The rise in the availability and intake of processed foods (PF) and ultra-processed foods (UPF) has been posited by some public health authorities and organisations to be a prime cause of poor diets and rising rates of obesity and chronic disease(Reference Monteiro1–Reference Popkin and Reardon10). Therefore, Montiero and others published the NOVA (not an acronym) categorisation, which divides foods into four categories: minimally PF-NOVA (MPFn); UPFn; processed culinary ingredients (PCI); PFn. Designation of NOVA categories in the present paper will carry the subscript n; for example UPF-NOVA is UPFn. By contrast, for generic PF and UPF there is no subscript. Those classified by International Food Information Council (IFIC) will be MPFi and PFi(Reference Monteiro1, 2, Reference Monteiro, Levy and Claro11). NOVA proponents suggest that shifts from ingestion of the two latter categories to MPFn and PCIn will improve nutrition and health.
Category designations in NOVA are controversial because they imply their basis on the complexity of food processing, however, this is not the case. For example, foods with added sugar are deemed as PFn or UPFn regardless of processing methods or technology used. Foods processed by innovative, non-traditional techniques such as electric or magnetic fields may be deemed as MPFn despite the use of non-traditional, complex processes(Reference Heinrich, Zunabovic and Varzakas12–Reference Misra, Koubaa and Roohinejad14).
Studies using NOVA demonstrate that PFn/UPFn deliver most of the added sugars and are associated with obesity and other health risks(Reference Moubarac, Batal and Louzada6–Reference Cediel, Reyes and da Costa Louzada9, Reference Juul, Martinez-Steele and Parekh15), but other categorisations yield different results(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18). Further, placement of foods into categories among NOVA studies is inconsistent(Reference Moubarac, Batal and Louzada6–Reference Cediel, Reyes and da Costa Louzada9, Reference Dwyer, Fulgoni and Clemens19).
The present paper will compare the NOVA definition with legal, technical, popular press and public health definitions. The NOVA categorisation will be compared with that of the IFIC. Designation of foods with more than five ingredients or presence of ‘added sugars’ or additives as UPFn will be challenged. Further, analyses documenting that foods categorised as PFn/UPFn provide much of the ‘added sugars’ will be shown as tautological logic.
Nutrient intakes and health outcomes using the NOVA system will be compared with those recommended in dietary guidance such as Dietary Approaches to Stop Hypertension (DASH)(Reference Challa and Uppaluri20) or the United States Department of Agriculture MyPlate(21, Reference Britten, Marcoe and Yamini22). NOVA's adherence to requirements for dietary guidance: understandability, adaptability, applicability and practicality, will be questioned(Reference Evert, Boucher and Cypress23, Reference Rowe, Alexander and Almeida24).
Processed food: history and definitions
‘Cooking, which is one part of processing, went hand-in-hand with becoming human. Human food is processed food,’ according to food historian Rachel Laudan(Reference Laudan25). PF enabled world exploration and settling of territories and continents. PF's ability to extend the food supply yielded the highest accolades from Napoleon, who awarded 50 000 francs to Nicholas Appert for developing canned food to feed French troops(Reference Nicholas26). PF became vital to a country's food supplies and as such, they became the purview of governments to ensure their safety(27). Thus, they were regulated and defined(28–36).
Definitions of processed foods: legal and food science
Regulatory and food science definitions are found in Table 1A(28–36). These definitions show strong congruence but differ in detail. All agree that one or more physical, chemical or microbiological steps change raw commodities into ingredients or foods. All allow formulations with any number or type of ingredients. The United States Department of Agriculture also has a legal definition of MPF(31).
Table 1. Representative definitions and descriptions of food processing (FP) and processed food (PF)
* Nearly all legal and food science definitions of food processing have similar examples and allow additions to the list as new processed emerge.
† Example of a consumer education group using dietitians and food professionals as spokespeople.
‡ Example of an organic agricultural products marketing and trade resource that is not in favour of biotechnology or pesticides.
§ Example of a US newspaper website.
║ Example of health newsletter associated with the large health system.
¶ Natural is not legally defined in many jurisdictions.
** Example of the newsletter from a vendor of supplements and health foods.
Goals of food processing are also aligned in this group of definitions. These include increasing shelf life, maintaining or enhancing safety and nutrient quality, addressing specific nutritional requirements and adding variety and convenience.
