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Evaluating the ≤10:1 wholegrain criterion in identifying nutrient quality and health implications of UK breads and breakfast cereals

Published online by Cambridge University Press:  26 December 2017

Bahar Ghodsian
Affiliation:
School of Life and Medical Sciences, University of Hertfordshire, Hatfield, Hertfordshire AL10 9AB, UK Homerton University Hospitals NHS Foundation Trust, London, UK
Angela M Madden*
Affiliation:
School of Life and Medical Sciences, University of Hertfordshire, Hatfield, Hertfordshire AL10 9AB, UK
*
*Corresponding author: Email [email protected]
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Abstract

Objective

To evaluate the nutrient quality of breads and breakfast cereals identified using the wholegrain definition of ≤10:1 carbohydrate:fibre ratio.

Design

Following a cross-sectional study design, nutritional information was systematically gathered from food labels of breads and breakfast cereals that met the ≤10:1 carbohydrate:fibre criterion. The median nutrient content was compared with the UK Food Standards Agency’s nutrient profiling standards and the associations between carbohydrate:fibre ratio and other nutrients were analysed. Subgroup analyses were undertaken for products with and without fruit, nuts and/or seeds.

Setting

Products from four major supermarket stores in the UK.

Subjects

Breads (n 162) and breakfast cereals (n 266).

Results

Breads which met the ≤10:1 criterion typically contained medium fat, low saturated fat, low sugar and medium Na. Breakfast cereals typically contained medium fat, low saturated fat, high sugar and low Na. In both groups, as the carbohydrate:fibre ratio decreased, fat content increased (bread: P=0·029, r=−0·171; breakfast cereal: P=0·033, r=−0·131) and, in breakfast cereals, as the ratio increased, sugar content increased (P<0·0005, r=0·381). Breakfast cereals with fruit, nuts and/or seeds contained, per 100 g, more energy (P=0·002), fat, saturated fat and sugar (all P<0·0005), while seeded breads had more energy, fat and saturated fat (all P<0·0005).

Conclusions

Overall, breads and breakfast cereals meeting the ≤10:1 criterion have good nutritional quality, suggesting that the criterion could be useful in public health and/or food labelling. The utility of applying the ≤10:1 criterion to products containing fruit, nuts and/or seeds is less clear and requires further research.

Type
Research Papers
Copyright
Copyright © The Authors 2017 

The term ‘whole grain’ typically refers to the entire edible grain from cereals and related plants( 1 ). Food containing whole grains can include the full grain or be reconstituted so the components of the grain are recombined to a similar proportion to that of the original grain( Reference Jonnalagadda, Harnack and Liu 2 ). Many studies suggest that foods high in wholegrain ingredients may reduce the risk of chronic diseases such as CVD, type 2 and gestational diabetes and some cancers, including gastrointestinal and breast cancer( Reference Jonnalagadda, Harnack and Liu 2 Reference Helnæs, Kyrø and Andersen 6 ). Foods high in whole grains can replace more processed, higher-glycaemic-index cereals such as white bread and hence maintain satiation and prolong gastric emptying, which may reduce obesity risk( Reference Ludwig 7 ). These effects are potentially due to substances in the germ and bran of the grain which work synergistically, including insoluble and soluble fibre, phytosterols and antioxidants such as lignans, polyphenols and flavonoids( Reference Slavin 8 ). However, some of the health benefits of whole grains may also be attributed to their role as a proxy for a diet high in other nutrients. For example, Venn and Mann( Reference Venn and Mann 9 ) demonstrated uncertainty about whether the impact of unrefined grain intake on reducing diabetes-related mortality is due to wholegrain foods or other lifestyle factors. Thus, the mechanism by which whole grains are beneficial is still partially unclear. Furthermore, much of the research into whole grains is sponsored by companies that manufacture cereal-based products( Reference Jonnalagadda, Harnack and Liu 2 , Reference Schroeder, Gallaher and Arndt 10 , Reference Giacco, Clemente and Cipriano 11 ). While not all of these companies are interested in wholegrain goods, this funding may influence both the focus of cereal-based studies and the findings that are published. In addition, there is little consistency in how authors define wholegrain foods( Reference Ferruzzi, Jonnalagadda and Liu 12 ). These factors influence conclusions that can be drawn from the literature( Reference Ferruzzi, Jonnalagadda and Liu 12 , Reference Fontanarosa, Flanagin and DeAngelis 13 ). Despite this, there is a general consensus from authoritative organisations that increasing intake of whole grains can reduce the risk of many important public health problems( 14 16 ).

