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Emulsifiers in ultra-processed foods in the UK food supply

Published online by Cambridge University Press:  21 September 2023

Alicia Sandall ,
Leanne Smith ,
Erika Svensen  and
Kevin Whelan Open the ORCID record for Kevin Whelan [Opens in a new window]
Alicia Sandall
Affiliation:
King’s College London, Department of Nutritional Sciences, Franklin Wilkins Building, London, SE1 9NH, UK
Leanne Smith
Affiliation:
King’s College London, Department of Nutritional Sciences, Franklin Wilkins Building, London, SE1 9NH, UK
Erika Svensen
Affiliation:
King’s College London, Department of Nutritional Sciences, Franklin Wilkins Building, London, SE1 9NH, UK
Kevin Whelan*
Affiliation:
King’s College London, Department of Nutritional Sciences, Franklin Wilkins Building, London, SE1 9NH, UK
*
*Corresponding author: Email kevin.whelan@kcl.ac.uk
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Abstract

Objective:

Ultra-processed foods (UPF), including those containing food additive emulsifiers, have received research attention due to evidence implicating them in the pathogenesis of certain diseases. The aims of this research were to develop a large-scale, brand-level database of UPF in the UK food supply and to characterise the occurrence and co-occurrence of food additive emulsifiers.

Design:

A database was compiled sampling all products from the food categories contributing to energy intake from UPF in the UK from the National Diet and Nutrition Survey (2008–2014). Every food in these categories were identified from online supermarket provision from the ‘big four’ supermarkets that dominate the market share in the UK, comprising Tesco, Sainsbury’s, Asda and Morrisons.

Setting:

Major supermarkets in the UK.

Results:

A total of 32 719 food products in the UK supermarket food supply were returned in searches. Of these, 12 844 products were eligible and manually reviewed for the presence of emulsifiers. Emulsifiers were present in 6642 (51·7 %) food products. Emulsifiers were contained in 95·0 % of ‘Pastries, buns and cakes’, 81·9 % of ‘Milk-based drinks’, 81·0 % of ‘Industrial desserts’ and 77·5 % of ‘Confectionary’. Fifty-one per cent of all emulsifier-containing foods contained multiple emulsifiers. Across emulsifier-containing foods, there were a median of two emulsifiers (IQR 2) per product. The five most common emulsifiers were lecithin (23·4 % of all products), mono- and diglycerides of fatty acids (14·5 %), diphosphates (11·6 %), and xanthan gum and pectin (8·0 %).

Conclusions:

Findings from this study are the first to demonstrate the widespread occurrence and co-occurrence of emulsifiers in UPF in the UK food supply.

Keywords

Ultra-processed foodFood additiveEmulsifierFood database
Type
Research Paper
Information
Public Health Nutrition , Volume 26 , Issue 11 , November 2023 , pp. 2256 - 2270
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Food additives are substances that are not normally consumed as food itself but added to food intentionally for a technological purpose(1). Since the 1950s, ready-to-eat, convenience packaged products containing food additives have become more prominent in the food supply(Reference Monteiro, Cannon and Lawrence2).

Ultra-processed foods (UPF) are a group of foods defined based on the extent and purpose of processing as part of the NOVA classification system adopted by the FAO of the UN(Reference Monteiro, Cannon and Lawrence2). The NOVA classification defines UPF as those whose constituent ingredients are of exclusive industrial use, usually created by a sequence of processing techniques only available in industry(Reference Monteiro, Cannon and Lawrence2).

Dietary surveys have demonstrated that UPF contribute to 16 %–58 % of total energy intake(Reference Martini, Godos and Bonaccio3). In the UK, UPF contribute to over half the average UK daily adult energy intake(Reference Rauber, da Costa Louzada and Steele4). In Europe, household purchasing of UPF is highest in the UK, contributing 50·4 % of household foods(Reference Monteiro, Moubarac and Levy5). This significant share of UPF to supply and intake demonstrates how ubiquitous this food class is in the UK diet, a pattern observed in other high-income countries, such as the USA(Reference Baraldi, Steele and Canella6), Canada(Reference Moubarac, Batal and Louzada7) and Australia(Reference Machado, Steele and Levy8). UPF represent 83 % of packaged supermarket foods in New Zealand(Reference Luiten, Steenhuis and Eyles9), and 67 % in France(Reference Davidou, Christodoulou and Fardet10).

UPF have received extensive recent research attention due to epidemiological evidence of associations with disease. For example, prospective cohort studies have associated increased UPF consumption with overweight and obesity(Reference Moradi, Entezari and Mohammadi11), hypertension(Reference Wang, Du and Huang12), cancer(Reference Isaksen and Dankel13), Crohn’s disease(Reference Narula, Chang and Mohammad14) and all-cause mortality(Reference Taneri, Wehrli and Roa-Díaz15). Some UPF contain high amounts of added fat, sugar and/or salt(Reference Daniela Neri, Monteiro and Levy16,Reference Weaver, Dwyer and Fulgoni17) in addition to food additives, all of which are being mechanistically implicated in the aetiology of some of these disorders(Reference Srour, Kordahi and Bonazzi18).

Emulsifiers are a family of food additives present in a wide range of UPF, including industrial sliced bread, bakery foods, ready-made sauces, chocolate, confectionary and processed dairy foods(Reference Cox, Sandall and Smith19). Emulsifiers form or stabilise a uniform emulsion of two or more phases in a food(Reference Cox, Sandall and Smith19). For example, they can be used to maintain a uniform consistency in fat-containing foods that would otherwise form an unappetising separation of oil and water. However, recent evidence has implicated food additive emulsifiers in disease pathogenesis of metabolic syndrome(Reference Srour, Kordahi and Bonazzi18) and inflammatory bowel disease (IBD)(Reference Bancil, Sandall and Rossi20). In murine models, emulsifiers modify the luminal and mucosal microbiome and increase intestinal and chronic low-grade systemic inflammation(Reference Chassaing, Koren and Goodrich21Reference De Siena, Raoul and Costantini23).

