Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-22T21:24:11.079Z Has data issue: false hasContentIssue false
  • English
  • Français

Ultra-processed foods and the limits of product reformulation

Published online by Cambridge University Press:  13 July 2017

Gyorgy Scrinis Open the ORCID record for Gyorgy Scrinis [Opens in a new window]  and
Carlos Augusto Monteiro
Gyorgy Scrinis*
Affiliation:
Faculty of Veterinary and Agricultural Sciences, University of Melbourne, Building 142, Parkville, Melbourne, VIC 3010, Australia
Carlos Augusto Monteiro
Affiliation:
Department of Nutrition, School of Public Health, University of São Paulo, São Paulo, Brazil
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The nutritional reformulation of processed food and beverage products has been promoted as an important means of addressing the nutritional imbalances in contemporary dietary patterns. The focus of most reformulation policies is the reduction in quantities of nutrients-to-limit – Na, free sugars, SFA, trans-fatty acids and total energy. The present commentary examines the limitations of what we refer to as ‘nutrients-to-limit reformulation’ policies and practices, particularly when applied to ultra-processed foods and drink products. Beyond these nutrients-to-limit, there are a range of other potentially harmful processed and industrially produced ingredients used in the production of ultra-processed products that are not usually removed during reformulation. The sources of nutrients-to-limit in these products may be replaced with other highly processed ingredients and additives, rather than with whole or minimally processed foods. Reformulation policies may also legitimise current levels of consumption of ultra-processed products in high-income countries and increased levels of consumption in emerging markets in the global South.

Keywords

Food processingUltra-processed foodsProduct reformulationNutrition policy
Type
Commentary
Information
Public Health Nutrition , Volume 21 , Special Issue 1: Ultra Processed Foods , January 2018 , pp. 247 - 252
Check for updates
Copyright
Copyright © The Authors 2017 

Product reformulation commonly refers to policies and practices aimed at reducing the quantities of a set of ‘negative nutrients’ – or so-called ‘nutrients-to-limit’ – in packaged or fast-food products: Na, free sugars, SFA, trans-fatty acids and total energy.

Reformulation has been promoted by many nutrition experts, governments, international agencies and food corporations as an important means of addressing the nutritional imbalances in contemporary dietary patterns( 1 4 ). In many countries, there are now a range of industry- and government-led initiatives to systematically reformulate packaged and fast foods, as well as to inform new product development( Reference Marotta, Simeone and Nazzaro 2 , Reference Unnevehr and Jagmanaite 5 ). While still in its early phases, this systematic and often ‘quiet’ (i.e. without labelling) reformulation across entire product categories and company portfolios can be contrasted with the more selective reformulation of products that food companies have introduced since the 1970s, such as prominently marketed ‘low-fat’ and ‘low-calorie’ foods and beverages that function as optional choices for consumers( Reference Nestle 6 ).

Some governments are beginning to develop their own mandatory standards and limits for some nutrients, such as trans-fatty acids and Na( Reference Webster, Trieu and Dunford 7 ). However, most government policies to date have taken the form of voluntary and indirect measures to encourage food corporations to reformulate their products through the use of labelling, taxes, advertising restrictions and voluntary public–private partnerships( Reference Lloyd-Williams, Bromley and Orton 8 ). Most transnational food manufacturing and service corporations have also developed their own company-specific policies and set their own nutrient standards that they are progressively applying to their product portfolios( Reference Sacks, Mialon and Vandevijvere 9 , Reference Vlassopoulos, Masset and Charles 10 ).

The success or otherwise of these public and private reformulation policies is usually evaluated in terms of reductions in the quantities of these nutrients-to-limit within particular food products. Common criticisms of these policies from public health experts relate to the voluntary and inadequate targets and timelines for reformulation that have been set, the slow and uneven progress, and the lack of accountability of food corporations( Reference Panjwani and Caraher 11 Reference Knai, Petticrew and Durand 13 ). Some of these criticisms are based on the assumption that nutrients-to-limit reformulation is a worthwhile and important goal, but that there are limitations in its implementation( 3 , Reference van Raaij, van Raaij and Hendriksen 12 , Reference Lacey, Clark and Frewer 14 , Reference Mohamedshah and Ruff 15 ). Common proposals are for higher and mandatory independent standards to be adopted by industry or to be legislated by governments( Reference Reeve and Magnusson 16 ).