Unlike the USA, Australia, Denmark and Canada, the UK does not have a quantified recommendation for intake of whole grains( Reference Mann, Pearce and McKevith 17 ). The only recommendation is in The Eatwell Guide, which advises that ‘starchy food should make up about a third of the food’ eaten in a day and wherever possible, wholegrain options should be chosen( 14 ). However, intake of whole grains remains low. Comparison of data from the UK National Diet and Nutrition Survey (NDNS) with the US recommendation of at least three 16 g servings of whole grains per day shows that 45 % of UK adults ate less than one serving and 18 % consumed no whole grains during the 4 d collection period( Reference Mann, Pearce and McKevith 17 ). With obesity and diabetes increasing( 18 ) and low intakes of whole grains, a public health initiative to substitute foods containing whole grains for those containing significant amounts of refined grains might improve health, save resources and reduce total and CVD-related mortality( Reference Wu, Flint and Qi 19 ).

However, it is difficult to promote whole grains when there is little standardisation in defining ‘wholegrain’ foods. In Europe, a food must have ≥51 % wholegrain ingredients by wet weight in order to make a health claim( 20 ). However, other nutrients are not specified in relation to this, which means that products making this claim can also have very high levels of sugar or fat. The UK Institute of Grocery Delivery( 1 ) recommends that a food should have at least 8 g of wholegrain ingredients per serving to be called whole grain. However, as with the USA and Canadian Whole Grain Stamp( 21 ), this recommendation is non-binding. Non-statutory labelling is predominantly decided by industry representatives( 1 ), which raises the concern that they may focus on commercial rather than health purposes and thus may be potentially misleading( Reference Gilmore, Savell and Collin 22 , Reference Mozaffarian, Lee and Kennedy 23 ).

In 2015 the UK Scientific Advisory Committee on Nutrition recommended that a standardised definition of ‘whole grain’ and wholegrain foods should be developed as this would facilitate recommended portion sizes for wholegrain foods and support public health messages about the importance of dietary fibre( 24 ). Similarly, the US Dietary Guidelines Technical Advisory Committee has declared ‘a call to action’ to develop a definition of wholegrain foods that can be internationally implemented( Reference Ferruzzi, Jonnalagadda and Liu 12 ). This would benefit public health directly by providing consumers with consistent and useful information and indirectly by facilitating research into whole grains( Reference Ferruzzi, Jonnalagadda and Liu 12 , Reference Serra-Majem and Bautista-Castaño 25 ).

Mozaffarian et al. recently compared five different criteria to see which represented the healthiest American wholegrain-based foods( Reference Mozaffarian, Lee and Kennedy 23 ). They found that foods with a ≤10:1 carbohydrate:fibre ratio contained the least sugar, Na and trans-fats. No similar studies have been undertaken outside the USA but this criterion could be considered in other countries.

The ≤10:1 criterion is based on the recommendation of the American Heart Association( Reference Lloyd-Jones, Hong and Labarthe 26 ) as it is approximately the carbohydrate:fibre ratio in whole-wheat flour( Reference Mozaffarian, Lee and Kennedy 23 ). This ratio acts as a benchmark to represent the ‘balance of whole grain v. sugars and refined grains’, hence indicating overall carbohydrate quality( Reference Mozaffarian, Lee and Kennedy 23 ). However, there is no clarification that the fibre content must come from wholegrain ingredients.

The aim of the current cross-sectional study was to evaluate the nutritional quality of breads and breakfast cereals identified using the wholegrain definition of ≤10:1 carbohydrate:fibre ratio and, therefore, to examine the utility of this criterion by considering the health implications of foods that it defines.

