Hostname: page-component-586b7cd67f-t7czq Total loading time: 0 Render date: 2024-11-25T21:16:13.078Z Has data issue: false hasContentIssue false

Study sponsorship and the nutrition research agenda: analysis of randomized controlled trials included in systematic reviews of nutrition interventions to address obesity

Published online by Cambridge University Press:  19 December 2016

Alice Fabbri
Affiliation:
Centre of Research in Medical Pharmacology, University of Insubria, Varese, Italy Charles Perkins Centre and Faculty of Pharmacy, The University of Sydney, Camperdown NSW 2006, Australia
Nicholas Chartres
Affiliation:
Charles Perkins Centre and Faculty of Pharmacy, The University of Sydney, Camperdown NSW 2006, Australia
Gyorgy Scrinis
Affiliation:
Faculty of Veterinary and Agricultural Sciences, The University of Melbourne, Parkville, VIC, Australia
Lisa A Bero*
Affiliation:
Charles Perkins Centre and Faculty of Pharmacy, The University of Sydney, Camperdown NSW 2006, Australia
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective

To categorize the research topics covered by a sample of randomized controlled trials (RCT) included in systematic reviews of nutrition interventions to address obesity; to describe their funding sources; and to explore the association between funding sources and nutrition research topics.

Design

Cross-sectional study.

Subjects

RCT included in Cochrane Reviews of nutrition interventions to address obesity and/or overweight.

Results

Two hundred and thirteen RCT from seventeen Cochrane Reviews were included. Funding source and authors’ conflicts of interest were disclosed in 82·6 and 29·6 % of the studies, respectively. RCT were more likely to test an intervention to manipulate nutrients in the context of reduced energy intake (44·2 % of studies) than food-level (11·3 %) and dietary pattern-level (0·9 %) interventions. Most of the food industry-sponsored studies focused on interventions involving manipulations of specific nutrients (66·7 %). Only 33·1 % of the industry-funded studies addressed dietary behaviours compared with 66·9 % of the non-industry-funded ones (P=0·002). The level of food processing was poorly considered across all funding sources.

Conclusions

The predominance of RCT examining nutrient-specific questions could limit the public health relevance of rigorous evidence available for systematic reviews and dietary guidelines.

Type
Research Papers
Copyright
Copyright © The Authors 2016 

Public health nutrition policies are essential for controlling the epidemics of obesity, CVD and type 2 diabetes( 1 , 2 ). Many political, social and economic factors contribute to dietary guideline and nutrition policy development, but a fundamental principle is that they should be informed by relevant, rigorous evidence( Reference Brannon, Taylor and Coates 3 ). Systematic reviews have been extensively used as the evidence base for the development of both clinical and public health guidelines( Reference Qaseem, Snow and Owens 4 ). In recent years the use of systematic reviews has also become increasingly common to address nutrition-related questions. The most recent national dietary guidelines in the USA and Australia were based on systematic reviews and Food Standards Australia New Zealand currently requires systematic reviews to support high-level health claims on food labels( 5 7 ). The Cochrane Collaboration has launched the Cochrane Nutrition Field to increase the number, quality and relevance of Cochrane Nutrition Reviews( Reference Lawrence, Naude and Armstrong 8 ).

A major limitation of the growing use of systematic reviews for the development of guidelines, policies and regulations is that their scope is limited by the topics of the original research studies available to be included in the reviews. In addition, systematic reviews are often limited to randomized controlled trials (RCT). This could lead to systematic reviews that are not relevant or representative of the target population for the guidelines( Reference Odierna and Bero 9 ).

The characteristics of the research agenda (namely the questions being studied) are particularly important in nutrition because the questions asked, such as nutrient-specific questions, could produce evidence that is disproportionately focused on certain policy solutions, such as food fortification( Reference Lawrence, Wingrove and Naude 10 ). This research could then distract from considering other possible public health solutions, such as taxes or regulating food advertising or processed food commodities. Studies to address complex policy questions relevant to public health nutrition also present methodological challenges that may contribute to them being less studied( Reference Pelletier, Porter and Aarons 11 ).

Several actors (industry, government and non-profit stakeholders) have the potential to affect the policy-making process by influencing the nutrition research agenda( Reference Marks 12 , Reference Moodie, Stuckler and Monteiro 13 ). Data from other sectors (e.g. tobacco, pharmaceuticals) has previously demonstrated biases in the design, conduct and publication of research that are related to funding sources and investigators’ conflicts of interest( Reference Barnes and Bero 14 Reference Lundh, Sismondo and Lexchin 16 ). Corporate interests can manipulate the research agenda by funding research that supports their position and suppressing research that does not( Reference Bero 17 ). For example, the tobacco industry undermined the research agenda on the health effects of second-hand smoke by funding studies suggesting that other components of indoor air were more harmful than tobacco( Reference Barnes and Bero 14 ). Echoing tactics used by the tobacco industry, the sugar industry has influenced the dental research agenda ‘as part of a strategy to deflect attention away from sugar restriction as a means to control caries’( Reference Kearns, Glantz and Schmidt 18 ).

