What are (ultra)processed foods?

There is widespread agreement that we need to change the way we produce the foods we consume, with rising levels of diet-related chronic disease matched by global concerns on the environmental impact of food production and distribution. Food-based dietary recommendations are supported by scientific evidence that underpins population guidance on healthy eating, with the goal of minimising diet-related chronic disease and enhancing nutritional well-being across the lifespan. These guidelines are informed by the highest quality scientific research from longitudinal observation studies and randomised controlled trials (RCT) within target and general populations. In recent years, dietary recommendation has moved away from nutrient-specific guidance (e.g. increase calcium and vitamin D for bone health), to emphasise the contribution of whole foods (i.e. milk) and food groups (i.e. dairy) in promoting nutrient adequacy. In 2009, a group in Brazil proposed the ‘NOVA’ approach to classify foods, not by their nutrient content, but by the degree to which they have been processed^{(Reference Monteiro, Cannon and Lawrence1)}. This approach proposes that it is not the nutrients in a food that predict its health properties, but the degree of processing that is most important for health. The NOVA approach advises the complete avoidance of highly processed foods to maximise health^{(Reference Lawrence2)}, and although quite subjective, the approach has a simplicity that is appealing when compared to more complex systems to code processed food or detailed dietary guidance based on nutrients or food groups.

There are currently at least six different systems that are used to classify foods by their degree of processing including the European Prospective Investigation into Cancer^{(Reference Slimani, Deharveng and Southgate3)}, the International Food Information Council^{(Reference Eicher-Miller, Fulgoni and Keast4)}, the Siga classification^{(Reference Davidou, Christodoulou and Fardet5)}, the University of North Carolina^{(Reference Bleiweiss-Sande, Chui and Evans6)}, NOVA and more recently the Food Compass system^{(Reference Mozaffarian, El-Abbadi and O'Hearn7)}. The NOVA system has evolved considerably since its initial introduction, initially focusing on number of ingredients and processes and more recently evolving to include the ‘purpose of processing’ as a central component of the definition^{(Reference Gibney8)}. There is little cohesion between these different systems of processing classification, and this becomes apparent when the same dietary data set is compared using different processing classification approaches, resulting in wide variation in the reported associations between processed food consumption and health. When data from the PREDIMED trial were classified using four of these different processing classifications (NOVA, the European Prospective Investigation into Cancer, the International Food Information Council, the University of North Carolina), the resulting associations with health varied considerably across systems, with most significant associations either attenuated or lost completely^{(Reference Martinez-Perez, San-Cristobal and Guallar-Castillon9)}. The NOVA scheme is the simplest and by far the most widely used approach to classify foods and diets by their degree of processing, but it's worth noting that there is a lack of consensus on its formulation and its application in dietary epidemiology^{(Reference Gibney, Forde and Mullally10–Reference Monteiro and Astrup12)}. The aim of the current review is to provide a critique of available evidence and mechanisms and to highlight some important considerations for future research priorities on the topic of food processing and health.

The purpose of food processing and the objectivity of a definition

The NOVA system classifies foods based on (i) the extent and (ii) purpose of their processing into four categories from minimally processed (1), processed culinary ingredients (fats/oils, salt) (2), processed foods (3) and ultra-processed foods (UPF) (4)^{(Reference Monteiro, Cannon and Levy13)}. Minimally processed foods are the original whole food with no additives which undergo only mild or minimal processing and include fresh meats, fruits, vegetables and dairy. Processed culinary ingredients include salt, sugar and refined oils and other ingredients that are derived from the original whole food. When processed culinary ingredients are added to minimally processed foods, they join the processed food category, which also includes salting, canning, fermenting, freezing and prepared food that has undergone several processing steps. The UPF category is distinct from other processed foods and describes foods as ‘industrial formulations that are made entirely from food derivatives, chemical substances and sequence of processes, that bears little resemblance to the original food material’^{(Reference Monteiro, Cannon and Levy13)}. In addition to degree of processing and formulation described earlier, the definition extends further to include the motivation behind specific formulations, such as ‘the use of additives whose function is to make the final product palatable and more appealing’^{(Reference Monteiro, Cannon and Lawrence1)}. The NOVA system overlaps with many existing nutrient indices^{(Reference Drewnowski, Gupta and Darmon14)}, but is unique among classification approaches in that NOVA 4 (ultra-processed) category is the least discriminating, offering the broadest grouping of packaged foods available for consumption in the modern food environment. As such, when correlations are made with health markers or diet-related chronic disease, this category of foods is more likely to yield significant associations between processed food consumption and negative health outcomes. The popularity of the NOVA system has grown slowly since its inception, originally only used by small groups of researchers in specific regions^{(Reference Ivens15)}, but has since grown to become the most popular and widely used classification in the published literature and is increasingly referred to in FAO and WHO recommendations^{(Reference Monteiro, Cannon and Lawrence1)}.