The term ‘utility’ in this context is used to describe a variety of factors. These include, but are not limited to: how easily the criterion can be used; how healthy the foods that meet it are; whether it can be used to promote healthier choices; and whether it is representative of wholegrain foods. Even though the word ‘healthy’ is used herein, the authors acknowledge that it is subjective and can have various meanings; this is discussed further in the paper’s limitations.

Methods

Data collection

The NDNS was used to establish which cereal-based foods are most commonly eaten in the UK. It was determined that breads and breakfast cereals constitute 49 % of UK cereal intake( 27 ). Using these foods to evaluate the use of the criterion was appropriate as they make a major contribution to cereal intake. The remaining 51 % included foods like pasta, rice and sweet items. However, other commonly consumed foods containing whole grains, such as pasta, varied considerably in the form of products available (e.g. being sold dry or fresh), which confounded analysis, so they were not included in the present study. Hence, all the products in the current research were breads or breakfast cereals with a carbohydrate:fibre ratio ≤10:1. Products with a ratio >10:1 were not studied. Sweet breads (e.g. malt loaf), gluten-free foods and foods marketed for infants and toddlers were excluded due to typically having a different composition.

Nutritional information was obtained online from four major supermarkets to make the results generalisable, as 79 % of the UK population buys food from one or more of these shops( 28 ). Their websites were accessed in order of their market share: Tesco, Asda, Sainsbury’s and Morrison’s( 28 ). A generic search was made using the terms ‘bread’ and ‘breakfast cereal’ and then searches were conducted for more unusual products that the NDNS included such as ‘roti’ or ‘English muffins’. Out of all the breads and breakfast cereals across the supermarkets that met the search terms, a total of 162 breads and 266 breakfast cereals met the criterion and were included in the study. The nutritional information for each product was documented as g/100 g and kJ/100 g for comparison. Data included portion size, carbohydrate, fibre, energy, fat, saturated fat, sugar, Na and ingredients. These nutrients were included because they are used to assess a food’s nutrient quality( 29 ). Carbohydrate:fibre ratio was calculated.

Data analysis

Nutritional data were assessed for statistical distribution and, as the data were non-parametric, the median and quartiles of energy and each nutrient were calculated for breads, breakfast cereals and subgroups (listed below). The data for fat, saturated fat, sugar and Na were categorised according to the Food Standards Agency’s (FSA) definitions of ‘high’, ‘medium’ and ‘low’ levels of each nutrient per 100 g as used in UK nutrient profiling( 29 ) (Table 1). Therefore, conclusions were drawn about amounts of nutrients in the foods meeting the criterion. Na is referred to throughout this paper but was multiplied by 2·5 for conversion to salt (based on 1 g of salt containing 390 mg Na) for comparison with the FSA definitions( Reference Grimes, Wright and Liu 30 ).

Table 1 Food Standard Agency’s nutrient profiling categories for high, medium and low amounts of nutrients per 100 g, including salt recalculated as sodium as described in the ‘Methods’ section( Reference Serra-Majem and Bautista-Castaño 25 )

The association between the carbohydrate:fibre ratio and the amount of energy, fat, saturated fat, sugar and Na was examined in breads and breakfast cereals using a Spearman rank correlation.

Subgroup analyses were undertaken using independent-samples median tests as it was observed that some of the products containing fruit, nuts and/or seeds also contained substantial quantities of refined carbohydrate and fewer wholegrain ingredients. The analyses compared breads containing seeds with breads that did not and breakfast cereals containing fruit, nuts and/or seeds with those that did not.

Most of the analyses for breakfast cereals were based on the dry products. However, it was recognised that breakfast cereals are often consumed with milk. As milk contains carbohydrate but negligible fibre( Reference Finglas, Roe and Pinchen 31 ), a separate analysis was completed in which the carbohydrate in a portion of semi-skimmed milk (125 ml)( Reference Finglas, Roe and Pinchen 31 , 32 ) was added to the carbohydrate content of a portion of each breakfast cereal (specified by the manufacturer) to assess how milk affects the carbohydrate:fibre ratio. This was conducted for breakfast cereals containing fruit, nuts and/or seeds and those that did not. The breakfast cereals that exceeded this ratio once milk was added were still included in the research as the carbohydrate:fibre ratio of the dry product was the main focus.

