent diet’:ti,ab OR ‘western diet’:ti,ab OR omniheart:ti,ab OR omni:ti OR ‘plant based diet’) OR ((dietary OR eating OR food OR diet) NEAR/2 (pattern? OR habit? OR profile? OR recommendation? OR guideline?))  OR (('ethnic, racial and religious groups'/exp  or Okinawa* OR ‘mediterranean') AND (diet/exp OR eating/exp OR 'food intake'/de)) 

AND

'environmental sustainability'/exp OR 'food security'/exp OR 'carbon footprint'/exp OR 'human impact (environment)'/exp OR 'greenhouse effect'/exp OR 'ecosystem'/de OR 'land use'/de OR 'plant water use'/exp OR (food NEAR/5 sustainab*) OR 'food insecurity'/exp OR ‘environmental impact’ OR (environment* NEAR/2 footprint) OR diet* NEAR/5 sustainab* AND [humans]/lim AND [english]/lim AND [embase]/lim

NOT [medline]/lim

Cochrane 8; 2/21/2014
(“diet quality” OR (dietary NEXT guideline*) OR (dietary NEXT recommendation*) OR ((food OR eating OR diet OR dietary) NEAR/3 (pattern OR profile OR habit)) OR (eating NEXT style*) OR (“dietary approaches to stop hypertension” OR vegan* OR vegetarian* OR “prudent diet” OR “western diet” OR nordiet OR “Nordic diet” OR omniheart OR "Optimal Macronutrient Intake Trial to Prevent Heart Disease" OR ((asia* OR western OR Okinawa* OR “plant based” OR Mediterranean OR DASH) AND (diet* OR food)))  OR ((Index OR score OR indices OR scoring) NEAR/3 (dietary OR diet OR food OR eating)) OR “adequacy index” OR kidmed OR MedDietScore)

AND

((Food OR environment* OR diet) NEAR/4 (sustainab*)) OR ((carbon OR environment*) NEAR/2 footprint) OR “food insecurity” OR “food security” OR (greenhouse NEAR/1 effect*) OR (“greenhouse gas” NEAR/1 emission*) OR “land use” OR “water use”

Navigator (FSTA/BIOSIS/CAB Abstracts) 63; 2/21/2014

(MedDietScore or "adequacy index" or kidmed or ((index or score) near/2 (("diet quality") or dietary or nutrient* or eating or food or diet)) or ((Diet or dietary or eating or food) near/2 (pattern* or profile* or habit* or guideline* or recommendation*) or "diet quality") or “dietary approaches to stop hypertension” or vegan* or vegetarian* or "prudent diet" or "western diet" or omniheart or "Optimal Macronutrient Intake Trial to Prevent Heart Disease" or nordiet  or “Nordic diet” OR  ((Okinawa* or asia* or Chinese or japan* or Hispanic* or ethnic or "plant based" or title:omni or title:Mediterranean or DASH) near/3 (title:diet* or abstract:diet*))) 

AND

((Food OR environment* OR diet) NEAR/4 sustainab*) OR ((carbon OR environment*) NEAR/2 footprint) OR “food insecurity” OR “food security” OR (greenhouse NEAR/1 effect*) OR (“greenhouse gas” NEAR/1 emission*) OR “land use” OR “water use”

Analytical Framework

Inclusion Criteria

PubMed, Cochrane, Embase, and Navigator were searched for original research articles published in English in peer-reviewed journals. Studies published since January 2000 with subjects who were healthy or at elevated chronic disease risk from countries with high or very high human development were considered. Study designs included in the review were randomized and non-randomized controlled trials, prospective cohort studies, cross-sectional studies, before and after studies, and case-control studies. Only systematic reviews, meta-analyses, and narrative reviews were excluded. Trials were required to have ≥10 subjects per arm and a follow-up of ≥80%. Studies that examined low-calorie diets and other treatment diets were excluded. Finally, studies were required to include a description of the dietary pattern along with sustainability or food security outcomes.

Search Results

Included Articles

The following articles have been determined to be relevant for inclusion in the body of evidence:

Excluded Articles

The table below lists the excluded articles with at least one reason for exclusion, but may not reflect all possible reasons.