Measuring the presence of emulsifiers in the food supply is important as population exposure patterns are crucial to understanding potential deleterious health effects of emulsifiers. Depending on the body responsible for legislating food additives, there are between 63 and 261 emulsifiers added to foods throughout the world, with sixty-six in the UK as defined by both the Codex Alimentarius and the Joint FAO and WHO Expert Committee on Food Additives(Reference Cox, Sandall and Smith19). However, there is a paucity of research regarding the foods in which emulsifiers are contained, and so the occurrence of food additive emulsifiers in the UK food supply is unknown(Reference Halmos, Mack and Gibson24), in part due to the absence of a database of emulsifier content of foods that lists all UPF and details all different types of emulsifiers. Such a database would enable analysis of food additive emulsifier occurrence in the food supply and enable measurement of the frequency of emulsifier exposure in dietary surveys and clinical trials.

The aims of this research were to develop a large-scale, brand-level database of UPF in the UK food supply and to characterise the occurrence and co-occurrence of food additive emulsifiers.

Methods

This study involved the development of a database of the majority of UPF in the UK food supply, and then extraction of data on the presence and type of emulsifier from manual review of all ingredients labels.

Eligibility of foods

Eligibility criteria for foods were developed a priori using the FAO definition of UPF and National Diet and Nutrition Survey descriptors(Reference Monteiro, Cannon and Lawrence2,25) (Table 1).

Table 1 Search terms and eligibility criteria for the fifteen top consumed ultra-processed food (UPF) categories in the UK. Adapted using the FAO descriptors of ultra-processed foods and National Diet and Nutrition Survey descriptors

Food categories are the top fifteen that contribute to UPF intake in the UK based on National Diet and Nutrition Survey data(Reference Rauber, da Costa Louzada and Steele4). The search terms and eligibility are adapted from FAO descriptors of UPF(Reference Monteiro, Cannon and Lawrence2) and the National Diet and Nutrition Survey categories(25).

A database was compiled of all products in the food categories that contributed to UPF intake from the National Diet and Nutrition Survey (2008–2014)(Reference Rauber, da Costa Louzada and Steele4). The top fifteen food categories contributing to energy intake from UPF in the UK were as follows: industrialised packaged breads (11·01 % of total energy intake); packaged pre-prepared meals (7·77 %); breakfast cereals (4·36 %); sausage and other reconstituted meat products (3·84 %); confectionery (3·55 %); biscuits (3·46 %); pastries, buns and cakes (3·26 %); industrial chips (French fries) (2·79 %); soft and fruit drinks (2·49 %); milk-based drinks (2·23 %); margarine and other spreads (2·19 %); sauces, dressings and gravies (2·11 %); packaged salty snacks (2·02 %); industrial pizza (1·84 %); and industrial desserts (0·87 %)(Reference Rauber, da Costa Louzada and Steele4). Thus, the database consisted of all foods in these categories that are known to contribute 53·79 % of mean adult energy intake in the UK(Reference Rauber, da Costa Louzada and Steele4).

Search strategy

Every food item in these top fifteen categories contributing to UPF intake were identified from an online search of supermarkets. The supermarket websites of the ‘big four’ supermarkets that dominate the market share in the UK were reviewed, comprising Tesco (26·9 % market share), Sainsbury’s (14·9 %), Asda (13·9 %) and Morrisons (10·1 %) (data in the 12 weeks ending 14/06/2020 when the supermarket sample was selected)(26).

A search term for each food category was devised (Table 1). As online supermarkets organise products into hierarchical ontologies, the search terms were chosen at the highest level in order to maximally widen the search (e.g. ‘bread’ would capture white loaf, tortilla, wraps, ciabatta, etc). Where food categories had broad descriptors (e.g. confectionary), numerous search terms were selected (e.g. sweets and chocolate) to maximise identification of individual food items(25).

The search terms were used in the websites of the four supermarkets to retrieve all food products in the UK food supply in that category. The supermarket search was conducted in Google Chrome used in ‘incognito mode’ to minimise the influence of previous browsing history on retrieval of food brands from the search results(Reference Satvat, Forshaw and Hao27). Searches were conducted over a 6-month period (June 2020–November 2020) and was performed by a team of three research dietitians.

Data extraction for emulsifier content

All retrieved food products from each supermarket search were transferred into the database ready for de-duplication, eligibility screening and data extraction.

Identical food products were identified, and duplicates discounted from the analysis (e.g. four identical brands of tomato ketchup in identical portion size, one from each of the supermarkets). Differing portion sizes of the same food products were not excluded on the basis of duplication (given the individual products remained representative of different products available in the food supply). After discounting duplicates, each food product was assessed for eligibility based on inclusion criteria (Table 1).

In the final count of eligible food products, the ingredients labels were extracted from supermarket database and manually reviewed for the presence of food additive emulsifiers, and the details extracted. The list of sixty-six food additives classified as emulsifiers was based on both JECFA and Codex Alimentarius classifications and have been published elsewhere(Reference Cox, Sandall and Smith19), a list of which are provided for reference in Supplemental Table 1, including the International Numbering System code (‘E number’) and full name of the food additive emulsifier.

Thus, the final database contained the following extracted data: food item brand name; food category (e.g. industrialised breads); search term under which it was identified, eligibility (yes/no); ingredients list for eligible food items; and emulsifier details (presence/absence, which emulsifiers, total number of emulsifiers).