Despite some case studies documenting discrepancies in the design and conclusions of research sponsored by the food industry compared with other funders( Reference Bes-Rastrollo, Schulze and Ruiz-Canela 19 Reference Vartanian, Schwartz and Brownell 22 ), a systematic analysis examining whether funding sources influence the nutrition research agenda has not been done. Analysing the relationship between funders and the nutrition research agenda could assist both researchers and policy makers in understanding whether an entire area of research has been funded only by stakeholders with conflicts of interest and in identifying new or neglected areas which may require further investigation.

Therefore the objectives of the present study were to:

  1. 1. categorize the research topics covered by a sample of RCT included in systematic reviews of nutrition interventions to address obesity;

  2. 2. describe their funding sources; and

  3. 3. explore the association between funding sources and nutrition research topics.

Methods

Study selection

We analysed RCT that were included in Cochrane Reviews of nutrition interventions aimed at reducing obesity. Cochrane Reviews cover a broad range of clinical and public health interventions and have been used to support the WHO Nutrition Guidelines Programme( Reference Lawrence, Naude and Armstrong 8 ). We searched the Cochrane Database of Systematic Reviews on 24 July 2015 using the following broad search strategy: obesity AND (nutrition* OR diet*), to identify reviews that included nutrition interventions to prevent or reduce obesity. We focused on obesity because this is a complex condition that could be addressed by a variety of interventions ranging from patient-specific to system-wide interventions( 23 ). Two investigators screened the retrieved records for obvious exclusions. We excluded reviews that did not include studies of nutrition interventions or did not have measures of obesity or overweight as primary or secondary outcomes (see online supplementary material, Supplemental Tables 1 and 2 for lists of included and excluded Cochrane Reviews). Since the emphasis of Cochrane Reviews has been on the identification and assessment of RCT, we then included all the RCT that were included in the selected Cochrane Reviews if they investigated nutrition interventions or a combination of nutrition and non-nutrition interventions (e.g. drug, physical activity). For this purpose, we defined nutrition interventions as all dietary interventions that modify energy, dietary patterns, whole food and/or nutrient intake. We included studies where the primary or secondary outcomes were BMI or other measures of overweight and obesity (e.g. body composition, waist-to-hip ratio).

Data extraction

The full text was retrieved for each included RCT. If the same study appeared in more than one Cochrane Review, we included it only once. The following data were collected from each RCT publication.

  1. 1. Study characteristics: target group, location, year of publication.

  2. 2. Disclosed funding source(s): these were classified as food industry, pharmaceutical industry, other for-profit entities, governmental agencies, not for profit, mixed funding sources, unknown (when the funding source was disclosed in the article, but information about the sponsor could not be retrieved from the Internet) or no funding disclosed.

  3. 3. Disclosure of investigators’ conflicts of interest.

  4. 4. Research topics classified according to the categories described below.

The taxonomy we used to code research topics was inspired by a framework for food classification( Reference Scrinis 24 ) that was informed by iterative coding of a sample of nutrition intervention studies and by input from a multidisciplinary group of public health researchers, physicians, dieticians, nutritionists and social scientists. We coded research topics by: (i) the level of dietary composition; (ii) level of food processing; and (iii) dietary behaviours. Each category was coded as ‘yes’ or ‘no’. The coding categories are described in more detail below.

Level of dietary composition

This categorization is based on the differentiation between the three levels of dietary composition discussed in the nutrition literature: the nutrient level, the food level and the dietary pattern level( Reference Scrinis 24 , Reference Tapsell, Neale and Satija 25 ). Since our sample included nutrition interventions to address obesity, we expected most of the studies to have an energy component, often without the study specifying the restriction of one nutrient over another to achieve energy restriction; therefore the additional category of energy was added to the initial taxonomy. Specifically, we assessed whether the intervention described in the article focused on

  • energy level: focus on energy restriction;

  • nutrient level: focus on changing intake of specific nutrients such as fat, protein, carbohydrates, etc.;

  • food level: focus on changing consumption of a single food or food product, food groups or food combinations, such as vegetables, fruit, grain foods, meats, fish, eggs, or processed foods such as sugar-sweetened beverages, high-energy snacks, fast foods, etc.;

  • dietary pattern level: focus on the overall dietary pattern or cuisine, for example the Mediterranean diet; or

  • not applicable: when there was not enough information in the article or the intervention did not fit in any of the above categories.