Beyond some of these commonly identified inadequacies of existing industry and government reformulation policies and practices, the present commentary examines some of the inherent limitations – and potential risks – of nutrients-to-limit reformulation policies, particularly when applied to the reformulation of ultra-processed products. These products are the main driver of the excessive intake of nutrients-to-limit in many people’s diets around the world( Reference Monteiro, Cannon and Moubarac 17 ). First, we define ultra-processed products and consider the function and potential health impacts of the range of processed ingredients used in their production. Second, we consider the limitations of focusing only on a narrow range of nutrients-to-limit and the potential for the ‘mal-substitution’ of ingredients to achieve this reformulation. Third, we argue that reformulation policies may be used to provide scientific and political legitimacy for the continued and growing consumption of ultra-processed foods. Finally, we explore alternatives approaches to reformulation, including those involving the reduction in consumption of ultra-processed foods and the more substantial and comprehensive reformulation of these products.

For this analysis, we introduce a classification of types of reformulation practices. As the primary aim of these reformulation policies is to limit the set of negative nutrients or nutrients-to-limit, we refer to this form of reformulation as nutrients-to-limit reformulation. We could equally refer to this form of reformulation as negative-nutrient reformulation, or as harm-reduction reformulation, since the aim is largely to reduce the harmfulness of food products containing these negative nutrients, rather than to make them more nutritious or healthful. Nutrients-to-limit reformulation can be contrasted with two forms of more positive reformulation that are mentioned below. The first is positive-nutrient reformulation, which involves the addition of ‘positive’ nutrients – or so-called ‘nutrients-to-encourage’ – that are considered by many nutrition experts to be beneficial. The second is wholefood reformulation, which is focused on foods and ingredients rather than nutrients, and that involves the replacement of highly processed with minimally and unprocessed foods and ingredients.

The nutritional qualities and characteristics of ultra-processed foods

The focus on Na, free sugars, SFA, trans-fatty acids and energy within product reformulation initiatives is commonly justified on the basis that these are key nutrients of concern identified within national dietary guidelines and supported by broad scientific consensus( Reference Kanzler, Hartmann and Gruber 18 ). There is a reasonable body of scientific evidence and expert consensus linking diets with excessive content of Na, free sugars (particularly in the form of sugar-sweetened beverages) or with trans-fatty acids and excess energy intake to particular detrimental health outcomes( Reference Santos, Trieu and Raj 19 Reference Popkin and Hawkes 22 ). The focus on SFA is, arguably, somewhat more problematic because the scientific evidence supporting reduced intake of SFA per se is increasingly being challenged by some nutrition experts( Reference Mozaffarian 23 Reference Raziani, Tholstrup and Kristensen 25 ).

The target of most reformulation policies is ultra-processed products. However, it is important to acknowledge the exclusive nutrient focus of these reformulation policies and scientific discourses( Reference Scrinis 26 ). Free sugars, Na, SFA and trans-fatty acids are added to many packaged and fast-food products mostly as parts of ingredients, such as sugarcane, sugarbeet, high-fructose corn syrup, fruit concentrates, table salt and other types of salt, and refined or hydrogenated plant oils. These ingredients are themselves the products of particular food processing techniques, including the processes of extraction, concentration, enzyme treatment, chemical synthesis, refinement and hydrogenation. Yet the sources of the nutrients-to-limit in packaged and fast-food products and the level of processing used in their production are typically not considered within these product reformulation policies.

The focus on nutrients-to-limit within reformulation policies is an extension of the way nutrients and nutrient profiling remain the primary lens of analysis within nutrition science. This nutri-centric approach has been a feature of the dominant paradigm of ‘nutritionism’ within nutrition science – a paradigm characterised by a reductive focus on, and reductive interpretation of, nutrients( Reference Scrinis 27 ). Yet this nutrient focus has tended to obscure and hinder research into the health impacts of food processing and processed food products. It is only in recent years that there have been attempts to bring food processing to the centre of the understanding of food quality and as the basis for conducting nutrition science research( Reference Moubarac, Parra and Cannon 28 , Reference Fardet, Rock and Bassama 29 ). This involves consideration of the levels and types of processing that foods and their constituent ingredients have been subjected to( Reference Scrinis 27 , Reference Moubarac, Parra and Cannon 28 , Reference Poti, Mendez and Ng 30 , Reference Monteiro, Moubarac and Cannon 31 ).