De-duplication, eligibility screening and data extraction were performed by the same team of three research dietitians. In order to ensure consistency of data extraction, the lead dietitian (PhD in emulsifiers and the gut) trained the team on the process and regularly reviewed data extraction in the early stages until the other team members developed independence. Following full data extraction, database checking was performed on twenty randomly selected food items from each of the fifteen food categories (300 food items in total). Of the 300 random food items checked, there were no errors or disputes in de-duplication, eligibility screening or data extraction for emulsifiers.

Statistical analysis

Frequency of emulsifiers are presented as median and interquartile range (IQR) due to non-normal distribution, and the number of emulsifiers in food products across UPF categories were compared using a Kruskal–Wallis test. Categorical data are presented as n (%) and were compared across UPF groups using Chi-square tests. Emulsifier co-occurrence was investigated using Spearman’s rank correlation and presented as a heat map. For all statistical tests, a P-value of <0·05 was considered statistically significant.

Results

Supermarket food product sample

A total of 32 719 food products were returned in searches. Of these, 9921 food products were excluded based on duplication and a further 9954 excluded based on ineligibility (Fig. 1). Therefore, the ingredients of 12 844 food products (both foods and beverages) in the UK supermarket food supply were manually reviewed for the presence of food additive emulsifiers.

Fig. 1 Flow diagram of food product inclusion

Occurrence of emulsifiers

Overall, food additive emulsifiers were present in 6642 (51·7 %) of the 12 844 foods reviewed (Table 2).

Table 2 Occurrence of food additive emulsifiers by ultra-processed food (UPF) category in the UK food supply

Ultra-processed foods are defined as detailed by Rauber et al. (2018) according to the FAO NOVA definitions(Reference Rauber, da Costa Louzada and Steele4). Emulsifiers are identified by E-number (the Codex Alimentarius International Numbering System number, prefixed by the letter ‘E’)(49). Number of emulsifiers per food product (median, IQR) was assessed for significance between UPF categories using a Kruskal–Wallis test. Proportions of food products containing emulsifiers between UPF categories was assessed using Chi-square tests for independence.

The five most common emulsifiers across all products were lecithin (E322) (23·4 % of all UPF), mono- and diglycerides of fatty acids (E471) (14·5 %), diphosphates (E450) (11·6 %), xanthan gum (8·2 %) and pectin (E440) (8·0 %) (Table 2).

From the sixty-six food additive emulsifiers approved for use in the EU, fifty-one were identified in the products reviewed. Due to foods containing multiple emulsifiers (Table 2), there were 14 300 occurrences of emulsifiers across 6642 emulsifier-containing foods. Patterns of occurrence of individual emulsifiers are shown in Table 3.

Table 3 Occurrence of individual emulsifiers across ultra-processed food categories in the UK food supply

Emulsifiers are identified by their E-number (the Codex Alimentarius International Numbering System number, prefixed by the letter ‘E’)(49) and the number of food products containing that emulsifier are reported for each of the top fifteen UPF categories contributing to energy intake in the UK(Reference Rauber, da Costa Louzada and Steele4).

Of the emulsifiers with most research on their impact on the gastrointestinal tract, carrageenan was present in 565 foods (4·4 %), E466 in 179 foods (1·4 %) and polysorbate-80 in eight foods (0·06 %).

Occurrence of emulsifiers by food category

Overall, 51·7 % of the foods contained food additive emulsifiers; however, there was wide variation and statistically significant differences between UPF categories (P < 0·001). For example, emulsifiers were contained in 95·0 % of ‘Pastries, buns and cakes’, 81·9 % of ‘Milk-based drinks’, 81·0 % of ‘Industrial desserts’ and 77·5 % of ‘Confectionary’. In contrast, they were contained in only 11·6 % of ‘Packaged salty snacks’ (Table 2).

The type of emulsifier was also highly variable across food categories, for example, carrageenan (E407) was the most common emulsifier in ‘Milk-based drinks’ (63·1 % of products) and was only present in 4·9 % of ‘Sausage and other reconstituted meat products’ (Table 2). Carboxymethylcellulose (E466) was present in 40·0 % of ‘Milk-based drinks’ and only 3·0 % of ‘Soft drinks, fruit drinks and fruit juices’ (Table 2). Polysorbate-80 was only identified in eight foods (Table 3) from varying food categories.

Frequency of emulsifiers in each food

Across all 6642 foods that contained an emulsifier, there were a median of two emulsifiers (IQR 2) per product (Table 2). Fifty-one per cent of emulsifier-containing foods contained multiple emulsifiers, but this pattern of co-occurrence varied between food categories (P < 0·001) (Table 2). For example, emulsifier-containing ‘Pastries, buns and cakes’ had a median of four emulsifiers (IQR 3) per product, and ‘industrialised packaged breads’, ‘biscuits’ and ‘milk-based drinks’ had a median of two emulsifiers per product. Of all emulsifier-containing foods, 11·3 % contained at least two emulsifiers, 6·1 % three, 4·1 % four and 4·8 % five or more emulsifiers (Fig. 2).

Fig. 2 Number of individual emulsifiers per food product

Co-occurrence of emulsifiers in foods

There were a number of statistically significant positive correlations (Spearman’s rank) between emulsifier co-occurrence in foods indicating common use of the two emulsifiers together in a food product (Fig. 3). There were strong positive correlations between the presence of polysorbate-60 (E435) and sorbitan monostearate (E491) (rho = 0·70, P < 0·001) and between carob bean gum (E410) and guar gum (E412) (rho = 0·54, P < 0·001). There were moderate positive correlations between the presence of ammonium salts of phosphatidic acid (E442) and polyglycerol esters of interesterified ricinoleic acid (E476) (rho = 0·46, P < 0·001); sodium lactylates (E481) and tragacanth gum (E413) (rho = 0·32, P < 0·001); microcrystalline cellulose and powdered cellulose (E460) and carboxymethyl cellulose (E466) (rho = 0·47, P < 0·001); and E471 and E475 (rho = 0·31, P < 0·001).