Our a priori hypothesis was that while a focus on the nutrient level is a common feature of nutrition research( Reference Jacobs and Tapsell 26 ), the food industry has supported nutrient-level studies as a means of generating evidence to support its nutritional claims on food products( Reference Scrinis 24 ).

Level of food processing

We determined whether the nutrition intervention studied in each RCT mentioned food processing, namely the type, level and intensity of technological intervention used in the production of food( Reference Scrinis 24 ). A study was rated as ‘yes’ if it mentioned highly processed foods, defined as foods that are constructed primarily out of processed–reconstituted and refined–extracted materials, either specifically (e.g. sugar-sweetened beverages) or descriptively (e.g. foods high in energy with low nutrient density), or as part of a complex intervention (e.g. mentioning limiting consumption of high-energy snacks and fast foods on one part of a nine-part weight-reduction intervention). The initial version of our taxonomy included the multiple levels of processing: whole foods, refined–processed foods and processed–reconstituted foods. However, when we pilot tested the taxonomy, we found that some studies defined the level of processing very poorly and many of the complex interventions included all three levels of food processing. Therefore, we modified the initial taxonomy to code for the mention of highly processed foods or not.

Our a priori hypothesis was that there is currently a lack of studies focusing on the evaluation of nutrients, foods and dietary patterns in terms of the levels of processing and that the food industry is not funding this kind of research( Reference Scrinis 24 , Reference Monteiro 27 ).

Dietary behaviours

A study was coded as ‘yes’ for dietary behaviours if the nutrition intervention addressed dietary behaviours (e.g. portion size, menu planning and cooking style, timing of meals, eating while watching television, meal skipping, self-control/self-monitoring of food intake). Our a priori hypothesis was that the food industry is less likely to fund studies aimed at improving dietary behaviours.

Double coding

For the analysis of the nutrition research topics, 30 % of the publications were randomly selected to be coded independently by two reviewers and any disagreement was resolved by consensus.

On average, the percentage of agreement between the two coders was 91·4 %.

Analysis

Categorical variables were described using frequency tables. Cross-tabulations were performed for evaluating possible associations between the funding sources and the research topics using the χ 2 test. All analyses were performed using the statistical software package IBM SPSS Statistics Version 22.0.

Results

Study selection

The electronic database search yielded forty-four Cochrane Reviews (Fig. 1). Of these, twenty-seven were excluded because they did not match our inclusion criteria (online supplementary material, Supplemental Table 2).

Fig. 1 Flowchart of study selection (RCT, randomized controlled trial)

Of the 272 RCT contained in the seventeen remaining Cochrane Reviews (online supplementary material, Supplemental Table 1), fifty-nine were excluded because they did not match the inclusion criteria (Fig. 1). Five studies appeared in more than one Cochrane Review and they were each included once. The 213 included RCT evaluated a broad range of nutrition interventions targeting children/adolescents (n 25; 11·7 %), adults (n 114; 53·5 %) or both (n 74; 34·7 %). The range of publication dates was 1978–2013 and 31·5 % of the included studies were published before 2000. The majority of the RCT were conducted in the Americas; US-based studies represented 55·4 % (n 118) of the total sample (Table 1).

Table 1 Location of study site by WHO Region in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2013 (n 213)

Funding disclosure

Of the 213 included RCT, 82·6 % (n 176) disclosed their funding source. Of these, 175 RCT disclosed the presence of one or multiple sponsors, while in one study the investigators stated they received no funding for their work. Of the 175 RCT that disclosed having a sponsor, 37·1 % (n 65) were funded by governmental or intergovernmental agencies, while food industry sponsorship (alone or with other sponsors) was disclosed in 13·7 % (n 24) of the studies (Table 2). The disclosure rate increased over time: from 74·2 % for the studies published before the year 2000, to 85·3 % for the ones published between 2000 and 2009, to 93·3 % for the ones published after 2009. We chose these cut-offs because of the increasing attention that has been given to the need for transparency in recent years and the consequent adoption of disclosure policies by most scientific journals( Reference Drazen, Van Der Weyden and Sahni 28 , 29 ).