This concept that the ‘purpose of food processing’ should be included as part of an objective definition of processed food is a unique element of the NOVA classification scheme, when compared to the other approaches. Here the NOVA definition goes beyond a product's composition or even degree of processing to include the motivation or reason behind the processing or formulation. These reasons have been listed in the definition as processing materials ‘to drive profitability, affordability, (hyper)palatability, convenience and ubiquity, where processed products are available everywhere, are affordable, and are widely marketed’^{(Reference Scrinis and Monteiro16)}. The ultra-processed definition highlights further links with purpose, where ingredients that are added to ‘mimic the sensorial quality of unprocessed or minimally processed foods and their culinary preparations or to disguise undesirable qualities of the final product’^{(Reference Scrinis and Monteiro16)}. Here the emphasis is not on the specific chemical or nutrient properties of the ingredient per se, but rather the intention behind its addition, suggesting the motivation for why a food is formulated this way is part of what qualifies it as (ultra)processed, and thus linked to a negative health impact. This is a clear departure from traditional nutrient-based dietary guidelines where the NOVA scheme describes ‘purpose’ of processing and formulation as part of the problem, and where product elements such as profitability, convenience, palatability or affordability are seen to play a role in the health or nutrient quality of the product^{(Reference Visioli, Marangoni and Fogliano17)}.

Food processing is a broad term that encompasses many different unit operations that are applied for a variety of different reasons, and although primarily used to increase the safety and digestibility of raw materials, they cannot all be described or defined as a single formulation or ‘process’^{(Reference Forde and Decker18)}. These approaches are applied to enhance sensory properties, ensure safety, extend shelf-life and improve nutrient (bio)availability among other reasons. Including ‘purpose of processing’ in the NOVA definition opens the classification to subjective interpretations of the intended purpose, increasing the risk of a biased interpretation and misclassification of processes and related health outcomes. This creates a separate, but related, debate on the potential to conflate the healthfulness of a food with an individual's own ideological bias against the modern food production system, or preconceptions towards the economic success of large food producers. Importantly, to date, there is no evidence that foods that are unprofitable, unpalatable, expensive or inconvenient to eat are necessarily better for your health. Moreover, producing foods that are unappealing and more expensive may reduce their intake in the short-term, but is unlikely to be a popular approach among consumers or food producers, and hardly seems a strong basis for public health strategies that aim to combat diet-related chronic disease^{(Reference Mela19)}. It is unlikely that company size, profitability or the ‘purpose’ of processing will inform dietary guidance in the future, and recommendations will continue to be firmly grounded in the evidence related to an objective appraisal of a foods nutritive value, and its potential to support healthy dietary patterns.

A critique of the observational evidence on the impact of processed food on health