Fig. 3 Heat map displaying co-occurrence of individual food additive emulsifiers in the UK food supply. Values are Spearman’s rho correlation coefficients, and cell shading indicates the magnitude of correlation co-occurrence between emulsifiers. The degree of green shading indicates positive correlations, and red shading denotes negative correlations

There were a small number of statistically significant negative correlations between emulsifier co-occurrence, although in general these were weakly correlated (Fig. 3), for example, lecithin (E322) and xanthan gum (E415) (rho = −0·22, P < 0·001), indicating that the presence of one was associated with less use of the other.

Discussion

This paper demonstrates the ubiquity of food additive emulsifiers across foods contributing to UPF intake in the UK food supply. Over half of foods in these UPF categories contained emulsifiers, being most commonly found in industrial desserts, milk-based drinks and confectionary, pastries and cakes. The most common emulsifiers were lecithin, mono- and diglycerides of fatty acids, diphosphates, xanthan gum and pectin; however, variations in emulsifier type occurred across food categories. Half of all emulsifier-containing foods contained more than one emulsifier, with two foods containing eleven emulsifiers.

Comparing the findings of the present study with previous literature is challenging as minimal data are available on the occurrence of emulsifiers in foods at the brand level. Studies attempt to measure either emulsifier intakes in population groups or emulsifier content in the food supply (as in the current study).

In terms of measuring emulsifier intakes, Shah et al., (2017) estimated population exposure to seven common emulsifiers in the USA (carboxymethycellulose (E466), polysorbate-80 (E433), lecithin (E322), mono- and diglycerides of fatty acids (E471), sodium lactylates (E481), sucrose esters of fatty acids (E473) and polyglycerol esters of interesterified ricinoleic acid (E476)(Reference Shah, Kolanos and DiNovi28). They combined national dietary survey data, including the 2003–2010 National Health and Nutrition Examination Survey (NHANES) (2-d dietary intake) and assumed all food categories contained the US Maximum Permitted Levels of each emulsifier(Reference Shah, Kolanos and DiNovi28). Lecithin (55 mg/kg bw/d) and mono- and diglycerides of fatty acids (80 mg/kg bw/d) had the highest mean exposure, whereas exposure to carboxymethycellulose (27 mg/kg bw/d) and polysorbate-80 (8 mg/kg bw/d) was relatively low. Whilst a very different methodological approach was used to estimate emulsifier exposure by Shah et al., (2017) (individual dietary intake data) compared to the present study (occurrence in the food supply), it mirrors the findings reported here that lecithin and mono- and diglycerides of fatty acids are more common than polysorbate-80 or carboxymethycellulose.

Other studies have measured emulsifiers in the food supply, similar to the current study. The United States Department of Agriculture Global Branded Food Products Database (241 688 food products) has been used to investigate patterns of food additive content across baked goods, reporting emulsifiers being present in 91 % of cookies, 94 % of crackers, 95 % of bread and rolls and 100 % of pastry and doughnuts(Reference Ahuja, Li and Bahadur29). Lecithin accounted for about 44–45 % of the total counts of emulsifiers listed in cookies and crackers, whereas gums such as xanthan, guar, and agar account for about 18 % of the listed emulsifiers in pastries. Whilst that study only measured food additives in one food group, it concurs with the findings presented here that emulsifiers are ubiquitous in baked goods. A database study in France using The Open Food Facts Database (126 566 food products) found that emulsifiers/thickeners were one of the most frequently used food additives, compared with antioxidants, dyes, preservatives and sweeteners(Reference Chazelas, Deschasaux and Srour30), with the most commonly present emulsifiers being lecithin (second most common food additive), xanthan gum (sixth), diphosphates (eighth), pectins (ninth) and mono- and diglycerides of fatty acids (tenth), which were identical to the five most common emulsifiers in the present study. In addition, carrageenan was common in the French food supply (thirteenth most common food additive, in 4·2 % of foods) and is similar to that in the current study (4·4 % of foods)(Reference Chazelas, Deschasaux and Srour30). Other studies have examined the presence of emulsifiers in food supply, although not at the level of individual emulsifiers as in the current study. A review of 24 229 foods in Australia reported emulsifiers to be the seventh most common ingredient being present in 15·6 % of all foods(Reference Gaines, Shahid and Huang31), whilst a study of 9856 foods in Brazil reported emulsifiers to be the sixth most common food additive being present in 19·4 % of all foods(Reference Montera, Martins and Borges32). Both of these values are lower than that reported here (51·7 %), although in the current study only foods contributing to UPF intake were selected and therefore our value is inevitably higher.

The emulsifiers implicated in gastrointestinal inflammation, carrageenan (4·4 % of foods), carboxymethycellulose (1·4 %) and polysorbate-80 (0·06 %) were not overall very common in the UK food supply. However, carrageenan and carboxymethylcelluose, which form a viscous solution in the aqueous phase creating a stable water-fat emulsion for a creamy mouthfeel(Reference Blakemore, Harpel and Imeson33,Reference Murray, Phillips and Williams34) , were therefore contained in 63·1 % (carrageenan) and 40·0 % (carboxymethylcellulose) of all milk-based drinks. Thus, whilst these additives are not ubiquitous in the food supply, people consuming high levels of foods from these specific categories may be disproportionately exposed. A recent human study reported that carboxymethylcelluose reduced microbial diversity(Reference Chassaing, Compher and Bonhomme35); meanwhile, several prospective cohort studies report that higher intakes of UPF are associated with an increased risk of IBD(Reference Narula, Chang and Mohammad14,Reference Chen, Wellens and Kalla36,Reference Lo, Khandpur and Rossato37) . Interestingly, different UPF categories, including soft drinks, refined sweetened foods, salty snacks and processed meat, were each independently associated with increased risk of IBD, suggesting that perhaps certain processing or food additives commonly found in these categories (such as the aforementioned emulsifiers) could theoretically be contributing to the development of IBD(Reference Narula, Chang and Mohammad14).