Table 2 Categories of funding sources for studies disclosing a sponsor in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2012 (n 175)

Investigators’ conflicts of interest disclosure

Of the 213 included RCT, 70·4 % (n 150) did not contain a conflicts of interest disclosure. In twenty-two studies (10·3 %) the authors disclosed financial conflicts of interest, in one study (0·5 %) the authors disclosed non-financial conflicts of interest, and in forty (18·8 %) the authors stated they had no financial conflicts of interest. The disclosure rate increased over time. Conflicts of interest disclosure was completely absent in the papers published before the year 2000, the disclosure rate was 39·0 % in the papers published between 2000 and 2009, and 66·7 % in the papers published after 2009.

Research topics

Table 3 shows the nutrition research topics studied in the included RCT. Most of the RCT studied interventions that involved a combination of energy-, nutrient- and food-level approaches. As anticipated for interventions to reduce obesity, most trials aimed to restrict energy intake and vary the dietary composition, while sixteen (7·5 %) varied energy intake only. Ninety-four trials (44·2 %) tested interventions focused on specific nutrients, fifty-eight (27·2 %) analysed a combination of nutrients and foods, while only twenty-four (11·3 %) analysed whole foods. Only two trials (0·9 %) included an analysis of dietary patterns (e.g. Mediterranean diet). Highly processed foods were considered in less than one-third of the tested interventions and slightly more than half the interventions considered dietary behaviours such as portion size or timing of meals.

Table 3 Nutrition research topics in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2013 (n 213)

Research topics by funding sources

Table 4 shows the results of the analysis of nutrition research topics by funding source. To test our hypotheses that research with a focus on nutrients has been supported by the food industry while research including an analysis of food processing has not been supported by the food industry, we compared the research topics of food industry-sponsored v. non-food industry-sponsored studies. The food industry sponsorship category includes studies sponsored solely by the food industry or with mixed food industry and other funding (n 24). The non-food industry category includes studies funded by governmental agencies, non-profit sector and mixed funding sources without the presence of food industry (n 127). We did not include in this analysis the trials funded by pharmaceutical companies and the ones with undisclosed funding sources, therefore the total number of included RCT is 151.

Table 4 Research topics by funding source* in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2012 (n 151)

Column percentages are calculated.

*The food industry-sponsored category includes studies sponsored solely by the food industry or with mixed food industry and other funding; the non-food industry category includes studies funded by governmental agencies, non-profit sector and mixed funding sources without the presence of food industry.

As shown in Table 4, most of the food industry-sponsored studies focused on interventions involving manipulations of specific nutrients (66·7 %). The non-food industry-funded trials addressed different levels of dietary composition, including whole foods and a combination of foods and nutrients. The dietary pattern level was poorly considered across all funding sources. There was no statistically significant association between the research sponsorship and the different levels of dietary composition addressed in the included RCT (χ 2 test: P=0·083). With regard to food processing, only 25·0 % (n 6) of industry-funded studies and 31·5 % (n 40) of the non-industry-funded interventions mentioned the issue of highly processed foods. No statistically significant differences were observed between the two categories of funding sources (χ 2 test: P=0·526). Finally, non-industry-funded trials were more likely to address dietary behaviours compared with food industry-sponsored studies (χ 2 test: P=0·002).

Discussion

The nutrition research agenda

Our findings show a gap in the research topics covered by RCT of nutrition intervention studies. The majority of the included RCT involved some manipulation of nutrients in a context of a reduced energy intake, while there was less study of food-level and dietary pattern-level interventions. A reductive focus on nutrients has been a feature of nutrition research in the past decades( Reference Tapsell, Neale and Satija 25 , Reference Jacobs and Tapsell 26 , Reference Fardet and Rock 30 ). A fundamental characteristic of nutritional reductionism is that ‘the role of nutrients has often been interpreted outside the context of the foods, dietary patterns, and broader social contexts in which they are embedded’( Reference Scrinis 24 ). While recognizing the importance of understanding the biological effect of nutrients, a nutrient approach is likely to offer only a decontextualized, context-free interpretation of the complex relationship between diet and health outcomes. In this regard, some researchers have already called for an alternative research approach, namely a ‘top-down’ approach that works ‘from complex to simple’( Reference Jacobs and Tapsell 26 ), starting from the dietary pattern level and working backwards to the nutrient level( Reference Fardet and Rock 30 ). In addition, nutritional ecology studies suggest that powerful insights into the causes of obesity can be gained by studying the interactive rather than the independent effects of nutrients( Reference Raubenheimer, Machovsky-Capuska and Gosby 31 ). Since people eat foods and not isolated nutrients, dietary guidelines and policies built upon research on foods and dietary patterns might more effectively inform people’s behaviours and food choices( Reference Tapsell, Neale and Satija 25 , Reference Cespedes and Hu 32 ).