All tests were completed using the statistical software package IBM SPSS Statistics version 22.0 and P<0·05 was accepted as statistically significant.

Results

Comparisons of nutrient content with Food Standards Agency categories

The nutrient content per 100 g for 162 breads and 266 breakfast cereals with ≤10:1 carbohydrate:fibre ratio classified using the FSA( 29 ) high, medium or low categories is presented in Table 2. For bread, the content of saturated fat, sugar and Na based on median values were consistent enough for generalisations to be made, i.e. that typically they contained low saturated fat, low sugar and medium Na. There was more variation in the fat content, but, based on median values, they contained a medium amount of fat.

Table 2 Energy and nutrient content per 100 g of breads and breakfast cereals meeting the ≤10:1 wholegrain criterion available from four major supermarket stores in the UK, September–November 2015. Values are classified as high, medium or low amounts of nutrients per 100 g, following the Food Standards Agency’s nutrient profiling categories( 29 )

For breakfast cereals, the median values indicated medium fat, low saturated fat, high sugar and low Na content. However, for all the nutrients, the values at the 25th, median and/or 75th quartiles corresponded to different FSA categories, indicating that the amounts of nutrients in breakfast cereals are more widely distributed (Table 2).

Relationships between carbohydrate:fibre ratio and energy and nutrient content

A significant positive correlation was found between the ratio and sugar content for breakfast cereals (P<0·0005, r=0·381) indicating that as carbohydrate increases and/or fibre decreases, sugar content increases. A significant negative correlation was found for both breads and breakfast cereals between the ratio and fat (breads: P=0·029, r=−0·171; breakfast cereals: P=0·033, r=−0·131). This indicates that as carbohydrate decreases and/or fibre increases, fat content increases.

For breads, there were no significant relationships between the ratio and the content of energy, saturated fat, sugar or Na. For breakfast cereals there were no significant relationships between the ratio and energy, saturated fat or Na.

Subgroup analyses

There were significant differences in the median amounts of nutrients in breads with and without seeds (Table 3). Most importantly, seeded breads had significantly higher energy, fat and saturated fat (all P<0·0005).

Table 3 Median content of carbohydrate, fibre, carbohydrate: fibre ratio, sugar, sodium, energy, fat and saturated fat for breads with and without seeds, and breakfast cereals with and without fruit, nuts and/or seeds, available from four major supermarket stores in the UK, September–November 2015

* The only difference in Food Standards Agency categories( 29 ) between subgroups is in fat content with seeded and non-seeded breads: seeded breads having medium fat and non-seeded breads having low fat.

P values obtained by comparing nutrients in breads with seeds and without seeds using the independent-samples median test.

P values obtained by comparing nutrients in breakfast cereals containing fruit, nuts and/or seeds with those that did not using the independent-samples median test.

There were also significant differences in the median amounts of nutrients in the breakfast cereals containing fruit, nuts and/or seeds and those without (Table 3). The products containing fruit, nuts and/or seeds had significantly higher energy (P=0·002) and fat, saturated fat and sugar (all P<0·0005).

Without distinguishing between breakfast cereals that did and did not contain fruit, nuts and/or seeds, when the nutritional information of a portion of semi-skimmed milk was added to each breakfast cereal portion, ninety (34 %) exceeded the ≤10:1 ratio.

Discussion

The present study aimed to evaluate the nutritional quality of breads and breakfast cereals identified using the wholegrain definition of ≤10:1 carbohydrate:fibre ratio in order to contribute to understanding of the utility of the criterion in promoting nutritional health. The FSA categories for fat, saturated fat, sugar and salt were chosen for comparison as they are an accepted method of nutrient profiling in the UK( Reference Lobstein and Davies 33 ) and highly relevant to public health.