The NOVA system for classifying levels of processing developed by Monteiro and colleagues has become increasingly studied and adopted in public health nutrition research and policy analysis( Reference Monteiro, Cannon and Moubarac 17 ). The NOVA classification distinguishes four groups of foods according to the nature, extent and purpose of the industrial processing they undergo: minimally processed foods, processed culinary ingredients, processed foods and ultra-processed foods ( Reference Monteiro, Cannon and Levy 32 ). The most highly processed products in the NOVA system are ultra-processed foods( Reference Monteiro, Cannon and Moubarac 17 ). NOVA defines ultra-processed foods as industrial food and drink formulations mostly or entirely made from processed culinary ingredients, such as sugar, oils and salt, and other substances derived from foods but not normally used in kitchens, such as protein isolates, modified starches and hydrogenated fats. Also common in ultra-processed foods are additives used to imitate the sensory qualities of natural foods or to disguise undesirable qualities of the final product, such as colorants, flavourings, artificial sweeteners and emulsifiers. The nature of the ingredients, the various processing techniques and the sequences of stages used by the industry to manufacture ultra-processed foods (hence ‘ultra-processed’) are designed to create durable, accessible, convenient, hyper-palatable, highly profitable ready-to-eat, ready-to-drink or ready-to-heat products liable to displace all other NOVA food groups and the dishes and meals made with them( Reference Monteiro, Cannon and Moubarac 17 ). Longitudinal and cross-sectional studies in several countries have found a positive association between ultra-processed food consumption and obesity, hypertension, metabolic syndrome and dyslipidaemia( Reference Canella, Levy and Martins 33 Reference Rauber, Campagnolo and Hoffman 39 ). These types of highly processed foods have also been referred to by Scrinis as ‘processed-reconstituted foods’, which are similarly defined as products that contain little whole or minimally processed ingredients, and instead are largely constructed – from the ground up – out of refined, extracted, concentrated, deconstituted and chemically transformed components of whole foods( Reference Scrinis 27 ).

The concept of ultra-processed foods does not just focus attention on the high levels of sugar, fat and salt in packaged and fast foods, but also on the lack of intact foods and the range of processed ingredients and food processing techniques used in their production. Some forms of processing strip wholefoods of some of their nutritious components( Reference Louzada, Martins and Canella 40 ). In some cases, there is evidence of potentially detrimental health effects related to these ingredients, beyond that of salt, sugar, saturated and trans fats. For example, there is evidence linking highly refined flours and starches to increased glycaemic load and detrimental impacts on blood cholesterol levels( Reference Mozaffarian 23 , Reference Fardet 41 ); and experimental evidence indicates that dietary emulsifiers, a common additive of ultra-processed foods, may impact the gut microbiota promoting colitis and metabolic syndrome( Reference Chassaing, Koren and Goodrich 42 ). Aside from any intrinsic harmful effects, these ingredients may also play a role in creating products that are hyper-palatable, rapidly consumable, cheap, durable and possibly addictive( Reference Kessler 43 , Reference Moss 44 ). For example, salt, sugars and other processed sweeteners and flavourings are used in large quantities by packaged and fast-food producers to give flavour to foods that have had their intrinsic flavours processed out of them and to mask any unpleasant flavours in the final product.

Reformulation and the mal-substitution of ingredients

In considering the effectiveness of nutrients-to-limit reformulation policies, it is important to identify and to distinguish between the types of foods that are the target of these initiatives. In the case of the NOVA category of processed foods – whose ingredients are restricted to minimally processed foods, salt, sugar, and non-modified oils and fats extracted from minimally processed foods – reducing the quantity of the nutrients-to-limit could substantially improve their nutritional quality. However, in the case of ultra-processed foods that are primarily constructed out of sources of nutrients-to-limit and other highly processed ingredients, the substantial reduction of nutrients-to-limit poses great technological and economic challenges for manufacturers and will not necessarily result in the production of nutritious products.

While the focus of reformulation strategies has been on reducing nutrients-to-limit, there has been relatively little attention given to the quality of the ingredients being substituted during reformulation. Nutrition and public health experts have certainly emphasised the need to avoid replacing one nutrient-to-limit with another nutrient-to-limit as when fats are replaced with sugar or sources of trans-fatty acids are replaced by sources of saturated fats( Reference Mozaffarian, Jacobson and Greenstein 45 ). There have been a number of studies that document the reductions of nutrients-to-limit achieved through reformulation programmes and also the overall nutrient profile of the reformulated products( Reference Vlassopoulos, Masset and Charles 10 , Reference Savio, Mehta and Udell 46 Reference Pombo-Rodrigues, Hashem and He 48 ). Yet there have not been systematic examinations of the changes in ingredients before and after nutrients-to-limit reformulation.