Newer usages and definitions of processed foods and ultra-processed foods
Bibliographic citations in PubMed about PF until 10 years ago were about the intersection of food science and nutrition and presented data on the impacts of processing techniques on food safety, nutrient retention or availability and microbiological quality. In 2009 UPF emerged as a term and transmuted (along with the term PF) from food science to public health. It defined the degree of processing non-traditionally and added presence or absence of certain food components as a dimension(Reference Monteiro1–Reference Montiero, Moubarac and Cannon4). This prompted studies that documented the penetration of PF and UPF into diets and that tested associations between their intake and nutrient quality, obesity and disease(2–Reference Montiero, Moubarac and Cannon4, Reference Moubarac, Batal and Louzada6, Reference Costa Louzada, Martins and Canella7, Reference Cediel, Reyes and da Costa Louzada9, Reference Moubarac, Batal and Martins37). This spawned promotion of the NOVA dietary system that recommended the use of MPFn and avoidance of PFn/UPFn.
Definitions of processed foods: dictionary, consumer organisations and popular press
Among this group (Table 1B)(38–Reference Peitrangelo43), definitions and connotations vary greatly. Only two, Wikipedia(38) and IFIC(39), show alignment with legal or food science definitions. Several recognise that most foods are processed in some way to improve nutrient absorption, to make food safer and to prevent waste and that they are ‘not all bad’(Reference Collins40–Reference Sunley45).
Many websites and popular press definitions (Table 1B) describe PF as requiring complex processes and having lengthy ingredient lists including chemicals and additives(Reference Ferrer46–49). Regardless of nutritive value, PF are often presented pejoratively with comments such as ‘not whole or found in nature’, ‘sold in packets or tins’, ‘fast or junk foods with minimal nutrients and fiber’, ‘less satisfying’ and ‘use fewer calories to metabolize than whole foods’(50–Reference Gif56). Web images most frequently depict sugary drinks, candy, crisps, chips (fries) and frozen or baked sugary, fatty or salty treats. However, some also show bread, canned fish and fruit, baby foods, infant formula and ready-to-eat cereals (RTEC)(57, 58).
The diversity of foods, images and descriptions portrayed demonstrate lack of agreement as to definition or food categorisation in the popular press. Further confusing consumers is the suggestion that home-prepared foods are always nutritionally superior and are not processed, even when techniques and ingredients are identical(Reference Wahlqvist and Briggs59).
Processed foods: continuums and categorisations
Food scientists
PF exist on a continuum that food scientists base on the complexity of processes, not numbers or kinds of ingredients. Additives, salts and sugars are regarded as part of the recipe, not as processes, and can add flavour but also extend shelf life and preserve nutrients(Reference Sandulachi and Tatarov60). These components help to fulfill the goal of processing, which is to reduce pre- and post-harvest losses, to minimise resource use, to decrease waste, to maintain safety and quality and to offer convenience(Reference van Boekel, Fogliano and Pellegrini61, Reference Xu, Sun and Zeng62). These may address food supply issues and lower costs(Reference Martindale63, Reference Janssen, Nijenhuis-de Vries and Boer64).
Food scientists recognise processing may alter nutrient content and bioavailability, either positively or negatively(Reference Wahlqvist and Briggs59). Processes and ingredients are adjusted to minimise losses and maintain nutrients. Fortificants may be added to address demonstrated deficiencies(65, Reference Fulgoni, Keast and Bailey66). Additional ingredients can add variety and palatability making nutrients more likely to be ingested(Reference Bernstein, Tucker and Ryan67). While variety may induce overeating, so can food that is unsatisfying, as people eat more to seek satisfaction. Both aspects need more study(Reference Johnson and Wardle68).
Nutrition and the food processing continuum
Traditional dietary guidance is based on optimising intakes of food groups and nutrients(69, 70). Nutrient-poor foods are to be chosen infrequently(71). Vetted diet plans with proven health benefits, such as DASH, use a mix of foods from all levels of processing to help consumers reach nutrition and health targets(Reference Challa and Uppaluri20, Reference Panagiotakos, Notara and Kouvari72–Reference Duyff77). PF are featured in the United States Department of Agriculture MyPlate (ChooseMyPlate.gov) sample menu plans, which are designed to meet recommendations for consumers with limited resources(21, 78).
International Food Information Council categorisation
Table 2 shows the five categories of the IFIC model. All categories contain foods to choose frequently and infrequently. Addition of sugar, salt or additives or numbers of ingredients had no effect on category placement. Home-prepared foods are categorised with the same criteria as manufactured ones.
Table 2. International food information council (IFIC) processed food categorisation
Adapted from http://www.ific.org.