Our findings also suggest that the research agenda may be influenced by industry interests. We found that most of the food industry-sponsored studies focused on interventions involving manipulations of specific nutrients. Some researchers have argued that in response to concerns about how diet contributes to the obesity epidemic, the food manufacturing industry has responded by emphasizing the benefits of particular nutrients in their foods( Reference Scrinis 24 ). Thus, the food industry may have an incentive to fund research showing that certain types of nutrients are beneficial to health. A focus on nutrients – rather than on dietary patterns or interactions among nutrients within foods and within the body - may produce evidence that will allow the food industry to market highly processed foods using nutrient content claims (e.g. functional foods). For example, a systematic review of highly processed breakfast cereals commissioned by the Australian Breakfast Cereal Manufacturers Forum suggests that cereal consumption is associated with lower rates of diabetes and CVD( Reference Williams 33 ) and cereals are often advertised as having beneficial health outcomes( Reference Scrinis 24 ).

Despite the evidence that processed foods are a significant driver in the global rise of overweight, obesity and associated diseases( Reference Moodie, Stuckler and Monteiro 13 , Reference Levy, Canella and Martins 34 ), our findings showed that little research describes the level of processing of the food being studied. This lack of data cannot provide the evidence needed to inform guidelines and policies that could limit consumption of processed foods. Food classifications have often grouped foods according to their nutrient profile or unprocessed food groups (e.g. fruits, vegetables), whereas the nature and extent of food processing should also be included as part of the description of the intervention( Reference Monteiro, Levy and Claro 35 ). This lack of categorization by level of food processing has led to examples of processed foods such as ketchup being classified as a school-lunch vegetable in the USA( Reference Thornton and Schram 36 ).

Our findings identified that food industry-sponsored studies were significantly less likely to address dietary behaviours as part of an intervention compared with non-food industry-sponsored studies. While nutrition-specific interventions are necessary to measure the effect of specific nutrients, there is evidence to suggest that they fail to address the underlying complexities of what is required to achieve and maintain weight loss in obese populations( Reference Peirson, Douketis and Ciliska 37 , Reference Oude Luttikhuis, Baur and Jansen 38 ). In a food system where dietary intake is no longer influenced primarily by food availability, a research agenda that continues to mostly examine nutrients and foods in isolation and not in the context of dietary and other behaviours will likely fail to ease the growing burden of obesity.

Sponsors’ interests are not the only drivers of a nutrient focus. Studies to address complex nutrition policy problems present enduring challenges that may contribute to them receiving less attention and funding( Reference Pelletier, Porter and Aarons 11 ). Moreover, the current process for evidence synthesis and translation itself tends to favour a nutrient-oriented approach. A recent study has shown that in the field of undernutrition there are significantly more systematic reviews, guidelines and policy statements related to nutrition-specific interventions (e.g. fortification and supplementation) compared with nutrition-sensitive interventions that could instead address the underlying causes of the problem( Reference Lawrence, Wingrove and Naude 10 ).

Finally, our results show a gap in the research topics covered by RCT of nutrition interventions to decrease obesity, but diet–disease relationships are often evaluated using non-randomized studies and many dietary guidelines are currently supported by evidence from observational studies( 6 ). The Cochrane Collaboration is currently exploring evidence synthesis methods that are needed to address complex nutrition interventions which are often studied using observational research( Reference Lawrence, Naude and Armstrong 8 ). Therefore, further research is needed to evaluate whether the gaps in the topics covered by RCT included in systematic reviews apply also to non-randomized studies.

Reporting of funding source and investigators’ conflicts of interest

We found that about 20 % of the studies did not report funding sources, although disclosure rates increased over time. The low proportion of food industry-sponsored studies in our sample could be due to a lack of reporting of industry sponsorship. This phenomenon has already been reported in other fields; for example, the tobacco industry funded institutes and organizations that hid the true extent of industry involvement in their projects( Reference Schick and Glantz 39 ).

We also found a low rate of reporting of investigators’ conflicts of interest. Although a recent study found that all core clinical journals require disclosure of author financial conflicts of interest( Reference Shawwa, Kallas and Koujanian 40 ), these disclosure policies are still not enforced across all journals. The failure to comply with the current conflicts of interest disclosure requirements has been reported in several studies( Reference Ruff 41 Reference Forsyth, Odierna and Krauth 43 ); therefore it is likely that the disclosures we relied on did not give an accurate assessment of authors’ conflicts of interest.