Contribution of specific food groups to the NOVA 4 (ultra-processed) category

Epidemiological research categorises foods and beverages into ‘food groups’ to move beyond single foods and nutrients and inform a better understanding of the specific dietary patterns that link to specific health outcomes. In this way, we can conclude that regular consumption of a given food group is associated with positive or negative health outcomes. For example, ‘dairy’ describes a wide range of products including different milks, butter, yogurts or cheeses and regular consumption of this broad ‘food group’ has been shown to be positively associated with improved bone-health and reduced risk of fracture^{(Reference Rizzoli30)}. By contrast, the NOVA 4 category (UPF) currently covers a broad spectrum of different foods united only by the definition of ‘foods of industrial creation’, as described previously. The broad nature of this definition means the NOVA 4 category covers approximately 60 % of energy sold in many developed countries, although this prevalence varies between countries^{(Reference Zhang, Jackson and Martinez31,Reference Zhang, Jackson and Steele32)} . Importantly, unlike the example of dairy foods and bone health, where consumption of a single food group can be linked to specific health outcome, the diversity of the NOVA 4 category encompasses between ten and twelve different food groups, and includes everything from ambient dairy to extruded breakfast cereals and frozen meals^{(Reference Gibney33,Reference Pereira34)} . Recent findings highlight the trouble with such a broad range of different food groups under the same ultra-processed umbrella. Across two studies from the Dutch Life-Lines cohort, UPF consumption was linked to all-cause mortality in a group of renal transplant patients^{(Reference Osté, Duan and Gomes-Neto35)}, and separately to the incidence of type-2 diabetes among Dutch adults^{(Reference Duan, Vinke and Navis36)}. Among renal transplant patients, the NOVA 4 category corresponded to ten distinct food groups. Closer inspection of the relationship of individual food groups revealed that only two of the ten groups remained positively associated with all-cause mortality and included sugar-sweetened beverages/desserts and processed meats^{(Reference Osté, Duan and Gomes-Neto35)}. The other food groups either had no clear association or were negatively associated with mortality (i.e. protective), including starchy foods, refined grains breakfast cereals, prepared meals, cookies, sources of fat, fried foods, salty snacks, toppings, liquors and candies. A separate comparison reported a positive association between consumption of NOVA 4 foods and increased risk of type-2 diabetes where comparison of the food's groups showed the risk was highest when the dietary pattern is defined by cold and warm savoury snacks. A pattern of NOVA 4 ‘sweet snacks and pastries’ was inversely associated with type-2 diabetes risk^{(Reference Duan, Vinke and Navis36)}. Grouping foods into the same category of NOVA 4 poses as risk when making dietary recommendations to public, as you may remove foods that are both a risk for and protective against the chronic disease outcome of interest.

The central issue is that the NOVA 4 classification assumes that most of the food processing is deleterious for health, whereas closer examination of the food groups reveals this is not the case. There is now a growing acceptance that the NOVA system is not fit for purpose if it is to be applied to guide public health strategies or provide population-level dietary guidance^{(Reference Tobias and Hall37)}. Many of the main recommendations overlap with conventional nutrient profiling approaches that offer a quantitative comparison of foods based on their nutrient and energy contents^{(Reference Drewnowski, Gupta and Darmon14,Reference Gupta, Hawk and Aggarwal38)} . Defining UPF by the purpose, ‘number’ or ‘type’ of ingredient rather than nutrient content results in recommendations to remove or reduce many foods with an acceptable nutritional quality. Removing all UPF from the diet is likely to have a significant negative effect on population health, where alongside removing nutrient-poor/energy-dense foods, it would also result in the falling intakes of food groups that have adequate nutrition and may offer protective effects to the development of diet-related chronic disease. Uniformly, discouraging the avoidance of all processed food is impractical, unrealistic and this approach lacks the nuance needed to holistically evaluate the significant contribution made by many processed and packaged foods to daily dietary intakes^{(Reference Hallinan, Rose and Buszkiewicz39–Reference Weaver, Dwyer and Fulgoni41)}.

Proposed mechanisms for the link between food processing, energy intake and health

Processing and formulation make considerable changes to a raw materials' composition and structure, and this has led to widespread speculation on the potential mechanisms by which processed foods can promote higher energy intakes and poorer health^{(Reference Srour, Kordahi and Bonazzi57,Reference Juul, Vaidean and Parekh58)} . There follows a summary of some of the putative mechanisms linking processing and health, and the available evidence to support them including the role of additives, hyper-palatability, satiety glycaemic response, energy density and energy intake rate.