Polysorbate-80 was rarely identified in food products in the present study. This could explain why the European Food Safety Authority (EFSA) estimates of mean intakes of polysorbates across Europe (0·6–16·9 mg/kg bw/d)(38) are lower than that of carrageenan (22·0–88·9 mg/kg bw/d)(39) and the modified celluloses (20–67 mg/kg bw/d)(40).

This is the first study to demonstrate that UPF in the UK commonly contain multiple emulsifiers. Yet, whether emulsifiers have synergistic effects on gastrointestinal inflammation is not known, as previous murine and ex vivo studies tested individual emulsifiers in isolation(Reference Chassaing, Koren and Goodrich21,Reference Chassaing, Van de Wiele and De Bodt22,Reference Sandall, Cox and Lindsay41) . Whilst half of all emulsifier-containing foods contained multiple emulsifiers, there were few strong patterns of co-occurrence. Co-occurrence of food additives is common across UPF. A third of foods in the United States Department of Agriculture Global Branded Food Products Database contain at least three additives(Reference Tseng, Grigsby and Austin42). The French-based Open Food Facts Database found that 11·6 % of food products contained at least two additives, 7·8 % three, 5·3 % four and 11·3 % five or more food additives(Reference Chazelas, Deschasaux and Srour30). This is similar to the present study, which found that 11·3 % of foods contained at least two emulsifiers, 6·1 % three, 4·1 % four and 4·8 % five or more emulsifiers. Of course, foods are often eaten together during a single meal, resulting in higher numbers, quantities and combinations of emulsifiers potentially being consumed within a single eating occasion. The NutriNet Santé cohort was used to identify six clusters of food additive consumption based on foods commonly consumed together (e.g. additives found in breakfast cereals, pastries and dairy desserts)(Reference Chazelas, Druesne-Pecollo and Esseddik43), emphasising that foods containing emulsifiers and other food additives are often eaten together and therefore exposure will depend not only on food supply but also on food preference, choice and meal pattern.

Fifteen food additives classified as emulsifiers were not present in the sample of foods. This could be due to a number of reasons. Firstly, it could be that these emulsifiers are used in foods categories not in the top fifteen most highly consumed UPF categories, although this would still result in low exposure. Secondly, it could be that food industry is reducing its use of certain emulsifiers. For example, soyabean hemicellulose (E426) which was not present in any food products in this study may be used less frequently, since soya allergy has become better understood and reported(Reference Jędrusek-Golińska, Piasecka-Kwiatkowska and Zielińska44). Another example is alginic acid (E400), a gel forming additive, that has been identified as a choking hazard in jelly confectionary owing to its semi-rigid consistency, and so its use in foods has been limited by the EU(1).

This study was the first to explore the occurrence of all food additive emulsifiers in a large sample of foods in the UK food supply. The EFSA attempts to estimate population exposure to food additives in the EU, but current estimates use the rudimentary approach of assuming that all food categories that are permitted to contain emulsifiers will contain emulsifiers(Reference Cox, Sandall and Smith19). Whereas brand-level data with actual emulsifier occurrence would increase the external validity of population exposure estimates when combined with national dietary surveys, providing the surveys also record food intake at the brand level.

Emulsifier occurrence in this sample of 12 844 foods was considerable. This is significant because more than half of all foods in UK households are ultra-processed5, and these foods contribute to more than half of the UK energy intake(Reference Rauber, da Costa Louzada and Steele4). If the deleterious effects of emulsifiers observed in animal models are confirmed in humans, and the present study has highlighted the ubiquity of emulsifiers in the food supply, then food formulations would require significant changes. This study is the first to confirm the widespread occurrence of food additive emulsifiers in the UK food supply and therefore the likely challenge of restricting dietary intakes of emulsifiers as part of ongoing therapeutic dietary interventions, for example, for metabolic syndrome(Reference De Siena, Raoul and Costantini23) or IBD(Reference Bancil, Sandall and Rossi20). Most concerningly, availability of UPF in middle-income countries are growing rapidly. Sales of UPF in South-East Asia and the East are expected to match those of high-income countries by 2035(45).

Strengths, limitations and future research

This is the first study to report the occurrence of emulsifiers in the UK food supply. It surveyed a large number of foods (12 844) contributing to UPF intake, larger than some previous studies in other countries(Reference Ahuja, Li and Bahadur29,Reference Montera, Martins and Borges32) , although smaller than others that used pre-established databases(Reference Chazelas, Deschasaux and Srour30,Reference Gaines, Shahid and Huang31) . Occurrence of total and individual emulsifiers was reported here, whereas some previous studies report only the occurrence of ‘total emulsifiers’(Reference Ahuja, Li and Bahadur29,Reference Gaines, Shahid and Huang31,Reference Montera, Martins and Borges32) , which is important as there is escalating evidence of differential impacts of individual emulsifiers on gut health(Reference Sandall, Cox and Lindsay41,Reference Naimi, Viennois and Gewirtz46) .

A number of limitations of this study must be considered, and these mostly pertain to the UPF category sampling method.