Evaluation of the criterion in relation to breads meeting the ≤10:1 ratio

The median nutrient content for wholegrain breads identified using the ≤10:1 ratio suggests they have good nutritional quality, an important indication of the utility of this criterion. The low saturated fat and sugar content supports current public health guidance as limiting saturated fat and sugar intake is recommended to reduce the risk of common long-term conditions in the UK, notably CVD and diabetes( 14 ). This is one reason why wholegrain bread is recommended as a carbohydrate source in guidelines across Europe( 14 , Reference van Dooren and Kramer 34 ). The medium content of fat is not concerning as only 16 % is saturated. The remaining unsaturated fats may promote a healthier blood lipid profile, improving cardiovascular health( Reference Vafeiadou, Weech and Altowaijri 35 ), again suggesting these breads have good nutritional quality. The medium Na content is unsurprising as bread is the largest single contributor of Na in the UK diet( Reference Brinsden, He and Jenner 36 ). This is a well-established concern( Reference Mhurchu, Capelin and Dunford 37 ). Most breads have a high salt content, not just those meeting the criterion, but this is decreasing in UK bread following a voluntary salt-reduction programme( Reference Brinsden, He and Jenner 36 ).

Studies of wholegrain breads tend to examine health benefits or micronutrient supplementation rather than overall nutritional content as in the present study. In addition, no published studies have examined the ≤10:1 criterion in UK breads. Results of the present study cannot be compared with the findings of Mozaffarian et al.( Reference Mozaffarian, Lee and Kennedy 23 ) as their study did not distinguish between the nutritional composition of breads and other products meeting the criterion. However, when compared with wholegrain breads in the UK food tables (i.e. McCance and Widdowson’s The Composition of Foods ( Reference Finglas, Roe and Pinchen 31 )), the breads that met the criterion were higher in fat, saturated fat, sugar and Na, suggesting that they are, overall, less healthy. Nevertheless, this comparison is limited as the food tables have a smaller sample size and analysis methods may differ. Overall, the nutritional composition of breads meeting the criterion appears to correspond with healthy eating recommendations( 14 ), which indicates the utility of using this criterion.

Regardless of the relatively good nutritional profile and health implications, it is important to consider that, due to the inclusion criterion of the ≤10:1 carbohydrate:fibre ratio, many of the breads contained seeds. While people who eat seeds may have better health (including lower TAG levels and increased insulin sensitivity)( Reference Karlsen, Ellmore and McKeown 38 ), seeds contain a different type of fibre from whole grains, which some argue has fewer biological benefits( Reference McKee and Latner 39 ). This fibre lowers the ratio without contributing whole grains. In addition, the seeded breads have a different nutritional composition with more energy, fat and saturated fat (Table 3). While eating seeded rather than un-seeded breads is unlikely to have a major impact in isolation on someone’s body weight, it may be a less desirable choice for overweight or obese people who are trying to reduce their energy intake. Thirty-seven per cent of the breads examined contained seeds and, based on the food labelling, it is not possible to determine which would meet the ≤10:1 criterion by virtue of their wholegrain content alone, i.e. if the seeds were excluded. This is a limitation of the criterion as a ≤10:1 carbohydrate:fibre ratio does not guarantee that a product contains adequate wholegrain ingredients and, as a result, foods meeting the criterion may have a different nutritional profile.

In breads, there was an inverse relationship between the carbohydrate:fibre ratio and fat content. This may relate to the relative mutual displacement of the macronutrients in terms of fat and unrefined carbohydrate or it may be because the seeded breads have more fat and fibre (Table 3) due to the contribution from seeds( Reference Anderson, Baird and Davis 40 ). The difference in fibre between breads with and without seeds was not statistically significant, but this may be because of inadequate sample size. In fact, it disagrees with evidence that higher-fibre diets are usually associated with a lower fat intake( Reference Mozaffarian, Lee and Kennedy 23 ), although this may be because the negative association relates to wholegrain foods alone, not the total diet. Nevertheless, more research is needed to see if this is representative of breads and other wholegrain products. This correlation suggests that, to promote lower-fat wholegrain options, products with a higher ratio should be chosen; however, foods with a higher ratio provide fewer wholegrain benefits due to having less fibre( Reference Slavin 8 ).