NOVA
Public Health Professor Carlos Montiero and colleagues initiated the NOVA categorisation of foods found in Table 3(Reference Monteiro1–Reference Montiero, Moubarac and Cannon4). Initially, there were three categories, MPFn, PCI, PFn(Reference Adams and White79). Subsequently, PFn was split into PFn and UPFn making four categories. MPFn are described as undergoing minimal processing such as washing, milling, chilling, freezing, or vacuum-packing (vacuum-packing, especially of cooked, refrigerated vegetables, is viewed by food scientists as one which requires attention to maintain nutrients and safety and has a degree of complexity). PCI include ingredients found in home kitchens, such as starch, sugar and oil. (PCI initially included starch and pasta.) PFn are defined as recognisable versions of original foods that may have added PCI (e.g. sugar or salt) to extend shelf life or modify palatability. They are generally consumed as part of meals or dishes. UPFn are described as industrial formulations with five or more ingredients, which are often packaged, branded, convenient and highly palatable and function as snacks or replace homemade dishes. They may include additives, sweeteners and added micronutrients to fortify them.
Table 3. NOVA classification of foods(2, Reference Moubarac, Batal and Louzada6)
* PCIn −2010; MPFn-2016.
† UPFn −2010; PFn-2016(Reference Monteiro1–Reference Montiero, Moubarac and Cannon4, Reference Moubarac, Batal and Louzada6).
The NOVA categorisation was enfranchised by the Pan American Health Organisation(2). While Pan American Health Organisation recognises that nearly all foods are processed and notes their benefits and essentiality, they raise concern about and their potential contribution to disease.(2) Pan American Health Organisation's document described UPFn as ‘attractive, hyper-palatable, cheap, ready-to-consume food products that are characteristically energy-dense, fatty, sugary or salty and generally obesogenic.’(2).
Comparison of definitions and categorisations
Legal, food science, Wikipedia and IFIC usage, definitions and categorisations of PF show congruence, but those of NOVA, public health, popular press or website definitions show dissimilarities. Among the IFIC and NOVA categories, MPF, foods that require little processing, are most similar(Reference Monteiro1–Reference Montiero, Moubarac and Cannon4, Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18). However, the addition of sugar or salt moves foods from MPFn to PFn despite identical processing. Thus, pasteurised milk, yoghurts and roasted nuts are MPF in IFIC and NOVA but only remain MPFn in NOVA if no sugar, salt or additives are present. In the IFIC classification(Reference Martínez Steele, Baraldi and Louzada8, Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18), canned or frozen fruit, vegetables, meat or fish would be classed as ‘foods processed to help preserve and enhance nutrients’ regardless of the numbers or types of ingredients or additives. In NOVA a single food without additives would be MPFn, but the addition of sugar or additives make them PFn, and more than five ingredients, UPFn.
Bread and cereals in IFIC classification would be in the ready-to-eat (RTE) category. In NOVA breads with five or fewer ingredients and unpackaged are PFn, but become UPFn if packaged or contain more than five ingredients. All cereals containing sugar and salt are UPFn.
Studies on nutrient contribution of foods in International Food Information Council and NOVA categorisations
Post hoc analyses using food intake databases have been conducted with the IFIC categorisation and NOVA. The results of the analyses differ because criteria for the food categories are so different.
International Food Information Council
Analyses of US National Health and Nutrition Examination Survey (n 25 351 over 2 years old) showed that MPFi contributed 17% of energy (E), but over 50% of the vitamin D (mostly due to fortified dairy) and over 30% of the potassium, calcium and vitamin B12(Reference Martínez Steele, Baraldi and Louzada8, Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18). Foods processed for preservation (mostly canned and frozen) contributed about 5% of E, but over 30% vitamin C and over 5% of potassium, fibre, magnesium, folate, calcium, vitamin B6 and iron. This category contributed <5% of the salt but 8% of the sugar.
RTE PFi contributed 35% of E, and higher percentages of iron, folate and vitamin B6. It also contributed 45% of the added sugars (45%), with major contributions from sugar-sweetened beverages, juice drinks and grain-based snacks and desserts(Reference Martínez Steele, Baraldi and Louzada8, Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18). Sodium contributions were lower than the percent of E.
Mixtures of ingredients provided 17% of E and slightly more carbohydrate, fibre, thiamin, folate, calcium and iron, but a lower percentage of added sugars than the percent of E.
Prepared foods and meals provided about 4% of E and 5% of protein and sodium and contributed other nutrients equal to or slightly less than the percent of E.
All International Food Information Council processed food categories combined
When IFIC categories containing PFi (omitting MPFi) were combined, they contributed 57% of E, but they delivered nutrients of concern (designated by the 2010 US Dietary Guidelines Advisory Committee)(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18, 80). Specifically, PFi contributed 45–55% of dietary fibre and nearly all the cereal fibre, 48% of the calcium, 43% of the potassium, 34% of the vitamin D, 64% of the iron, 65% of the folate and 46% of the vitamin B12. For constituents to limit, total PFi contributed equivalent or slightly lower percent of E for saturated fat (52%) and sodium (57%). All five IFIC categories provided about 2300 mg sodium with most coming from mixtures of combined ingredients (approximately 700 mg) and RTE foods (approximately 1000 mg). Foods eaten outside the home provided about 1200 mg(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18).