Firstly, this study only sampled the top fifteen food categories, of the sixteen possible, that contribute to energy intake from UPF in the UK(Reference Rauber, da Costa Louzada and Steele4). Therefore, it is likely other foods not sampled here represent further sources of emulsifiers in the UK food supply. The only UPF category not sampled, the sixteenth and final, was ‘Miscellaneous foods’(Reference Rauber, da Costa Louzada and Steele4). This was because it would be challenging to search, identify and correctly categorise brand-level food items to a ‘miscellaneous’ category using supermarket websites. In addition, potentially eligible UPF in other categories were not searched. However, the top fifteen UPF categories sampled collectively contribute to 53·8 % of mean adult energy intake, and the remaining unaccounted miscellaneous category contribute only an additional 3·08 % to energy intake(Reference Rauber, da Costa Louzada and Steele4).

Secondly, food items from only four supermarkets were analysed, and this does not represent the full range of food product availability. However, these ‘big four’ supermarkets collectively dominate the UK food supply, owning the total market share of 65·8 %(26). Similarly, foods from restaurants or takeaways were not included in the analysis, and foods from these outlets may contain emulsifiers.

Thirdly, there is a risk the search terms did not retrieve all relevant foods, and so some foods in these fifteen UPF categories may have been missed. To minimise this, search terms were intentionally broad and inclusive in order to maximise the retrieval of results. Where it was perceived that a single search term would not be a catch-all term for a food group, multiple search terms for that food category were created a priori (Table 1).

Alternative data collection methodologies were considered that did not pose these three limitations in sampling approach. One option was to obtain the sample from market research data on the best-selling UPF products, as adopted to estimate phosphorus-based additives in the Australian food supply(Reference McCutcheon, Campbell and Ferguson47) or using supermarket loyalty card data of food purchasing habits, as used to estimate protein intake in older adults in the UK(Reference Green, Watson and Brunstrom48). The benefit of obtaining commercial data on UPF sales is that food products with a high population exposure are better captured in the sample frame. However, data on brand-level food sales was prohibitively costly, and this approach would not achieve the aim of this study, which related to measuring emulsifier occurrence in all foods contributing to UPF intake in the UK food supply.

Data were collected in the second half of 2020, just after the UK left the European Union (31 January 2020) but during the COVID-19 pandemic. Therefore, although the data collection period was entirely post-Brexit, its proximity to Brexit and to a global pandemic may mean that food supply measured at that time may have subsequently changed. Importantly, we surveyed four major supermarkets online (not in store) to minimise any supermarket-specific or localised food supply issues.

Future research may consider the nutrient composition, availability, and cost of emulsifier-free and emulsifier-containing foods to understand potential nutritional and economic impacts of consuming UPF-containing emulsifiers. In addition, the database can be used in future to identify other food additives in the UK food supply, and techniques that adopt algorithmic approaches to identifying these, rather than manual data extraction, could expedite this process.

Conclusion

Findings from this study demonstrate the widespread occurrence of food additive emulsifiers in the UK supermarket food supply. Emulsifiers are present in 51·7 % of foods from UPF categories, the most common being lecithin, diphosphates and mono- and diglycerides of fatty acids. This is the first study to demonstrate that UPF in the UK commonly contain multiple emulsifiers, with 26·4 % containing two or more emulsifiers. The three emulsifiers of interest in gastrointestinal inflammation are present in relatively small numbers of UPF; however, 63·1 % and 40·0 % of milk-based drinks contained carrageenan and carboxymethylcelluose, respectively.

Acknowledgements

None.

Financial support

Authors were supported by a grant from The Leona M. and Harry B. Helmsley Charitable Trust. The funder had no role in the design, performance or approval of this research.

Conflicts of interest

KW is the co-inventor of a volatile organic compounds in the diagnosis and dietary management of irritable bowel syndrome. KW is in receipt of research funding from Almond Board of California, Danone, International Dried Fruit and Nut Council. All authors were funded or part-funded by the Helmsley Charitable Trust.

Authorship

A.S. and K.W. developed the rationale and aims of the research and designed the study. A.S., L.S. and E.S. reviewed supermarket databases and extracted ingredient data. A.S. and K.W. analysed and interpreted the data. A.S. and K.W. wrote the manuscript. All authors reviewed and approved the final version of this manuscript.

Ethics of human subject participation

Not applicable.

Supplementary material

For supplementary material accompanying this paper visit https://doi.org/10.1017/S1368980023002021