Manufacturers of ultra-processed products can be expected to replace the sources of nutrients-to-limit with ingredients that replicate their taste, texture, bulk and processing functionality, and without significantly adding to costs( Reference Buttriss 49 ). This often means substituting with other refined and reconstituted processed ingredients. These substitute ingredients may themselves be of minimal nutritional value and may even be harmful in large quantities. These substituted ingredients are also intended to perform a similar role to salt/sugar/fat in maintaining the hyper-palatability and cheap cost of food products, and to thereby maintain the high levels of consumption of the reformulated products. The overall health benefits resulting from this mal-substitution of ingredients – as we refer to it – are therefore questionable.

There are two well-documented historical examples of this mal-substitution of ingredients. The first is the increase in the intake of trans-fatty acids when partially hydrogenated vegetable oils were promoted as a substitute ingredient for saturated fats derived from animal fats, such as in the promotion of margarine over butter beginning in the 1960s( Reference Scrinis 27 ). The second is the replacement of fat with sugar in the manufacture of low-fat processed foods during the 1980s and 1990s when the low-fat dietary advice was dominant in the USA and other countries( Reference Lawrence 50 , Reference La Berge 51 ). Other questionable substitutions currently being practised include: the substitution of sugar and reduction of energy using highly processed non-caloric sweeteners, most recently stevia-derived sweeteners; the reduction of fats and energy through the use of refined and chemically modified starches; and the replacement of trans-fat-rich, partially hydrogenated vegetable oils with vegetable oils that have been fully hydrogenated, fractionated and interesterified( Reference Scrinis 27 , Reference Upritchard, Zeelenberg and Huizinga 52 , Reference Borges, Louzada and de Sá 53 ).

The legitimation of ultra-processed foods and dietary patterns

Another concern with current reformulation policies is that they may serve to legitimate, endorse and even promote – rather than significantly challenge – the consumption of ultra-processed foods( Reference Monteiro and Cannon 54 ). One of the policy rationales for nutrients-to-limit reformulation is that it is a means of reducing the consumption of these nutrients without consumers having to change their food choices or dietary patterns. For example, in an article promoting reformulation in a food science and technology journal, reformulation is referred to as ‘the unobtrusive strategy’: ‘It creates the prospect of nutritional improvement without dietary change’( Reference Winkler 55 ).

Reformulation policies effectively provide positive endorsement for the consumption of (reformulated) ultra-processed products, as long as these reformulated products have met the required single-nutrient goals. If nutrients-to-limit reformulation is promoted as a primary goal of nutrition policy, then it potentially undermines policies that aim to more substantially improve the quality of the food supply and that promote the increased consumption of minimally processed foods. Reformulated products that have met the minimum standards for salt or fat or sugar may even be promoted as positively health-enhancing if they have also been fortified with supposedly beneficial or ‘positive’ nutrients and food components, such as vitamins, fibre or n-3 fatty acids – that is, if nutrients-to-limit reformulation is accompanied by positive-nutrient reformulation( Reference Monteiro and Cannon 54 ).

In examining the implications of these reformulation policies, it is important to distinguish between countries and classes of people whose diets may already be high in ultra-processed foods, on the one hand, and those still in the transition towards highly processed diets, on the other. In the largely saturated processed food markets in the global North, if these reformulation policies are systematically applied then we could expect to see modest population-wide reductions in some of these nutrients-to-limit. In the UK, for example, where voluntary salt reduction strategies have been in place since 2003, studies suggest that these policies have coincided with a modest reduction of salt intake( Reference Millett, Laverty and Stylianou 56 ). However, it is a different story in emerging markets in the global South, where the distribution and consumption of ultra-processed foods continue to grow rapidly, resulting in the displacement of traditional, freshly prepared and minimally processed meals( Reference Baker and Friel 57 Reference Stuckler, McKee and Ebrahim 59 ). In many low- and middle-income countries currently recording double-digit annual growth in packaged food consumption, any reductions in nutrients-to-limit within individual products are likely to be cancelled out by an overall increase in the consumption of ultra-processed food and drink products.