While MPFi contributed 5% of the added sugars, the four PFi combined contributed 75%, and restaurant foods the remainder. The RTE category provided the most added sugars(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18) but most were from foods dietary guidance recommends limiting such as sugary beverages. However, some added sugars were from foods to encourage such as fibre-rich, enriched and fortified bread and cereals, fruit and dairy.
Diet selection and categorisation
Authors of the IFIC studies(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18) concluded that diets were more likely ‘to meet… recommendations if nutrient-dense foods, either processed or not, are selected.’ Poti et al.(Reference Poti, Mendez and Ng81) also concluded that while PF had more added sugars, there was a wide variation in nutrient content within categories and that choice within a category mattered. Similar examples are gleaned from healthy dietary patterns such as DASH and the US Healthy-Style Eating Pattern (as symbolised by MyPlate), that show nutritious diets can be constructed with the right mix of PF and MPF(Reference Fulgoni, Keast and Bailey66, 69, Reference Panagiotakos, Notara and Kouvari72–78).
NOVA and nutrients
Several studies correlated the increased availability of UPFn over the last 30+ years with a decline in overall nutrient quality(Reference Montiero, Moubarac and Cannon4, Reference Popkin and Reardon10, Reference Moubarac, Batal and Martins37, Reference Martins, Levy and Claro82). Analyses of food intake data from several countries documented that those who chose the most UPFn had lower nutrient quality than those who chose the least. In the 2004 Canadian Community Health Survey.2 (n 33 694, >2 years), those in the highest quintile of intake of UPFn, ate on average 1046 kJ (250 kcals) more, but compared with those in the lowest quintile, ingested lower levels of riboflavin, niacin and vitamins A, B12, C, D and B6(Reference Moubarac, Batal and Louzada6). Sodium and energy density were higher for the consumers of UPFn.
Similar results came from 2008 to 2009 Pesquisa de Orçamentos Familiares (Brazilian Family Budgets Survey of 32 898 individuals over 10 years). UPFn contributed 21·5% of E(Reference Costa Louzada, Martins and Canella7). Those in the highest quintile of UPFn intake consumed more energy but less fibre and potassium. However, the analysis showed that certain PFn and UPFn, specifically bread, cheese, processed meats and canned fruit and vegetables, contributed important nutrients. This latter statement agrees with findings from other studies that emphasise choice of foods within a category, not the category itself(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18, Reference Poti, Mendez and Ng81).
Added sugars and the NOVA and International Food Information Council classifications
Since NOVA categorises all commercially prepared foods with added sugars as PFn or UPFn, it is self-evident that analysis of food intake data would identify them as significant contributors of added sugars. According to the US National Health and Nutrition Examination Survey 2009–2010 (n 9317), UPFn delivered nearly 60% of E but 90% of the added sugars for children and adults(Reference Martínez Steele, Baraldi and Louzada8). Canadian data showed UPFn contributing 49% of E and a significant amount of free sugars(Reference Moubarac, Batal and Louzada6). Analysis of Chile's 2010 Encuesta Nacional de Consumo Alimentario (n 4920, 2+ years) showed that UPFn contributed 29% of E and 59% of added sugars(Reference Cediel, Reyes and da Costa Louzada9). In the 22 116 households participating in the 2010 Spanish Household Budget Surveys (food disappearance, not intake data), UPFn provided 31·7% of daily E and 80·4% of added sugars(Reference Latasa, Louzada and Martinez Steele83). In the Brazilian Pesquisa de Orçamentos Familiares, UPFn provided 21·5% of E and 29% of added sugars(Reference Costa Louzada, Martins and Canella7).
Ultra-processed foods-NOVA and obesity
Proponents of NOVA have noted that the rise in obesity over the last 30+ years has paralleled the increased availability of UPFn(Reference Moubarac, Batal and Louzada6, Reference Costa Louzada, Martins and Canella7). Specifically, in nineteen European countries, their increased availability between 1991 and 2008 was associated with increased obesity(Reference Monteiro, Moubarac and Levy84). The authors concluded that ‘A significant positive association was found between national household availability of ultra-processed foods and national prevalence of obesity among adults…’ However, further analyses of their data showing UPFn availability by country does not show strong concordance with obesity data from the Organisation for Economic Co-operation and Development(85, 86). Table 4 compares a few countries with the high and low availability of UPFn and obesity percentages. Simple associational data(Reference Monteiro, Moubarac and Levy84) fail to consider Food and Agriculture Organization data documenting increased energy consumed over that same time period(Reference Roser and Ritchie87).