A recent call for disclosure of funding sources and authors’ conflicts of interest in all abstracts listed in PubMed could improve reporting across all journals( Reference McCarthy 44 ). If funding sources and investigator conflicts of interest are not reported or only partially reported, differences in the design, conduct and publication of industry- compared with non-industry-sponsored studies cannot be empirically investigated. Readers will not be able to determine whether an area of research has been funded only by certain stakeholders and might be left unsure about how to interpret the likelihood of bias related to funding source( Reference Roseman, Turner and Lexchin 45 ). This reporting gap may also have important research and policy implications by making it difficult to estimate the impact of funding sources on the studies included in systematic reviews and, consequently, public health guidelines and regulations. A recent revision of the methodological standards for Cochrane Reviews requires that funding sources for included studies be listed in the included studies table( 46 ). However, most Cochrane Reviews do not currently contain these disclosures( Reference Roseman, Turner and Lexchin 45 ).

Limitations

Our study has several limitations. First, we searched the Cochrane Database of Systematic Reviews using the following terms: obesity AND (nutrition* OR diet*). It is possible that this search strategy might have missed potentially eligible reviews. However, the search strategy is very broad and the large number of reviews identified that did not meet our inclusion criteria suggests that our initial search was sensitive rather than specific.

Another limitation is that we analysed only RCT included in Cochrane Reviews. However, Cochrane Reviews cover a broad range of interventions targeted at adults, children or both, involve a comprehensive search for evidence, and their topics are often driven by the availability of original research. Thus, the studies included in the Cochrane Reviews are likely a good representation of the type of RCT that have been conducted on nutrition interventions to reduce obesity. In addition, we focused on obesity because it is a complex health condition that could be addressed by a wide variety of nutrition interventions. Our findings may be different if we focused on other harm outcomes, such as CVD, or the beneficial effects of foods.

Another challenge of the present study was the development of a taxonomy able to capture the complexity of research topics examined in nutrition intervention studies. Moreover, we relied only on the intervention description provided in the publications. Sometimes the quality of the description was poor or not detailed, so we might have missed important aspects of the intervention. Accurate and complete descriptions of complex interventions are crucial to ensuring not only the evaluation of interventions but also their replicability( Reference Hoffmann, Glasziou and Boutron 47 ).

The low proportion of food industry-sponsored studies compared with non-food industry-sponsored studies may explain why we did not observe statistically significant differences between funding sources. Food industry sponsorship may have been under-reported.

Conclusions

Our findings show a gap in the research topics covered by RCT of nutrition interventions to address obesity and suggest that the research agenda may be influenced by industry interests. The predominance of nutrient-specific topics in the nutrition research agenda could limit the public health relevance of rigorous evidence available for systematic reviews and dietary guidelines. More independent funding of nutrition research could address some of the imbalance in the research agenda. Effective nutrition policies need to be informed by evidence on a wider variety of interventions.

Acknowledgements

Financial support: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Conflict of interest: L.A.B. is Co-Chair of the Cochrane Steering Group, for which The University of Sydney receives payment. Authorship: A.F., G.S. and L.A.B conceived the study and designed the data collection tool. A.F. and N.C. collected the data. A.F., N.C. and L.A.B. analysed the data. A.F. wrote the first draft of the paper. N.C., G.S. and L.A.B. contributed to the writing of the paper and approved the final version. Ethics of human subject participation: Not applicable.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1368980016003128