Reformulation policies can not only create political legitimation for ultra-processed products, but also for the food manufacturing and service corporations that produce them. By actively promoting their own reformulation policies, or complying with government standards for reformulation, food corporations will be able to demonstrate their corporate responsibility commitments and present themselves as part of the solution to obesity and diet-related non-communicable diseases( Reference Scrinis 26 , Reference Scott, Hawkins and Knai 60 ). Food corporations may thereby maintain their access to emerging markets in the South and their social licence to operate and expand within them. Their compliance with any government-endorsed nutritional standards may also protect corporations from the threat of future litigation. Beyond the defensive strategy of reformulating their products to reduce nutrients-to-limit, food corporations are also fortifying and ‘functionalizing’ these same products, and marketing them as addressing micronutrient deficiencies and providing targeted health benefits( Reference Scrinis 26 ).

Beyond nutrients-to-limit reformulation

An alternative to the substitution of nutrients-to-limit with other processed-refined-reconstituted ingredients is to replace the source of these nutrients with intact or minimally processed ingredients, a practice we refer to as wholefoods reformulation. Such more comprehensive reformulation is already being selectively carried out by some food companies, and is evident in the increased availability of premium packaged foods and fast-food/restaurant meals. These may take the form of new product innovations, rather than the reformulation of old products. It is also evident in the trend towards ‘clean labelling’, whereby manufacturers seek to avoid adding some artificial flavours or preservatives to their products, as well as adding some whole grains to their products( Reference Katz and Wlliams 61 ). These trends towards minimally processed ingredients point to the maturing of the packaged and fast-food industries in some markets and the growing consumer demand for better-quality foods. However, convenience premium products often cost more and therefore may not be as affordable to those on low incomes who already consume the poorest-quality diets( Reference Poti, Mendez and Ng 62 ).

The aim of the present commentary has not been to deny the importance of reducing levels of some of the nutrients-to-limit in the food supply, but to identify some of the limitations of a narrow focus on nutrients-to-limit. Even within the terms of nutrients-to-limit reformulation, setting higher nutrient standards can serve to weed out many ultra-processed products. This is the case with the new Chilean food labelling and advertising standards, which have resulted in many ultra-processed products receiving black symbols (up to four) that warn consumers of the high content in sugar, salt, saturated fat and energy( Reference Corvalán, Reyes and Garmendia 63 , Reference Aguirre Pascal 64 ). Importantly, any products carrying at least one black symbol cannot be advertised to children nor sold in schools in Chile.

If there is a genuine concern with reducing the consumption of nutrients-to-limit, then strategies that aim to restrict and reduce the production and consumption of ultra-processed products ultimately need to be considered. There are consumption trends and political movements heading in this direction, and that are in some cases supported by government policies. For example, the national dietary guidelines in Brazil and Uruguay now explicitly refer to the category of ultra-processed foods and advise the population not to replace minimally processed foods and their culinary preparations with ultra-processed food and drink products( Reference Monteiro, Cannon and Moubarac 65 , 66 ). Policies restricting or banning the sale of ultra-processed products – such as sugar-sweetened beverages and confectionery – in schools and other institutional or commercial settings have been implemented in several countries, and are a more direct way of reducing their consumption( Reference Hawkes, Jewell and Allen 67 ).

As governments begin to demonstrate a greater determination and resolve to address the problem of poor-quality foods and diets, there may be more scope and political will to push beyond the narrow focus of nutrients-to-limit reformulation.

Acknowledgements

Financial support: This work was supported by the Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP; grant number 2015/14900-9). FAPESP had no role in the design, analysis or writing of this article. Conflict of interest: The authors declare that there are no conflicts of interest. Authorship: Both authors participated in the conception and drafting of the commentary. Ethics of human subject participation: Not applicable.