Table 4. UPFn Availability and obesity in selected countries (2008)
UPFn, Ultraprocessed foods NOVA.(Reference Monteiro, Moubarac and Levy84)
Studies associating UPFn with obesity had differing outcomes if they were adjusted for other contributors to obesity. Findings from the 2008 to 2009 Brazilian Dietary Survey showed that those in the quintile eating the most UPFn, compared those eating the least, had higher risks of overweight (OR = 1·26) or obesity (OR = 1·98)(Reference Louzada, Baraldi and Steele88). However, it also showed that energy intakes for the higher quintile were 1255 kJ (300 kcal) more than for the lowest quintile(Reference Costa Louzada, Martins and Canella7). This begs the question about adjusting for energy and whether the cause is more energy consumed or UPFn. Findings were similar from Spanish University of Navarra cohort, where those in the highest, v. lowest, quartile of UPFn consumption (three NOVA categories, not four) had a hazard risk for obesity of 1·26(Reference Mendonça, Pimenta and Gea89, Reference Mendonça, Lopes and Gea90). However, there was no relationship between UPFn and weight in the UK's National Diet and Nutrition Survey (2008–12; n 2174), after adjusting for other causes of obesity. This study did show that diets high in PCIn were associated with body weight, indicating that food prepared at home may not stem the rise in obesity(Reference Monteiro, Moubarac and Levy84).
Processed foods, nutrient intake, food choice and added nutrients
MPFn were shown to contain the greatest share of vitamins and minerals, and UK diets high in PFn/UPFn were lower in nutrients(Reference Adams and White79). However, the study affirmed previous findings that not all PFn/UPFn were of lower nutritional quality. The study's authors emphasised the need for attention to nutrient density, not processing when constructing diets(Reference Eicher-Miller, Fulgoni and Keast16–Reference Eicher-Miller, Fulgoni and Keast18, Reference Adams and White79, Reference Poti, Mendez and Ng81).
Consumption of ultra-processed foods-NOVA may impact consumption of minimally processed foods-NOVA
Many MPF are processed or combined with other ingredients before eating. This not only may improve safety and acceptability, it may help with nutrient availability. For example, fat-soluble components in raw vegetables are better absorbed with fat from dressings and sauces (UPFn) and are more likely to be chosen by children(Reference Zeinstra, Vrijhof and Kremer91, Reference Fisher, Mennella and Hughes92). Furthermore, homemade oil-based condiments are not inherently healthier than commercial ones.
Consumption of certain UPFn appears to encourage consumption of important MPFn. For example, children and adolescents who consume RTEC breakfast also consumed more milk, yoghurt and fruit than those who consumed other breakfasts(Reference Affenito, Thompson and Dorazio93, Reference Michels, De Henauw and Beghin94).
Questions about foods categorised as ultra-processed foods-NOVA
UPFn as a group contributed smaller amounts of fibre, vitamins and minerals than other groups(Reference Moubarac, Batal and Louzada6, Reference Costa Louzada, Martins and Canella7). However, placement of foods in various groupings is puzzling. Categorising discretionary foods (candies, sugary beverages and grain-based desserts) with core (staple) foods such as whole grain bread and cereals, not only fails to make logical sense, it can foster erroneous conclusions about the nutrient contribution of core foods. For example, categorising corn or wheat starch as a PCIn but whole grain bread and cereals as UPFn does not make sense in terms of many nutrients. Whole grain/enriched/fortified breads are the leading sources of whole grain and fibre and are components that are under-consumed(Reference Priebe and McMonagle95–Reference Fayet-Moore, Cassettari and Tuck101). Consumption of enriched/fortified RTEC was, in a meta-analysis of sixty-four studies, associated with healthier dietary patterns and more fibre and whole grains intake, despite higher intakes of total sugars(Reference Michels, De Henauw and Beghin94). Persons consuming RTEC frequently (≥5 times/week) were more likely to have adequate intakes of vitamins A and B6, folate, calcium, magnesium and zinc(Reference Fulgoni, Keast and Bailey66).
Similarly, labelling of some forms of oily fish, especially shelf stable, affordable sources, as PFn/UPFn might decrease intakes of n-3 fatty acids(Reference Fayet-Moore, Baghurst and Meyer102).