References

1. World Health Organization (2015) Non communicable diseases, Fact sheet. http://www.who.int/mediacentre/factsheets/fs355/en/ (accessed May 2016).Google Scholar
2. World Health Organization (2015) Obesity and overweight, Fact sheet. http://www.who.int/mediacentre/factsheets/fs311/en/ (accessed May 2016).Google Scholar
3. Brannon, PM, Taylor, CL & Coates, PM (2014) Use and applications of systematic reviews in public health nutrition. Annu Rev Nutr 34, 401419.CrossRefGoogle Scholar
4. Qaseem, A, Snow, V, Owens, DK et al.; Clinical Guidelines Committee of the American College of Physicians (2010) The development of clinical practice guidelines and guidance statements of the American College of Physicians: summary of methods. Ann Intern Med 153, 194199.CrossRefGoogle ScholarPubMed
5. US Department of Health and Human Services (2015) Dietary Guidelines for Americans 2015–2020. http://health.gov/dietaryguidelines/2015/guidelines/ (accessed May 2016).Google Scholar
6. National Health and Medical Research Council (2011) A review of the evidence to address targeted questions to inform the revision of the Australian Dietary Guidelines. https://www.eatforhealth.gov.au/sites/default/files/files/the_guidelines/n55d_dietary_guidelines_evidence_report.pdf (accessed May 2016).Google Scholar
7. Food Standards Australia New Zealand (2015) Reviews of food–health relationships for high level health claims. http://www.foodstandards.gov.au/consumer/labelling/nutrition/pages/reviewsforhighlevelc3090.aspx (accessed May 2016).Google Scholar
8. Lawrence, M, Naude, C, Armstrong, R et al. (2016) A Call to Action to reshape evidence synthesis and use for nutrition policy. Cochrane Library. http://www.cochranelibrary.com/editorial/10.1002/14651858.ED000118 (accessed November 2016).Google Scholar
9. Odierna, DH & Bero, LA (2009) Systematic reviews reveal unrepresentative evidence for the development of drug formularies for poor and nonwhite populations. J Clin Epidemiol 62, 12681278.Google Scholar
10. Lawrence, M, Wingrove, K, Naude, C et al. (2016) Evidence synthesis and translation for nutrition interventions to combat micronutrient deficiencies with particular focus on food fortification. Nutrients 8, 555.Google Scholar
11. Pelletier, DL, Porter, CM, Aarons, GA et al. (2013) Expanding the frontiers of population nutrition research: new questions, new methods, and new approaches. Adv Nutr 4, 92114.Google Scholar
12. Marks, JH (2014) Toward a systemic ethics of public–private partnerships related to food and health. Kennedy Inst Ethics J 24, 267299.Google Scholar
13. Moodie, R, Stuckler, D, Monteiro, C et al. (2013) Profits and pandemics: prevention of harmful effects of tobacco, alcohol, and ultra-processed food and drink industries. Lancet 381, 670679.Google Scholar
14. Barnes, D & Bero, L (1996) Industry-funded research and conflict of interest: an analysis of research sponsored by the tobacco industry through the Center for Indoor Air Research. J Health Polit Policy Law 21, 515542.CrossRefGoogle ScholarPubMed
15. Sismondo, S (2008) How pharmaceutical industry funding affects trial outcomes: causal structures and responses. Soc Sci Med 66, 19091914.Google Scholar
16. Lundh, A, Sismondo, S, Lexchin, J et al. (2012) Industry sponsorship and research outcome. Cochrane Database Syst Rev 12, MR000033.Google ScholarPubMed
17. Bero, LA (2005) Tobacco industry manipulation of research. Public Health Rep 120, 200208.Google Scholar
18. Kearns, CE, Glantz, SA & Schmidt, LA (2015) Sugar industry influence on the scientific agenda of the National Institute of Dental Research’s 1971 National Caries Program: a historical analysis of internal documents. PLoS Med 12, e1001798.Google Scholar
19. Bes-Rastrollo, M, Schulze, MB, Ruiz-Canela, M et al. (2013) Financial conflicts of interest and reporting bias regarding the association between sugar-sweetened beverages and weight gain: a systematic review of systematic reviews. PLoS Med 10, e1001578.CrossRefGoogle ScholarPubMed
20. Kaiser, KA, Cofield, SS, Fontaine, KR et al. (2012) Is funding source related to study reporting quality in obesity or nutrition randomized control trials in top-tier medical journals? Int J Obes (Lond) 36, 977981.Google Scholar
21. Lesser, LI, Ebbeling, CB, Goozner, M et al. (2007) Relationship between funding source and conclusion among nutrition-related scientific articles. PLoS Med 4, e5.Google Scholar
22. Vartanian, LR, Schwartz, MB & Brownell, KD (2007) Effects of soft drink consumption on nutrition and health: a systematic review and meta-analysis. Am J Public Health 97, 667675.CrossRefGoogle ScholarPubMed
23. Foresight, Government Office for Science (2012) Tackling obesities: future choices – mid-term review (November 2008 to September 2010). https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/288025/12-1210-tackling-obesities-mid-term-review.pdf (accessed July 2016).Google Scholar
24. Scrinis, G (2013) Nutritionism. New York: Columbia University Press.Google Scholar