Even though breads meeting the criterion have a relatively good nutritional profile, the criterion does not account for the negative change to overall nutritional profile due to adding high-fat or high-sugar ingredients such as butter or jam. This is supported by recommendations in international guidelines( Reference Truswell 41 ) and recent Public Health England recommendations( 14 ) to avoid adding fats to starchy foods to prevent excess weight gain. Nevertheless, a small serving of butter or jam may not affect health benefits significantly whereas a larger serving could. This is pertinent because bread is normally eaten in a mixed meal which can affect its nutritional properties such as glycaemic index( Reference Dewettinck, Van Bockstaele and Kuhne 42 ), sometimes detracting from potential health benefits of the wholegrain ingredients. Clearly, the utility of the wholegrain criterion is limited by its inability to account for this.

Evaluation of the criterion in relation to breakfast cereals meeting the ≤10:1 ratio

There is no other research looking at this criterion in relation to UK breakfast cereals. There is literature that looks at the nutritional composition of wholegrain breakfast cereals, albeit defining whole grains differently, and these are considered here to assist the evaluation. The breakfast cereals meeting the criterion have low amounts of saturated fat and Na (Table 2) which could contribute beneficially to the diet as the average intake of these nutrients in the UK exceeds recommendations, contributing to poorer heart health( 27 ). This is supported by a systematic review by Williams( Reference Williams 43 ) who found that those who eat wholegrain breakfast cereals have a lower CVD and hypertension risk, partly due to reduced Na intake. The NDNS( 27 ) has also shown that breakfast cereals, on average, only contribute 1–2 % of total dietary Na. This indicates that the saturated fat and Na content of these breakfast cereals corresponds with healthy eating recommendations( 29 ). As with breads meeting this criterion, the medium fat content is not of concern as only 18 % is saturated. The remaining unsaturated fats contribute positively to the nutritional profile and may contribute to improved cardiovascular outcomes( Reference Martinez-Gonzalez, Salas-Salvado and Estruch 44 ).

Research has shown that, in all age groups, in the UK and internationally, breakfast cereal consumption is associated with reduced overall fat intake( 27 , Reference Ruxton and Kirk 45 ), suggesting that the medium fat content of the breakfast cereals is unlikely to contribute to increased fat intake.

However, some breakfast cereals have a high sugar content which is detrimental to their overall nutritional profile( Reference Lustig, Schmidt and Brindis 46 ). Even though it is well established that some breakfast cereals are high in sugar, there is no evidence that those who eat them have a higher overall sugar intake or are more likely to be overweight( Reference Williams 43 , Reference McKeown, Yoshida and Shea 47 ). The present study showed that the higher the carbohydrate:fibre ratio, the higher the sugar content. This may be due to added sugar, listed as an ingredient in 77 % of the breakfast cereals, which contributes to the carbohydrate but not the fibre content. This is supported by Williams( Reference Williams 43 ) who has discussed the presence of sugar in breakfast cereals. However, there are many lower-sugar breakfast cereals as the sugar content of these products varied from 0·3 to 31·4 g/100 g. It could be argued that to make the criterion a better tool, it should only be applied to breakfast cereals that have a ≤10:1 ratio and a medium or low amount of sugar (i.e. <15 g/100 g). Alternatively, promoting a lower criterion could exclude high-sugar cereals while providing more fibre as suggested by Mozaffarian et al. ( Reference Mozaffarian, Lee and Kennedy 23 ). Furthermore, the UK food tables show that the carbohydrate:fibre ratio of wholemeal flour is typically 6·5:1 to 7:1( Reference Finglas, Roe and Pinchen 31 ), which is lower than the ≤10:1 ratio suggested by the American Heart Association( 16 ). This may be further justification for a lower ratio to be used in order to exclude foods with significant amounts of added sugars. Alternatively, for breakfast cereals, carbohydrate:fibre:sugar ratio could be considered to provide a better indication of the overall carbohydrate composition and sugar content.