Fortified foods
All foods with added nutrients are UPFn. However, data support the positive impact of enrichment and fortification. In the USA their use means that fewer than 12% of the US population fall below the estimated average requirement for thiamin, riboflavin, folate, iron and vitamin B6(Reference Weaver, Dwyer and Fulgoni17, Reference Fulgoni, Keast and Bailey66). For thiamin, 49% meet the estimated average requirement without fortificants, but 96% with them; for folate 12% without and 89% with them(Reference Fulgoni, Keast and Bailey66). Avoidance of folate-fortified grains in women the year prior to conception (as part of low carbohydrate or gluten/grain-free diets) was associated with a 30% increased risk of spina bifida and anencephaly in the infants(Reference Desrosiers, Siega-Riz and Mosley103). Thus, questionable placement of some foods into various categories and recommending the avoidance of all foods designated as UPFn may not be sound dietary advice and may carry risks.
Ultra-processed foods, grain foods and body weight
Most grain-based foods are listed as UPFn. Many eat too many grain servings, especially grain-based desserts or snacks and most fail to ingest recommended levels of wholegrain and fibre(80, 104–Reference Cohen, Sturm and Lara106). Excess consumption of grain-based desserts and snacks may be associated with weight. However, avoidance of wholegrain and high-fibre bread and cereals because they are deemed UPFn, may not address weight concerns. In the Physicians Health Study, those who ate one or more servings of whole and refined grain cereals daily, compared with those who ate less, were associated with lower risk of increasing BMI over time(Reference Bazzano, Song and Bubes107). Adolescents in the European HELENA cohort who were daily RTEC consumers, either whole grain or refined, had an OR of being overweight, 0·43 compared with non-consumers(Reference Michels, De Henauw and Breidenassel108). Similar findings have been shown in Australian children and adults(Reference Fayet-Moore, Petocz and McConnell109, Reference Fayet-Moore, Kim and Sritharan110). Designation of RTEC and bread as PFn/UPFn may decrease wholegrain, fibre and nutrient intakes and may not address the obesity problem(Reference Ludwig, Hu and Tappy111).
Added sugars, flavoured milk, nutrients and obesity
Flavoured milk and yoghurts are categorised as UPFn. However, children consuming flavoured, v. unflavoured, milk have higher calcium and nutrient intakes and lower obesity risks(Reference Fayet-Moore112, Reference Murphy, Douglass and Johnson113). Initiatives to eliminate flavoured milk in schools made no difference in added sugars consumption. However, there was a significant drop in overall milk and calcium consumption(Reference Nicklas, O'Neil and Fulgoni114, Reference Hanks, Just and Wansink115) because flavoured milk drinkers consumed more milk. Avoidance of flavoured milk may do little to address obesity and may reduce nutrient intake(Reference Fayet-Moore112, Reference Murphy, Douglass and Johnson113).
Ultra-processed foods and other foods
Designating foods e.g. infant formulas, supplemental foods, lactose- and gluten-free foods, as UPFn might cause avoidance by those who need these(Reference Ortega, Jiménez Ortega and Perea Sánchez116–Reference Schultz, Roupas and Wiechula118). Avoidance of any of those foods might do little to address rising rates of obesity and may not improve health.
Does the NOVA categorisation meet standards for dietary guidance?
Nutrition recommendations should follow the Hippocratic oath primum non nocere ‘first do no harm.’ Ideally, they should improve food choices and health outcomes and not create a possibility of less healthy choices(Reference Tapsell, Neale and Satija119).
Standards for dietary recommendations state that they: (1) are based on valid assumptions and sound science; (2) improve nutrient intakes and public health; (3) have been successfully β-tested with consumers and have outcomes equivalent to vetted recommendations; (4) address the four principles for successful dietary recommendations (Table 5)(Reference Eicher-Miller, Fulgoni and Keast18, Reference Dwyer, Fulgoni and Clemens19).
Table 5. Principles for successful dietary recommendations.(Reference Aguayo-Patrón and Calderón de la Barca5, Reference Moubarac, Batal and Louzada6)
Adaptable to many lifestyles and cultures for the long term.
Does the placement of foods in the NOVA categories use valid assumptions and sound science?
Placement of foods in NOVA categories may not be based on valid assumptions as noted in the previous discussion. Analyses of food intake data showing that PFn/UPFn provide a large proportion of added sugars demonstrates a tautology(Reference Vogt120). (A tautology exists when a conclusion involves circular reasoning and cannot be tested with empirical data.) Since foods with added sugars were designated as PFn/UPFn, most added sugars would come from these categories(Reference Gibney, Forde and Mullally121).