A role for food additives in diet-related chronic disease

Food additives are substances added intentionally to foodstuffs to perform certain technological functions, for example, to colour, to sweeten or to help preserve foods. Today, there are over 300 food additives approved for use in the European Union that are identified by an ‘E-number’ that is always included in the ingredient lists of foods in which they are used^(59,60) . The most common additives used are antioxidants (which are added to prevent deterioration caused by oxidation), colours, emulsifiers, stabilisers, gelling agents and thickeners, preservatives and sweeteners. Their addition enhances the microbial stability, shelf-life and organoleptic properties, and their use is strictly controlled by the European Food Safety Authority in the European Union, Food and Drug Administration and globally by regulatory bodies such as the Joint FAO/WHO Expert Committee on Food Additives. Since they are added to foods, new and existing additives undergo a rigorous approval process before they can enter the food supply⁽⁶⁰⁾ and their potential harmful effects are tracked over time and monitored once the additive is available.

Additives become more prevalent in foods as degree of processing increases and have been shown to be higher within the NOVA 4 UPF category^{(Reference Chazelas, Deschasaux and Srour61,Reference Chazelas, Druesne-Pecollo and Esseddik62)} . Additives are always added to foods, so if they play a role in obesity-related diseases, there should be common biochemical pathways and mechanisms through which they can affect energy intake, either by promoting intake or dysregulation of appetite^{(Reference Gibney and Forde63)}. The use of food additives has been proposed as one of the potential mechanisms by which UPF consumption may promote metabolic dysfunction. A recent comparison of additive consumption within the Nutri-Net Sante cohort in France characterised the additive intakes in a large cohort of French consumers, and summarised these intakes by cluster from low to high intakes^{(Reference Chazelas, Druesne-Pecollo and Esseddik62)}. The authors proposed associations between additive intakes and the incidence of dietary chronic conditions such as obesity and type-2 diabetes. Importantly, when the reported levels of several additives were compared to those available and consumed in nature, the natural sources tended to be significantly higher in every case^{(Reference Gibney and Forde63)}.

How such a diverse set of chemical compounds could be associated with common biochemical pathways in the aetiology of such a wide range of conditions remain unclear. Whereas there is some evidence to show emulsifiers may have a negative effect on a subset of those suffering from irritable bowel syndrome and Crohn's disease^{(Reference Roberts, Rushworth and Richman64,Reference Bancil, Sandall and Rossi65)} , these same sensitivities have not been observed in healthy populations. To date, there is no direct evidence of widespread effects of these food additives on the gut health of a healthy human population, although further research will continue to add to our understanding of this complex area^{(Reference Las Heras, Melgar and MacSharry66)}. Studies are now proposing links between the additive content of processed foods, intakes of emulsifiers and putative links with microbiome health^{(Reference Karl, Armstrong and Player67–Reference Atzeni, Martínez and Babio69)}. Whereas it is important to inform these links with controlled hypothesis-driven research, there remains inconsistencies in the approaches used to compare the effect of specific food additives on microbiome composition, metabolites and health. There are also several obvious contradictions when linking the intake of specific food ‘additives’ to health via their impact on the microbiome. Take for example inulin, which is a soluble fibre that is frequently added to foods as a gelling agent, stabiliser and emulsifier in formulated packaged goods. Inulin is also promoted for its substantiated positive effect as an efficient pre-biotic with noted health benefits^{(Reference Ramnani, Gaudier and Bingham70,Reference Yoshinari, Bagchi and Ohia71)} . Inulin consumption has been shown to promote microbial fermentation to produce SCFA, lower gut pH that helps to inhibit pathogens, promotes the proliferation of beneficial bacteria and stimulates the production of a wide range of beneficial metabolites that positively influence health^{(Reference Teferra72)}. Evidence therefore supports the use of additives like inulin as having demonstrable health benefits that outweigh any speculative negative health outcomes linked to the use of additive more broadly.