As with bread meeting this criterion, in these breakfast cereals, as the carbohydrate:fibre ratio decreases, fat content increases. This may be due to nuts and seeds which have high fibre and fat content( Reference Anderson, Baird and Davis 40 ) and was reflected in the study results where breakfast cereals with fruit, nuts and/or seeds contained more energy, fat, saturated fat and sugar (Table 3). Therefore, even though the fruit, nuts and/or seeds can provide benefit through their contribution to micronutrient and phytosterol intake( Reference Liu 48 , Reference Phillips, Ruggio and Ashraf-Khorassani 49 ), the breakfast cereals containing fruit, nuts and/or seeds had a poorer nutritional profile and, considering some may not have met the ≤10:1 criterion without the addition of fruit, nuts and/or seeds, they may have less wholegrain benefits and hence less bioactive properties. Nevertheless, consuming breakfast cereals with fruit, nuts and/or seeds would still be a good way of increasing the general population’s fibre intake, which is an important public health message( 27 ). However, if consumers assumed that all foods with a ≤10:1 carbohydrate:fibre ratio contain whole grains, they could be misled and choose products high in fruit, nuts and/or seeds but low in actual wholegrain ingredients, especially as some ice creams and fruit juices (both without whole grains) meet this ratio. Another example is a supermarket own-brand porridge pot where the plain porridge did not meet the criterion but the same product with fruit, nuts and/or seeds did. Confusion could be avoided by using clear front-of-pack labelling showing if there is adequate fibre ‘from whole grains’ to meet the criterion. This would also help consumers identify products that are better for their health. Mozaffarian et al. ( Reference Mozaffarian, Lee and Kennedy 23 ) also supported codifying the ≤10:1 ratio to use it on front-of-pack labelling.

Furthermore, consideration needs to be given to the type of cereal. As whole wheat typically has a low carbohydrate:fibre ratio (e.g. wholemeal wheat flour, code 11-889=6·9)( Reference Finglas, Roe and Pinchen 31 ), this criterion is likely to favour wheat-based foods, along with those with added fibre and rye flour (rye flour, code 11-897=5·2)( Reference Finglas, Roe and Pinchen 31 ). However, despite oats having a higher carbohydrate:fibre ratio (porridge oats, code 11-788=9·1)( Reference Finglas, Roe and Pinchen 31 ) research shows that, due to the presence of β-glucans and avenanthramides among other bioactive components, there are more consistent results for the health benefits associated with their consumption( Reference Gani, Wani and Masoodi 50 ). Clearly identifying the source of the whole grains as well as the carbohydrate:fibre ratio may enable consumers to better understand the overall nutritional value of the food.

Adding other ingredients to breakfast cereals post-purchase alters the carbohydrate:fibre ratio, as with breads. Adding milk can alter the nutritional profile: 34 % of products originally meeting the criterion do not meet it after milk is added. The original premise of the criterion is to capture the balance of whole grains in relation to sugars and refined grains( 20 ) but adding milk detracts from this as lactose in milk increases the ratio. This may look like a drawback of the criterion. However, adding milk helps meet Ca, protein and vitamin B requirements( 51 ). Lactose also enhances Ca and Mg absorption while having a low glycaemic index and carcinogenicity( Reference Schaafsma 52 ). Therefore, even though adding milk to wholegrain breakfast cereals can result in the meal exceeding the ≤10:1 ratio, it can be argued that the nutrition that milk provides is more important, especially as it does not detract from the benefits of wholegrain ingredients. Adding other ingredients, such as sugar, is different and could detract from the wholegrain ingredients( Reference Ludwig 7 ). While this is a limitation of the criterion, it may not be worth altering it for this reason. Instead, a separate public health campaign that encourages reducing sugar intake, such as Change4Life’s Sugar Smart( 53 ), could mitigate this.