Recommendations to avoid foods containing more than five ingredients has an equivocal theoretical basis. Proof that foods with fewer than five ingredients are healthier than those with more is not possible because a food's nutritional quality depends on the ingredients and their treatment. More ingredients might complete a protein, contribute needed nutrients or act synergistically to improve nutrient absorption(Reference Cheatham122). Ingredients (including additives) can make food safer, prevent nutrient loss, enable foods for special needs (e.g. gluten-free products) or enhance acceptability of needed dietary components e.g. bran(Reference Hossain, Sadekuzzaman and Ha123–Reference Goldfein and Slavin125). They also can do the opposite especially if the ingredients are ‘components to limit,’ such as sugar(Reference Desrosiers, Siega-Riz and Mosley103). Judging food quality on the number of ingredients, rather on their nutritional contribution, is questionable(Reference Tapsell, Neale and Satija119, Reference Vogt120).
Are NOVA categories understandable and actionable?
Dietary guidance works when recommendations give consumers clarity about foods to choose. The many disparate definitions and categories (Tables 1–3) are a testament to the lack of agreement. Even within NOVA studies, foods are not uniformly categorised among studies and their placement in categories is not consistent among studies(Reference Monteiro1–Reference Juul, Martinez-Steele and Parekh15, Reference Adams and White79, Reference Martins, Levy and Claro82–Reference Monteiro, Moubarac and Levy84, Reference Louzada, Baraldi and Steele88–Reference Mendonça, Lopes and Gea90).
NOVA guidance requires consumers to have the knowledge of menu planning and skills and ability, time and resources to utilise PCI and MPFn to plan menus and prepare meals. However, consumers in many regions have limited skills in these areas(Reference Burton, Reid and Worsley126–Reference Murray, Mahadevan and Gatto129). Elderly and those with mobility or cognitive limitations may find PFn and UPFn not only helpful but necessary(Reference Goverover, Strober and Chiaravalloti130, Reference Van Gameren-Oosterom, Fekkes and Reijneveld131).
Time, cost and affordability for most consumers are limited, especially for those with children, employed outside the home. Processed foods and labour-saving equipment have decreased the 6+ hours spent daily in 1900 by women on food-related activities(Reference Arnquist and Roberts132, Reference Leeds133). Almost half of the respondents in a Euromonitor survey said that they do not cook from scratch because of lack of time(134). A 2018 survey of US households showed that only 28% of meals are prepared from scratch(Reference Watrous135). These data suggest that the operationalising NOVA would be difficult for many.
Cost of home-prepared foods from MPFn may not be lower, especially when time is considered(Reference Yang, Davis and Muth136). For example, the price of US packaged bread is about $2 (600 g, ten servings) and lasts up to 5–10 days; classic French baguette, about $5·00 (360 g, five–six servings) and lasts 1–2 days; and ingredients homemade bread, about $1–1·50 (450 g and, at $17/hour, the loaf costs over $8·00) and lasts 2–5 days depending on the ingredients. If most foods were prepared using PCI and MPFn, the time (and cost of time) dedicated to food procurement, preparation and cleaning would be significant.
Dietary recommendations must be affordable for all socioeconomic levels. Calls to avoid PFn/UPFn may adversely impact food selection, especially for lower-income consumers(Reference Mendoza Velázquez137). Studies show that the cost of fresh produce can inhibit the selection of fruit and vegetables(Reference Mulik and Haynes-Maslow138–Reference Mackenbach, Burgoine and Lakerveld143). The United States Department of Agriculture has designed nutritionally-balanced menus made primarily with PF/ UPF for consumers with limited refrigeration, cooking facilities, time and money(Reference Duyff77, 144).
Safety
Techniques and equipment for safe food handling are required to use MPFn, especially as many outbreaks are linked to these foods(Reference Evans and Redmond145–149). PFn and MPFn (without additives and preservatives) may not only have shorter shelf lives but also may pose a greater risk because ‘hurdle’ technologies and additives that inhibit microbial growth and maintain safety are not used(Reference Singh and Shalini150).
Infant formulas are designated as UPFn. While breastfeeding is optimal, safe options are needed where this is not possible. Home-prepared formulas not only carry risks of nutritional imbalances, they have documented food safety risks(Reference Reece151, 152).
Is NOVA adaptable for the long term?
Long-term food availability must address many issues including food waste. Food processing in developing countries has reduced losses by nearly 50%. Commercial processors have channels for waste not available to consumers(Reference Segovia Gómez and Almajano Pablos153, Reference Mattos, Tonon and Furtado154). Studies in Europe document lower food waste with frozen foods than fresh or ambient equivalents.(Reference Xu, Sun and Zeng62, Reference Martindale63).
Additives and ingredients, such as fat or sugar, extend shelf life and potentially decrease food cost and waste. Thus, diets constructed primarily of PCI and MPFn may not be the best ways to address food supply issues.
Will use of NOVA result in better diet quality?