References

1. World Health Organization (2004) Global Strategy on Diet, Physical Activity and Health. Geneva: WHO.Google Scholar
2. Marotta, G, Simeone, M & Nazzaro, C (2014) Product reformulation in the food system to improve food safety. Evaluation of policy interventions. Appetite 74, 107115.Google Scholar
3. International Food and Beverage Alliance (2016) Commitment on Product Formulation and Innovation. Trelex: IFBA.Google Scholar
4. World Health Organization (2014) Policy Brief: Producing and Promoting More Food Products Consistent with a Health Diet. Geneva: WHO.Google Scholar
5. Unnevehr, L & Jagmanaite, E (2008) Getting rid of trans fats in the US diet: policies, incentives and progress. Food Policy 33, 497503.Google Scholar
6. Nestle, M (2013) Food Politics: How the Food Industry Influences Nutrition and Health, 10th ed. Berkeley, CA: University of California Press.Google Scholar
7. Webster, J, Trieu, K, Dunford, E et al. (2014) Target salt 2025: a global overview of national programs to encourage the food industry to reduce salt in foods. Nutrients 6, 32743287.Google Scholar
8. Lloyd-Williams, F, Bromley, H, Orton, L et al. (2014) Smorgasbord or symphony? Assessing public health nutrition policies across 30 European countries using a novel framework. BMC Public Health 14, 1195.CrossRefGoogle ScholarPubMed
9. Sacks, G, Mialon, M, Vandevijvere, S et al. (2015) Comparison of food industry policies and commitments on marketing to children and product (re)formulation in Australia, New Zealand and Fiji. Crit Public Health 25, 299319.CrossRefGoogle Scholar
10. Vlassopoulos, A, Masset, G, Charles, VR et al. (2016) A nutrient profiling system for the (re)formulation of a global food and beverage portfolio. Eur J Nutr 56, 11051122.CrossRefGoogle ScholarPubMed
11. Panjwani, C & Caraher, M (2014) The Public Health Responsibility Deal: brokering a deal for public health, but on whose terms? Health Policy 114, 163173.Google Scholar
12. van Raaij, J, van Raaij, M, Hendriksen, H et al. (2009) Potential for improvement of population diet through reformulation of commonly eaten foods. Public Health Nutr 12, 325330.Google ScholarPubMed
13. Knai, C, Petticrew, M, Durand, M et al. (2015) Has a public–private partnership resulted in action on healthier diets in England? An analysis of the Public Health Responsibility Deal food pledges. Food Policy 54, 110.Google Scholar
14. Lacey, C, Clark, B, Frewer, L et al. (2016) ‘Reaching its limits’: industry perspectives on salt reduction. Br Food J 118, 16101624.CrossRefGoogle Scholar
15. Mohamedshah, FY & Ruff, J (2014) Dietary guidance and the role of food science: developing healthy foods to help Americans achieve the Dietary Recommendations. Nutr Today 49, 284290.Google Scholar
16. Reeve, B & Magnusson, R (2015) Food reformulation and the (neo)-liberal state: new strategies for strengthening voluntary salt reduction programs in the UK and USA. Public Health 129, 10611073.CrossRefGoogle ScholarPubMed
17. Monteiro, CA, Cannon, G, Moubarac, J-C et al. (2017) The UN Decade of Nutrition, the NOVA food classification and the trouble with ultra-processing. Public Health Nutr (Epublication ahead of print version).Google Scholar
18. Kanzler, S, Hartmann, C, Gruber, A et al. (2014) Salt as a public health challenge in continental European convenience and ready meals. Public Health Nutr 17, 24592466.Google Scholar
19. Santos, J, Trieu, K, Raj, T et al. (2017) The science of salt: a regularly updated systematic review of the implementation of salt reduction interventions (March–August 2016). J Clin Hypertens 19, 439451.Google Scholar
20. Willett, W (2014) The case for banning trans fats. The FDA’s new policy on these deadly artificial fatty acids is long overdue. Sci Am 310, 13.Google Scholar
21. Imamura, F, O’Connor, L, Ye, Z et al. (2015) Consumption of sugar sweetened beverages, artificially sweetened beverages, and fruit juice and incidence of type 2 diabetes: systematic review, meta-analysis, and estimation of population attributable fraction. BMJ 351, h3576.Google Scholar