Limitations

The present study included only breads and breakfast cereals. Other grain-based foods – such as pasta and foods aimed at children aged less than 4 years – could be assessed and evaluating these would contribute to a more comprehensive evaluation of how widely the criterion could be applied. Furthermore, foods from other retailers could have been included since 21 % of the UK population does not shop at the supermarkets surveyed( 28 ) and so there may be products that were not analysed. There are also nutritional components that affect health that are not included on food packaging which could have extended the evaluation; for example, trans-fats or the extent of processing. In addition, the effect of portion size when discussing nutritional content of foods has not been considered. Looking at nutrients per 100 g enables medians to be calculated and compared with the FSA standards but this does not account for the portion someone might eat. The FSA standards themselves were designed to inform consumers rather than assess food products and have limitations as a tool( Reference Scarborough, Matthews and Eyles 54 ).

In an attempt to discuss the possible health implications of foods meeting this criterion, some inevitable generalisations may have been made regarding the effects of the nutritional composition of wholegrain ingredients or foods on health; these associations are not always straightforward or predictable( Reference Jacobs, Tapsell and Temple 55 ). Another significant limitation is the unavoidable subjectivity when judging health quality. While the authors may consider a medium amount of fat, saturated fat, sugar or Na to represent a relatively healthy food, others may disagree. This indicates the importance of considering the whole diet rather than single components in isolation.

Future recommendations

As the present study is the first of its kind, more research is needed before steps can be taken towards using this criterion. It would be useful to repeat the research comparing it with similar products with a >10:1 ratio. This would also provide an opportunity to compare the price of foods that meet the criterion with those that do not, to explore the cost of foods that meet this criterion and how this could affect sales and intake. The research could also be completed while comparing the nutritional content of the foods with a different nutrient profiling model. This would improve understanding of how useful the criterion is in identifying healthier foods. An investigation into the contribution of fruit, nuts and seeds to products meeting the criterion would also be useful so that decisions can be made about whether products with fruit, nuts and seeds should be included. In addition, more research could be conducted to determine if a different ratio (e.g. ≤7:1) should be used to promote products with less fat or sugar. This could help meet other public health goals. However, a disadvantage of using a criterion other than ≤10:1 is that it may be more difficult for consumers to work out from food labels if a product meets the wholegrain criterion. It is also important to explore whether consumers would understand how to identify wholegrain foods using this criterion and if not, how it could be adapted. Nevertheless, this ≤10:1 criterion has potential as a standardised definition for wholegrain foods.

Conclusions

The present study furthers understanding of the ≤10:1 carbohydrate:fibre wholegrain criterion and its potential implementation by reporting that foods meeting the ≤10:1 criterion are relatively healthy when assessed using the FSA nutrient profiling standards as a benchmark; the main exception being the sugar content of breakfast cereals. The utility of the criterion is its potential to offer a standardised approach to the classification of wholegrain breads and breakfast cereals which relates to their nutrient content and thus potentially contributing to efforts to increase wholegrain intake( 20 , 21 , Reference de Munter, Hu and Spiegelman 56 ).

Acknowledgements

Acknowledgements: The authors would like to thank Dr Alla Mashanova for statistical advice and Dr Helen Crawley for public health feedback. Financial support: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Conflict of interest: None. Authorship: The research question was proposed by A.M.M.; the study was designed by B.G. supported by A.M.M.; data were collected and analysed by B.G.; the article was written by B.G. and A.M.M. Ethics of human subject participation: This research did not involve human subjects.

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Figure 0

Table 1 Food Standard Agency’s nutrient profiling categories for high, medium and low amounts of nutrients per 100 g, including salt recalculated as sodium as described in the ‘Methods’ section(25)

Figure 1

Table 2 Energy and nutrient content per 100 g of breads and breakfast cereals meeting the ≤10:1 wholegrain criterion available from four major supermarket stores in the UK, September–November 2015. Values are classified as high, medium or low amounts of nutrients per 100 g, following the Food Standards Agency’s nutrient profiling categories(29)

Figure 2

Table 3 Median content of carbohydrate, fibre, carbohydrate: fibre ratio, sugar, sodium, energy, fat and saturated fat for breads with and without seeds, and breakfast cereals with and without fruit, nuts and/or seeds, available from four major supermarket stores in the UK, September–November 2015