References

European Commission (2008) Regulation No 1333/2008/EC of the European Parliament and of the Council of 16 December 2008 on Food Additives. Official J Eur Union 51, 16–33.Google Scholar
Monteiro, CA, Cannon, G, Lawrence, M et al. (2019) Ultra-Processed Foods, Diet Quality, and Health Using the NOVA Classification System. Rome: Food and Agriculture Organization of the United Nations.Google Scholar
Martini, D, Godos, J, Bonaccio, M et al. (2021) Ultra-processed foods and nutritional dietary profile: a meta-analysis of nationally representative samples. Nutrients 13, 3390.CrossRefGoogle ScholarPubMed
Rauber, F, da Costa Louzada, ML, Steele, EM et al. (2018) Ultra-processed food consumption and chronic non-communicable diseases-related dietary nutrient profile in the UK (2008–2014). Nutrients 10, 587.CrossRefGoogle ScholarPubMed
Monteiro, CA, Moubarac, JC, Levy, RB et al. (2018) Household availability of ultra-processed foods and obesity in nineteen European countries. Public Health Nutr 21, 1826.CrossRefGoogle ScholarPubMed
Baraldi, LG, Steele, EM, Canella, DS et al. (2018) Consumption of ultra-processed foods and associated sociodemographic factors in the USA between 2007 and 2012: evidence from a nationally representative cross-sectional study. BMJ Open 8, e020574.CrossRefGoogle ScholarPubMed
Moubarac, JC, Batal, M, Louzada, ML et al. (2017) Consumption of ultra-processed foods predicts diet quality in Canada. Appetite 108, 512520.CrossRefGoogle ScholarPubMed
Machado, PP, Steele, EM, Levy, RB et al. (2019) Ultra-processed foods and recommended intake levels of nutrients linked to noncommunicable diseases in Australia: evidence from a nationally representative cross-sectional study. BMJ Open 9, e029544.CrossRefGoogle ScholarPubMed
Luiten, CM, Steenhuis, IH, Eyles, H et al. (2016) Ultra-processed foods have the worst nutrient profile, yet they are the most available packaged products in a sample of New Zealand supermarkets. Public Health Nutr 19, 530538.CrossRefGoogle Scholar
Davidou, S, Christodoulou, A, Fardet, A et al. (2020) The holistico-reductionist Siga classification according to degree of food processing: an evaluation of ultra-processed foods in French supermarkets. Food Funct 11, 20262039.CrossRefGoogle ScholarPubMed
Moradi, S, Entezari, MH, Mohammadi, H et al. (2023) Ultra-processed food consumption and adult obesity risk: a systematic review and dose-response meta-analysis. Crit Rev Food Sci Nutr 63, 249260.CrossRefGoogle Scholar
Wang, M, Du, X, Huang, W et al. (2022) Ultra-processed foods consumption increases the risk of hypertension in adults: a systematic review and meta-analysis. Am J Hypertens 35, 892901.CrossRefGoogle ScholarPubMed
Isaksen, IM & Dankel, SN (2023) Ultra-processed food consumption and cancer risk: a systematic review and meta-analysis. Clin Nutr 42, 919928.CrossRefGoogle Scholar
Narula, N, Chang, NH, Mohammad, D et al. (2023) Food processing and risk of inflammatory bowel disease: a systematic review and meta-analysis. Clin Gastroenterol Hepatol 2023, 2483.e12495.e1.Google Scholar
Taneri, PE, Wehrli, F, Roa-Díaz, ZM et al. (2022) Association between ultra-processed food intake and all-cause mortality: a systematic review and meta-analysis. Am J Epidemiol 191, 13231335.CrossRefGoogle ScholarPubMed
Daniela Neri, EM-S, Monteiro, CA & Levy, RB (2019) Consumption of ultra-processed foods and its association with added sugar content in the diets of US children, NHANES 2009–2014. Pediatr Obes 14, e12563.CrossRefGoogle Scholar
Weaver, CM, Dwyer, J, Fulgoni, VL et al. (2014) Processed foods: contributions to nutrition. Am J Clin Nutr 99, 15251542.CrossRefGoogle ScholarPubMed
Srour, B, Kordahi, MC, Bonazzi, E et al. (2022) Ultra-processed foods and human health: from epidemiological evidence to mechanistic insights. Lancet Gastroenterol Hepatol 7, 11281140.CrossRefGoogle ScholarPubMed
Cox, S, Sandall, A, Smith, L et al. (2021) Food additive emulsifiers: a review of their role in foods, legislation and classifications, presence in food supply, dietary exposure, and safety assessment. Nutr Rev 79, 726741.CrossRefGoogle ScholarPubMed
Bancil, AS, Sandall, AM, Rossi, M et al. (2021) Food additive emulsifiers and their impact on gut microbiome, permeability, and inflammation: mechanistic insights in inflammatory bowel disease. J Crohns Colitis 15, 10681079.CrossRefGoogle ScholarPubMed
Chassaing, B, Koren, O, Goodrich, JK et al. (2015) Dietary emulsifiers impact the mouse gut microbiota promoting colitis and metabolic syndrome. Nature 519, 9296.CrossRefGoogle ScholarPubMed
Chassaing, B, Van de Wiele, T, De Bodt, J et al. (2017) Dietary emulsifiers directly alter human microbiota composition and gene expression ex vivo potentiating intestinal inflammation. Gut 66, 14141427.CrossRefGoogle ScholarPubMed
De Siena, M, Raoul, P, Costantini, L et al. (2022) Food emulsifiers and metabolic syndrome: the role of the gut microbiota. Foods 11, 2205.CrossRefGoogle ScholarPubMed
Halmos, EP, Mack, A & Gibson, PR (2019) Review article: emulsifiers in the food supply and implications for gastrointestinal disease. Aliment Pharmacol Ther 49, 4150.CrossRefGoogle ScholarPubMed
National Diet and Nutrition Survey (2011) Diet and Nutrition Survey of Infants and Young Children. Appendix M. Main and Subsidiary Food Groups. Medical Research Council Human Nutrition Research. United Kingdom Government. https://www.gov.uk/government/publications/diet-and-nutrition-survey-of-infants-and-young-children-2011 (accessed October 2023).Google Scholar
Kantar (2020) Grocery Market Share UK 12 Weeks Ending. https://www.kantarworldpanel.com/grocery-market-share/great-britain (accessed June 2020).Google Scholar
Satvat, K, Forshaw, M, Hao, F et al. (2014) On the privacy of private browsing – a forensic approach. J Inf Secur Appl 19, 88100.Google Scholar