22. Popkin, B & Hawkes, C (2016) Sweetening of the global diet, particularly beverages: patterns, trends, and policy responses. Lancet Diabetes Endocrinol 4, 174186.Google Scholar
23. Mozaffarian, D (2016) Dietary and policy priorities for cardiovascular disease, diabetes, and obesity: a comprehensive review. Circulation 133, 187225.Google Scholar
24. Siri-Tarino, PW & Krauss, RM (2016) Which cheese to choose? Am J Clin Nutr 104, 953954.Google Scholar
25. Raziani, F, Tholstrup, T, Kristensen, MD et al. (2016) High intake of regular-fat cheese compared with reduced-fat cheese does not affect LDL cholesterol or risk markers of the metabolic syndrome: a randomized controlled trial. Am J Clin Nutr 104, 973981.CrossRefGoogle ScholarPubMed
26. Scrinis, G (2016) Reformulation, fortification and functionalization: Big Food corporations’ nutritional engineering and marketing strategies. J Peasant Stud 43, 1737.CrossRefGoogle Scholar
27. Scrinis, G (2013) Nutritionism: The Science and Politics of Dietary Advice. New York: Columbia University Press.Google Scholar
28. Moubarac, J-C, Parra, DC, Cannon, G et al. (2014) Food classification systems based on food processing: significance and implications for policies and actions: a systematic literature review and assessment. Curr Obes Rep 3, 256272.Google Scholar
29. Fardet, A, Rock, E, Bassama, J et al. (2015) Current food classifications in epidemiological studies do not enable solid nutritional recommendations for preventing diet-related chronic diseases: the impact of food processing. Adv Nutr 6, 629638.Google Scholar
30. Poti, JM, Mendez, MA, Ng, SW et al. (2015) Is the degree of food processing and convenience linked with the nutritional quality of foods purchased by US households? Am J Clin Nutr 101, 12511262.Google Scholar
31. Monteiro, CA, Moubarac, JC, Cannon, G et al. (2013) Ultra‐processed products are becoming dominant in the global food system. Obes Rev 14, 2128.Google Scholar
32. Monteiro, CA, Cannon, G, Levy, RB et al. (2016) NOVA. The star shines bright. World Nutr 7, 2838.Google Scholar
33. Canella, DS, Levy, RB, Martins, APB et al. (2014) Ultra-processed food products and obesity in Brazilian households (2008–2009). PLoS One 9, e92752.Google Scholar
34. da Costa Louzada, ML, Baraldi, LG, Steele, EM et al. (2015) Consumption of ultra-processed foods and obesity in Brazilian adolescents and adults. Prev Med 81, 915.Google Scholar
35. Juul, F & Hemmingsson, E (2015) Trends in consumption of ultra-processed foods and obesity in Sweden between 1960 and 2010. Public Health Nutr 18, 30963107.Google Scholar
36. de Deus Mendonça, R, Pimenta, AM, Gea, A et al. (2016) Ultraprocessed food consumption and risk of overweight and obesity: the University of Navarra Follow-Up (SUN) cohort study. Am J Clin Nutr 104, 14331440.Google Scholar
37. de Deus Mendonça, R, Lopes, ACS, Pimenta, AM et al. (2016) Ultra-processed food consumption and the incidence of hypertension in a Mediterranean cohort: the Seguimiento Universidad de Navarra Project. Am J Hypertens 30, 358366.Google Scholar
38. Tavares, LF, Fonseca, SC, Rosa, MLG et al. (2012) Relationship between ultra-processed foods and metabolic syndrome in adolescents from a Brazilian Family Doctor Program. Public Health Nutr 15, 8287.Google Scholar
39. Rauber, F, Campagnolo, P, Hoffman, D et al. (2015) Consumption of ultra-processed food products and its effects on children’s lipid profiles: a longitudinal study. Nutr Metab Cardiovasc Dis 25, 116122.Google Scholar
40. Louzada, MLdC, Martins, APB, Canella, DS et al. (2015) Impact of ultra-processed foods on micronutrient content in the Brazilian diet. Rev Saude Publica 49, 45.Google Scholar
41. Fardet, A (2015) A shift toward a new holistic paradigm will help to preserve and better process grain products’ food structure for improving their health effects. Food Funct 6, 363382.Google Scholar
42. Chassaing, B, Koren, O, Goodrich, JK et al. (2015) Dietary emulsifiers impact the mouse gut microbiota promoting colitis and metabolic syndrome. Nature 519, 9296.Google Scholar
43. Kessler, D (2009) The End of Overeating: Taking Control of the Insatiable American Appetite. New York: Rodale.Google Scholar