No studies show that consumers can use NOVA to match energy intake with energy needs and can replace foods with added sugar and fat with those that are recommended. Modelling studies replacing current products with those reformulated to meet lowered sugar and other values showed the only meaningful reduction in added sugars occurred if sugar-sweetened beverage consumption decreased(Reference Mendoza, Tolentino-Mayo and Hernández-Barrera155). Advice to decrease consumption of nutrient-poor foods,(Reference Bailey, Fulgoni and Cowan156) rather than foods labelled as PFn/UPFn, may be clearer and have fewer unintended consequences.
Studies are needed demonstrating that home-prepared foods from MPFn and PCI will improve diets and lower energy intake. Recipes from popular UK cooking programmes were shown to be neither lower in sugar and energy contributed, nor higher in nutrients than RTE versions from the supermarket.(Reference Howard, Adams and White157) The nutrient contribution of the ingredients mattered, not where and by whom the food is prepared.
Conclusion
Consumers fail to meet recommended intakes for nutrients and food groups(Reference Akseer, Al-Gashm and Mehta158, Reference Pursey, Collins and Stanwell159). Unhealthy diet patterns with excess energy intake, meat, salt, sugar, saturated fat and nutrient- poor foods are common and contribute to obesity and chronic disease(Reference Tapsell, Neale and Satija119, Reference Ronto, Wu and Singh160–Reference Fransen, Beulens and May164).
NOVA proponents suggest that replacement of PFn/UPFn with MPFn will improve diets and decrease disease risks(Reference Fardet, Rock and Bassama165).
NOVA definitions are non-traditional and lack congruence with legal or food science ones. Further, many divergent definitions on the web and popular press could muddle consumer understanding about which foods to avoid as PFn/UPFn. Further, the NOVA categories are different from the IFIC ones. With IFIC, all categories had foods ‘to limit’ and ‘to encourage’. In NOVA foods designated as PFn/UPFn are to be limited despite their nutrient contribution.
Analyses of food intake databases using NOVA do show that diets high in UPFn have lower nutrient density and more added sugars, but studies also show that not all foods in these categories are poor nutritional choices. Studies with the IFIC categorisation suggest that there are nutritious choices from all levels of processing. Diets such as DASH and MyPlate, constructed with the right mix of foods from all categories, can be nutritious.
No studies or β-testing show that consumers can operationalise NOVA's definitions and categories to choose nutrient-rich foods, to eschew foods of low nutritional quality and improve diets and health outcomes. Further, there are significant concerns about NOVA's actionability and practicality for various lifestyles, skill sets and resource availability. Studies comparing NOVA implementation with vetted plans such as DASH or MyPLATE are needed to show that nutrient intakes and health outcomes are at least equivalent to those from plans that promote the right balance of foods from all levels of processing(2, Reference Panagiotakos, Notara and Kouvari72–Reference Gay, Rao and Vaccarino76, Reference Maddock, Ziauddeen and Ambrosini166–Reference Wang, Heianza and Sun169).
Acknowledgements
The concept and much background for the present paper resulted from work of the Ad Hoc Joint Food and Nutrition Science Solutions Task Force (Task Force) [2006–2016], representing the Academy of Nutrition and Dietetics, American Society for Nutrition (ASN), Institute of Food Technologists (IFT), and International Food Information Council (IFIC). The author would like to take this opportunity to thank 2015–2016 members of the Task Force, who helped with the manuscript: Mildred M. Cody, Roger Clemens, Janet Collins, Silvia Dumitrescu, Johanna T. Dwyer, Mary Christ-Erwin, Guy Johnson, Gil Leveille, Barbara Ivens, Catherine Metzgar Lo, Farida Mohamedshah, Sarah Ohlhorst, Robert C. Post, and Katherine Wilkes. While the Task Force was made up of members of the Academy IFT, ASN or IFIC, the present paper may not reflect the positions of those organisations.
Financial Support
The staff from the Academy of Nutrition and Dietetics, ASN, IFT and IFIC assisted with the planning and facilitation of the conference calls and with the review and editing of the manuscript. No specific grant from any funding agency, commercial or not-for-profit sectors was received for the development of this manuscript.
Conflicts of Interest
Julie Miller Jones is a scientific advisor to the Grains Food Foundation, The Healthy Grains Institute (Canada), Quaker Oats Advisory Board, and the Campbell Soup Company Plant and Health Advisory Board. She has written papers of given speeches for Centro Internacional de Mejoramiento de Maíz y Trigo CIMMYT (International Maize and Wheat Improvement Center, Mexico), Cranberry Institute, and Tate and Lyle.
Authorship
The author had sole responsibility for all aspects of preparation of this paper.