25. Tapsell, LC, Neale, EP & Satija, A (2016) Foods, nutrients, and dietary patterns: interconnections and implications for dietary guidelines. Adv Nutr 7, 445454.Google Scholar
26. Jacobs, DR & Tapsell, LC (2013) Food synergy: the key to a healthy diet. Proc Nutr Soc 72, 200206.CrossRefGoogle ScholarPubMed
27. Monteiro, C (2011) The big issue is ultra-processing. There is no such thing as a healthy ultra-processed product. World Nutr 2, 333349.Google Scholar
28. Drazen, JM, Van Der Weyden, MB, Sahni, P et al. (2009) Disclosure of competing interests. BMJ 339, b4144.Google Scholar
29. International Committee of Medical Journal Editors (2009) Form for Disclosure of Potential Conflicts of Interests. http://www.icmje.org/conflicts-of-interest (accessed July 2016).Google Scholar
30. Fardet, A & Rock, E (2014) Toward a new philosophy of preventive nutrition: from a reductionist to a holistic paradigm to improve nutritional recommendations. Adv Nutr 5, 430446.Google Scholar
31. Raubenheimer, D, Machovsky-Capuska, GE, Gosby, AK et al. (2015) Nutritional ecology of obesity: from humans to companion animals. Br J Nutr 113, 2639.Google Scholar
32. Cespedes, EM & Hu, FB (2015) Dietary patterns: from nutritional epidemiologic analysis to national guidelines. Am J Clin Nutr 101, 899900.Google Scholar
33. Williams, PG (2014) The benefits of breakfast cereal consumption: a systematic review of the evidence base. Adv Nutr 5, 636673.Google Scholar
34. Levy, RB, Canella, DS, Martins, APB et al. (2013) Processed and ultra-processed food products and obesity in Brazilian households (2008–2009). Ann Nutr Metab 63, 940941.Google Scholar
35. Monteiro, C, Levy, R, Claro, R et al. (2010) A new classification of foods based on the extent and purpose of their processing. Cad Saude Publica 26, 20392049.CrossRefGoogle ScholarPubMed
36. Thornton, M & Schram, M (1981) US holds the ketchup in schools. The Washington Post, 26 September. https://www.washingtonpost.com/archive/politics/1981/09/26/us-holds-the-ketchup-in-schools/9ffd029a-17f5-4e8c-ab91-1348a44773ee/ (accessed November 2016)Google Scholar
37. Peirson, L, Douketis, J, Ciliska, D et al. (2014) Treatment for overweight and obesity in adult populations: a systematic review and meta-analysis. CMAJ Open 2, 306317.Google Scholar
38. Oude Luttikhuis, H, Baur, L, Jansen, H et al. (2009) Interventions for treating obesity in children. Cochrane Database Syst Rev issue 1, CD001872.Google Scholar
39. Schick, SF & Glantz, SA (2007) Old ways, new means: tobacco industry funding of academic and private sector scientists since the Master Settlement Agreement. Tob Control 16, 157164 CrossRefGoogle ScholarPubMed
40. Shawwa, K, Kallas, R, Koujanian, S et al. (2016) Requirements of clinical journals for authors’ disclosure of financial and non-financial conflicts of interest: a cross sectional study. PLoS ONE 11, e0152301.Google Scholar
41. Ruff, K (2015) Scientific journals and conflict of interest disclosure: what progress has been made. Environ Health 14, 45.Google Scholar
42. Baethge, C (2013) The effect of a conflict of interest disclosure form using closed questions on the number of positive conflicts of interest declared – a controlled study. Peer J 1, e128.CrossRefGoogle ScholarPubMed
43. Forsyth, SR, Odierna, DH, Krauth, D et al. (2014) Conflicts of interest and critiques of the use of systematic reviews in policymaking: an analysis of opinion articles. Syst Rev 3, 122.CrossRefGoogle ScholarPubMed
44. McCarthy, M (2016) PubMed is urged to include competing interest information in abstracts. BMJ 353, i2018.Google Scholar
45. Roseman, M, Turner, EH, Lexchin, J et al. (2012) Reporting of conflicts of interest from drug trials in Cochrane reviews: cross sectional study. BMJ 345, e5155.Google Scholar
46. The Cochrane Collaboration (2013) Standards for the reporting of new Cochrane Intervention Reviews, Version 2.3. http://editorial-unit.cochrane.org/mecir (accessed May 2016).Google Scholar
47. Hoffmann, TC, Glasziou, PP, Boutron, I et al. (2014) Better reporting of interventions: template for intervention description and replication (TIDieR) checklist and guide. BMJ 34, g1687.Google Scholar
Figure 0

Fig. 1 Flowchart of study selection (RCT, randomized controlled trial)

Figure 1

Table 1 Location of study site by WHO Region in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2013 (n 213)

Figure 2

Table 2 Categories of funding sources for studies disclosing a sponsor in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2012 (n 175)

Figure 3

Table 3 Nutrition research topics in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2013 (n 213)

Figure 4

Table 4 Research topics by funding source* in the analysed randomized controlled trials included in seventeen systematic reviews of nutrition interventions to address obesity, 1978–2012 (n 151)

Supplementary material: File

Fabbri supplementary material

Fabbri supplementary material

Download Fabbri supplementary material(File)
File 23 KB