Added flavours are common in packaged consumer goods and have been proposed as a marker of ultra-processing^{(Reference Huybrechts, Rauber and Nicolas29)}, and this has led to speculation that the added flavours promote overeating by increasing the hedonic appeal or by disrupting normal flavour nutrient learning to promote weight gain^{(Reference Neumann and Fasshauer73)}. The suggestion is that sensory cues from highly processed foods no longer signal a foods' underlying nutrient content, such that synthetic and cosmetic flavours disrupt normal ‘taste–nutrient’ relationships and through this facilitate over-consumption. If this were true, then foods high in mono- and di-saccharides would not have a sweet taste intensity that reflects this concentration, or foods higher in NaCl would lack a salt taste intensity that matches their salt content, due to disruption of these taste–nutrient associations^{(Reference van Langeveld, Gibbons and Koelliker74)}. Data from a nationally representative survey of Singaporean diets were pooled to compare the perceived taste of a wide range of different foods to the content of the taste substrates (i.e. NaCl) across all levels of processing^{(Reference Teo, Tso and van Dam75)}. These results highlight that taste–nutrient relationships are maintained across all levels of food processing, including among foods classified as ultra-processed. Available data currently do not support claims made on the role of flavour additives in promoting food intake, although it remains important to question and monitor the safety of food additives and their potential impact on health. Ongoing research is further exploring the role of additives in promoting palatability and energy intake from processed foods (i.e. NCT05290064; NCT05550818).

Researching the specific impact of individual additives is extremely challenging due to the mixed nature of our diets, and the lack of quantitative information on additive intakes or exposure from either branded food databases or dietary records^{(Reference Gibney and Forde63)}. For example, it would be wrong to use inappropriate exposure assessments such as cross-sectional data and food frequency questionnaires to construct links between a foods' additive content and health. Using this as a basis for conclusions on the effect of additives on health or to support arguments to remove additives from the food supply is both inappropriate and unrealistic. If additive use is playing a role in promoting metabolic dysfunction, then research is needed to demonstrate this and regulations adjusted accordingly.

Are (ultra)processed foods all low in satiety and high in glycaemic response?

Another proposed mechanism is that refined carbohydrates from highly processed products derived from maize, wheat and rice promote over-eating by contributing energy, while also stimulating insulin release that clears blood glucose to adipose stores and promotes an increased hunger^{(Reference Ludwig and Ebbeling87)}. This model of obesity and metabolic dysfunction has been hotly debated in recent years^{(Reference Hall, Farooqi and Friedman88)}. The premise is that if you reduce rapidly digestible carbohydrate, blood glucose levels will not spike to promote insulin release, fat storage and greater hunger/lower satiety. However, the links to ultra-processing and poor health are tenuous and based on a small set of selective comparisons. Preliminary comparison of published glycaemic and satiety values was used to propose that all processed foods have low satiety and a high glycaemic index^{(Reference Fardet89)}. Using previously published glycaemic and satiety databases, foods were categorised by their degree of processing and compared glycaemic response and satiety ratio, resulting in a descriptive comparison that has been used to substantiate claims that UPF promote insulin release and are less satiating than minimally processed foods^{(Reference Fardet89)}. However, a recent report has highlighted that UPF may in fact have a lower glycaemic index than comparable foods that are classified as minimally processed^{(Reference Basile, Ruiz-Tejada and Mohr90)}. Furthermore, there were no observed differences in post-meal satiety or later snack intake over 2 weeks in the only direct comparison of ultra- and minimally processed diets^{(Reference Hall, Ayuketah and Brychta91)}. Indeed, some foods classified as ultra-processed can have lower fibre and protein contents than minimally processed foods, which could influence gastric emptying rate and neuro-endocrine satiety signalling, but this would need to be tested and is not the case across all (ultra)processed foods. To test this requires further research where energy and macronutrient matched meals are compared directly within the same population for potential differences in post-meal satiety. The implication is that mechanisms linking degree of processing to energy intake or satiety should be formally tested under controlled conditions to ensure mechanistic claims are supported by the appropriate data. In the absence of direct evidence, caution should be exercised when claims are made on the many of the putative mechanisms and proposed solutions that are not currently supported by published data. Future research should now focus on formally testing the role of specific nutrient and behavioural features of processed foods that may drive greater energy intakes and health outcomes.