Shah, R, Kolanos, R, DiNovi, MJ et al. (2017) Dietary exposures for the safety assessment of seven emulsifiers commonly added to foods in the United States and implications for safety. Food Addit Contam Part A Chem Anal Control Expo Risk Assess 34, 905917.CrossRefGoogle ScholarPubMed
Ahuja, J, Li, Y, Bahadur, R et al. (2020) Characterizing Ingredients in Baked Products Sold in the U.S. Curr Dev Nutr 4, 733.CrossRefGoogle Scholar
Chazelas, E, Deschasaux, M, Srour, B et al. (2020) Food additives: distribution and co-occurrence in 126,000 food products of the French market. Sci Rep 10, 3980.CrossRefGoogle ScholarPubMed
Gaines, A, Shahid, M, Huang, L et al. (2021) Deconstructing the supermarket: systematic ingredient disaggregation and the association between ingredient usage and product health indicators for 24,229 Australian foods and beverages. Nutrients 13, 1882.CrossRefGoogle Scholar
Montera, VDSP, Martins, APB, Borges, CA et al. (2021) Distribution and patterns of use of food additives in foods and beverages available in Brazilian supermarkets. Food Funct 12, 76997708.CrossRefGoogle ScholarPubMed
Blakemore, WR & Harpel, AR (2010) Carrageenan. In Food Stabiliser, Thickeners and Gelling Agents, pp. 7294 [Imeson, A, editor]. New Jersey: Blackwell Publishing Ltd.Google Scholar
Murray, JCF (2009) Cellulosics. In Handbook of Hydrocolloids, pp. 710723 [Phillips, GO and Williams, PA, editors]. Boca Raton: CRC Press.CrossRefGoogle Scholar
Chassaing, B, Compher, C, Bonhomme, B et al. (2022) Randomized controlled-feeding study of dietary emulsifier carboxymethylcellulose reveals detrimental impacts on the gut microbiota and metabolome. Gastroenterology 162, 743756.CrossRefGoogle ScholarPubMed
Chen, J, Wellens, J, Kalla, R et al. (2023) Intake of ultra-processed foods is associated with an increased risk of Crohn’s disease: a cross-sectional and prospective analysis of 187,154 participants in the UK Biobank. J Crohns Colitis 17, 535–552.CrossRefGoogle ScholarPubMed
Lo, CH, Khandpur, N, Rossato, SL et al. (2022) Ultra-processed foods and risk of Crohn’s disease and ulcerative colitis: a prospective cohort study. Clin Gastroenterol Hepatol 20, e1323e1337.CrossRefGoogle ScholarPubMed
European Food Safety Authority (2015) Scientific opinion on the re-evaluation of polyoxyethylene sorbitan monolaurate (E 432), polyoxyethylene sorbitan monooleate (E 433), polyoxyethylene sorbitan monopalmitate (E 434), polyoxyethylene sorbitan monostearate (E 435) and polyoxyethylene sorbitan tristearate (E 436) as food additives. EFSA J 13, 174.Google Scholar
European Food Safety Authority (2017) Re-evaluation of celluloses E 460(i), E 460(ii), E 461, E 462, E 463, E 464, E 465, E 466, E 468 and E 469 as food additives. EFSA J 16, 1104.Google Scholar
European Food Safety Authority (2018) Re-evaluation of carrageenan (E407) and processed Eucheuma seaweed (E407a) as food additives. EFSA J 16, 5238.Google Scholar
Sandall, AM, Cox, SR, Lindsay, JO et al. (2020) Emulsifiers impact colonic length in mice and emulsifier restriction is feasible in people with Crohn’s disease. Nutrients 12, 2827.CrossRefGoogle ScholarPubMed
Tseng, M, Grigsby, CJ, Austin, A et al. (2022) Sensory-related industrial additives in the US packaged food supply. Front Nutr 8, 762814.CrossRefGoogle ScholarPubMed
Chazelas, E, Druesne-Pecollo, N, Esseddik, Y et al. (2021) Exposure to food additive mixtures in 106,000 French adults from the NutriNet-Santé cohort. Sci Rep 11, 19680.CrossRefGoogle ScholarPubMed
Jędrusek-Golińska, A, Piasecka-Kwiatkowska, D, Zielińska, P et al. (2019) Soy preparations are potentially dangerous factors in the course of a food allergy. Foods 8, 655.CrossRefGoogle ScholarPubMed
The Global Panel on Agriculture and Food Systems for Nutrition (2016) Food Systems and Diets: Facing the Challenges of the 21st Century. London: Global Panel on Agriculture and Food Systems for Nutrition.Google Scholar
Naimi, S, Viennois, E, Gewirtz, AT et al. (2021) Direct impact of commonly used dietary emulsifiers on human gut microbiota. Microbiome 9, 66.CrossRefGoogle ScholarPubMed
McCutcheon, J, Campbell, K, Ferguson, M et al. (2015) Prevalence of phosphorus-based additives in the Australian food supply: a challenge for dietary education? J Ren Nutr 25, 440444.CrossRefGoogle ScholarPubMed
Green, MA, Watson, AW, Brunstrom, JM et al. (2020) Comparing supermarket loyalty card data with traditional diet survey data for understanding how protein is purchased and consumed in older adults for the UK, 2014–2016. Nutr J 19, 83.CrossRefGoogle Scholar
FAO & WHO (2017) CODEX Alimentarius: International Food Standards. Class Names and the International Numbering System for Food Additives. Report no. CAC/GL 36-1989. https://www.fao.org/fao-who-codexalimentarius/ (accessed October 2023).Google Scholar
Figure 0

Table 1 Search terms and eligibility criteria for the fifteen top consumed ultra-processed food (UPF) categories in the UK. Adapted using the FAO descriptors of ultra-processed foods and National Diet and Nutrition Survey descriptors

Figure 1

Fig. 1 Flow diagram of food product inclusion

Figure 2

Table 2 Occurrence of food additive emulsifiers by ultra-processed food (UPF) category in the UK food supply

Figure 3

Table 3 Occurrence of individual emulsifiers across ultra-processed food categories in the UK food supply

Figure 4

Fig. 2 Number of individual emulsifiers per food product

Figure 5

Fig. 3 Heat map displaying co-occurrence of individual food additive emulsifiers in the UK food supply. Values are Spearman’s rho correlation coefficients, and cell shading indicates the magnitude of correlation co-occurrence between emulsifiers. The degree of green shading indicates positive correlations, and red shading denotes negative correlations

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