44. Moss, M (2012) Salt, Sugar, Fat: How the Food Giants Hooked Us. New York: Random House.Google Scholar
45. Mozaffarian, D, Jacobson, MF & Greenstein, JS (2010) Food reformulations to reduce trans fatty acids. N Engl J Med 362, 20372039.Google Scholar
46. Savio, S, Mehta, K, Udell, T et al. (2013) A survey of the reformulation of Australian child-oriented food products. BMC Public Health 13, 836.Google Scholar
47. Mathias, KC, Ng, SW & Popkin, B (2015) Monitoring changes in the nutritional content of ready-to-eat grain-based dessert products manufactured and purchased between 2005 and 2012. J Acad Nutr Diet 115, 360368.Google Scholar
48. Pombo-Rodrigues, S, Hashem, KM, He, FJ et al. (2017) Salt and sugars content of breakfast cereals in the UK from 1992 to 2015. Public Health Nutr 20, 15001512.Google Scholar
49. Buttriss, JL (2013) Food reformulation: the challenges to the food industry. Proc Nutr Soc 72, 6169.Google Scholar
50. Lawrence, F (2004) Not on the Label: What Really Goes into the Food on Your Plate. London: Penguin.Google Scholar
51. La Berge, AF (2008) How the ideology of low fat conquered America. J Hist Med Allied Sci 63, 139177.Google Scholar
52. Upritchard, J, Zeelenberg, MJ, Huizinga, H et al. (2005) Modern fat technology: what is the potential for heart health? Proc Nutr Soc 64, 379386.Google Scholar
53. Borges, MC, Louzada, ML, de Sá, TH et al. (2017) Artificially sweetened beverages and the response to the global obesity crisis. PLoS Med 14, e1002195.Google Scholar
54. Monteiro, CA & Cannon, G (2012) The food system: product reformulation will not improve public health. World Nutr 3, 406434.Google Scholar
55. Winkler, JT (2014) Nutritional reformulation: the unobtrusive strategy. Food Sci Technol J 28, 3740.Google Scholar
56. Millett, C, Laverty, AA, Stylianou, N et al. (2012) Impacts of a national strategy to reduce population salt intake in England: serial cross sectional study. PLoS One 7, e29836.Google Scholar
57. Baker, P & Friel, S (2014) Processed foods and the nutrition transition: evidence from Asia. Obes Rev 15, 564577.Google Scholar
58. Imamura, F, Micha, R, Khatibzadeh, S et al. (2015) Dietary quality among men and women in 187 countries in 1990 and 2010: a systematic assessment. Lancet Glob Health 3, e132e142.Google Scholar
59. Stuckler, D, McKee, M, Ebrahim, S et al. (2012) Manufacturing epidemics: the role of global producers in increased consumption of unhealthy commodities including processed foods, alcohol and tobacco. PLoS Med 9, e1001235.Google Scholar
60. Scott, C, Hawkins, B & Knai, C (2017) Food and beverage product reformulation as a corporate political strategy. Soc Sci Med 172, 3745.Google Scholar
61. Katz, B & Wlliams, LA (2011) Cleaning up processed foods. Food Technol 65, 33.Google Scholar
62. Poti, JM, Mendez, MA, Ng, SW et al. (2016) Highly processed and ready-to-eat packaged food and beverage purchases differ by race/ethnicity among US households. J Nutr 146, 17221730.Google Scholar
63. Corvalán, C, Reyes, M, Garmendia, ML et al. (2013) Structural responses to the obesity and non‐communicable diseases epidemic: the Chilean Law of Food Labeling and Advertising. Obes Rev 14, 7987.Google Scholar
64. Aguirre Pascal, B (2016) Etiquetado: grandes empresas tendrán 50% de sus productos con advertencia, y han reformulado 1.550 alimentos. El Mercurio, 22 May. http://www.economiaynegocios.cl/noticias/noticias.asp?id=254368 (accessed June 2017).Google Scholar
65. Monteiro, CA, Cannon, G, Moubarac, J-C et al. (2015) Dietary guidelines to nourish humanity and the planet in the twenty-first century. A blueprint from Brazil. Public Health Nutr 18, 23112322.Google Scholar
66. Food and Agriculture Organization of the United Nations (2016) Food-based dietary guidelines – Uruguay. http://www.fao.org/nutrition/education/food-based-dietary-guidelines/regions/countries/uruguay/en/ (accessed March 2017).Google Scholar
67. Hawkes, C, Jewell, J & Allen, K (2013) A food policy package for healthy diets and the prevention of obesity and diet‐related non‐communicable diseases: the NOURISHING framework. Obes Rev 14, 159168.Google Scholar