The role of energy intake rate in energy consumption from ultra-processed foods

A meal eating rate is described in g/min and is believed to be the product of the textural challenge posed by the food being consumed and an individual's internal drive to eat^{(Reference Teo, Forde and Meiselman100)}. Extensive evidence from observational epidemiological studies consistently shows that self-reported eating rate is a predictor of higher energy intakes, body weight, adiposity and a wide range of cardio-metabolic risk factors^{(Reference Ohkuma, Hirakawa and Nakamura101–Reference Forde, Stieger, Chen, Wolf and Bakalis105)}. This is further supported by findings from a series of controlled human feeding trials, where it has been shown that increasing the eating rate by approximately 20 % (g/min) results in a 12–15 % increase in ad libitum energy intake^{(Reference Forde106)}. Previous research on the textural properties of the food environment has shown that food form and texture can strongly influence the rate of consumption, with eating speeds for solid foods as low as 10–12 g/min, and for beverages up to 500–600 g/min^{(Reference Viskaal-van Dongen, Kok and de Graaf107–Reference Wee, Goh and Stieger112)}. These differences in eating speed can significantly and consistently influence ad libitum energy intakes^{(Reference Teo, van Dam and Whitton104,Reference Forde, van Kuijk and Thaler110,Reference McCrickerd, Lim and Leong113–Reference Teo, Lim and Goh115)} . A simple example of this is the comparison of energy consumed from liquids v. solids, where it has been well established that high energy-dense liquids promote passive overconsumption compared to an equivalent energy load consumed as a semi-solid or solid^{(Reference de Graaf116–Reference Mattes and Rothacker119)}. Meal eating rate is driven by its texture properties^{(Reference Bolhuis and Forde120)} and may also interact with other known meal properties of meals that result in great intake, including portion size^{(Reference Cunningham, Roe and Keller121)} and energy density^{(Reference McCrickerd, Lim and Leong113)}.

Higher energy density can interact with food form and texture to influence the rate and extent of energy intake within a meal^{(Reference Teo, Tso and van Dam75,Reference Teo, Lim and Goh115,Reference Forde, Mars and De Graaf122)} . Higher energy density contributes to positive energy balance but makes a smaller contribution to the onset of satiation, meaning there is little adjustment within meal in response to consuming foods with a high energy density. In the one RCT that compared energy intake from ultra- v. minimally processed diets, participants consumed the ultra-processed meals up to 50 % faster (i.e. average energy intake rate 200⋅8 (48) v. 129.7 (31) kJ (kcal)/min), reflecting a combination of both softer textures and higher energy density among the foods in the ultra-processed diet. For certain UPFs, their textural properties may facilitate easier and more rapid consumption resulting in a faster eating rate^{(Reference Forde, Mars and De Graaf122)}, such that overconsumption may occur before gut–brain signals have time to communicate satiation^{(Reference Tobias and Hall37)}. Further research into the specific question of whether food texture or degree of processing moderates energy intake led to a comparison of ad libitum energy intakes from ultra- and minimally processed meals that differed in their texture and eating rate^{(Reference Teo, Lim and Goh115)}. In the harder-texture condition, eating rates were reduced across both processing levels which produced a 21 % reduction in amount (g) and 26 % reduction in energy consumed. Research is now needed to clarify the role of food texture in moderating energy intake from processed foods, and an RCT is now underway to test whether the observed effect of food texture on intake from (ultra)-processed foods is sustained over time (https://restructureproject.org/).

Meal texture is more influential in driving intake within a meal than the degree of processing, leading to suggestions that the issue of texture and eating rate should be central in the development of new strategies to moderate energy intakes from processed food environment^{(Reference Gibney123)}. In recent years, there has been a proliferation in research on how to apply food texture changes to moderate eating rate^{(Reference Bolhuis and Forde120,Reference Forde and Bolhuis124)} and apply this to reduce meal size and moderate the metabolic response to food consumed^{(Reference Forde, Stieger, Chen, Wolf and Bakalis105,Reference Choy, Goh and Chatonidi125–Reference Chen, Stieger and Capuano128)} . Future research should consider food texture-based strategies and manipulations to support consumers to reduce their eating speed and meal size. To achieve this, we will need further mechanistic studies to establish how these nutritive and behavioural properties differ across processed foods to better understand their contribution to higher intakes, and test whether changing these properties can help mitigate the risk of overconsumption.