Free sugars and health

Global estimates suggest that some 650 million adults and 41 million children (<5 years) are now obese⁽²⁾. The global prevalence (age-standardised) of type-2 diabetes mellitus has almost doubled over the past 20 years, up from 4·7 % in 1980 to 8·5 % in the adult population⁽³⁾. The potential negative health impacts of overconsumption of free sugars, particularly from sugar-sweetened beverages (SSB), in relation to weight gain (and increased BMI), increased risk of developing type-2 diabetes and tooth decay are well documented^(1,4) .

Current and recommended sugar intakes

Most recent data from the UK National Diet and Nutrition Survey indicate that in all age groups, mean intake of free sugars exceeded (more than double) the UK government recommendation of no more than 5 % of daily total energy intakes (TEI)⁽⁵⁾. Furthermore, only 2 % of UK children aged 4–10 years, 5 % of children 11–18 years and 13 % of UK adults met these recommendations for free sugar intakes⁽⁵⁾. In 2010, the European Food Safety Authority (EFSA) published its Scientific Opinion on Dietary Reference Values for carbohydrates and dietary fibre and observed that the average intake of (added) sugars in some European Union (EU) Member States exceeded 10 % of TEI⁽⁶⁾. The current US Department of Agriculture dietary guidelines for Americans recommended that added sugar intake should not exceed 10 % of TEI⁽⁷⁾. Similarly, WHO strongly recommends reducing the intake of free sugars to less than 10 % of TEI in both adults and children; corresponding to about 50 g/d for females with a daily energy requirement of 8·64 MJ/d (2000 kcal/d) or about 60 g/d for males with a daily energy requirement of 10·46 MJ/d (2500 kcal/d). Furthermore, WHO⁽¹⁾ suggests a further reduction to below 5 % of TEI as desirable and in the UK, the Scientific Advisory Committee on Nutrition (SACN) has recommended that the average population intake of free sugars should not exceed 5 % of TEI for adults and children (aged 2 years and over)⁽⁴⁾.

Strategies for reducing intakes of free sugars

Considering current consumption of free sugars within the population, achieving the recommended reductions in free sugar intakes are likely to prove challenging. Strategies that have been endorsed include promoting healthier options (e.g. ‘sugar swaps’), reducing the sugar content of commonly consumed products, reducing portion size, and/or shifting purchasing towards lower sugar alternatives⁽⁸⁾. In the UK, efforts to achieve these public health targets for sugar intakes have also included the introduction of a SSB levy together with guidelines for all sectors of the food industry in relation to sugar (and energy) reduction of selected food products. These guidelines aim to encourage industry to achieve a 20 % sugar reduction by 2020 across the top nine categories of food products that contribute most to intakes of children up to age 18 years (based on the 2015 sugar content of these food products)⁽⁸⁾. It is interesting to note that, ahead of the UK introduction of the SSB drink tax (introduced on 6 April 2018), an estimated 50 % of all beverages already had reduced sugar content. Furthermore, early assessment of progress by the food industry in relation to sugar reduction targets show good progress towards the first 5 % reduction in sugar content across a number of food categories⁽⁹⁾. Using strategies such as promoting healthier choices, reducing portion size and reformulating products are also likely to go some way for achieving these sugar reduction targets. However, given the very significant health and economic implications of chronic conditions such as obesity and diabetes, it is essential that the effectiveness of such approaches aimed at reducing sugar consumption is robustly evaluated.

Limitations with current research approaches to investigating the health impacts of sugars

Current recommendations for sugar intakes are largely based on evidence prospective cohort studies and randomised clinical trials (RCT)^(1,4,7) . A recognised weakness of using epidemiological data is that prospective cohort studies rely on unreliable quantitative assessment of food intake, and hence, may yield erroneous estimates of dose–response relationships for sugar intake^{(Reference Tappy, Morio and Azzout-Marniche10)}. An alternative approach employed by Tappy et al.^{(Reference Tappy, Morio and Azzout-Marniche10)} focused on data from mechanistic studies and RCT to determine intake thresholds above which sugar intake may negatively impact on health and hypothesised that the specific effects of sugars were attributed to their fructose component and thereby focused on studies which had assessed the effects of pure fructose. Clearly, a limitation of this approach was that the authors assumed that the effect of 50 g fructose can be extrapolated to the effect of 100 g sucrose^{(Reference Tappy, Morio and Azzout-Marniche10)}, which may not be the case. Another limitation when considering such studies relates directly to how sugars are defined, for example as ‘added sugars’ (USA⁽⁷⁾) or ‘free’ sugars (WHO⁽¹⁾, SACN⁽⁴⁾). There has been considerable debate on these definitions which can result in significant variation in findings^{(Reference Erickson and Slavin11)}. Based on available data, it is not possible to distinguish the health effects of sugars naturally present in food (e.g. fruit, vegetables, milk/dairy) from those of added sugars^{(Reference Tappy, Morio and Azzout-Marniche10)}. In the case of foods which naturally contain sugars, strong evidence exists for the protective effect of high fruit and vegetable consumption in relation to non-communicable diseases, which likely reflects other beneficial constituents within these foods (such as NSP, vitamins, minerals and in the case of fruit/vegetables phytochemicals). Recently published guidance on sugar consumption in France sets an upper intake limit of 100 g total sugar/d while continuing to recommend promotion of fruit and vegetable intakes⁽¹²⁾. Food consumption data estimated that within the French diet, fruit intakes provide about 40 g sugars, and intakes of vegetables provide 6 g sugars; this is consistent with a daily amount of free or added sugars in the 5–10 % TEI range, and thus these recommendations align with the WHO⁽¹⁾ and SACN⁽⁴⁾ recommendations. When EFSA published its Scientific Opinion on Dietary Reference Values for carbohydrates and dietary fibre in 2010⁽⁶⁾, the available evidence at that time was deemed to be insufficient to set an upper limit for the daily intake of total or added sugars. It is expected that EFSA will provide scientific advice on a tolerable upper intake level for (total/added/free) sugars by early 2020 with the aim of establishing science-based cut-off values for daily exposure to added sugars from all sources which are not associated with adverse health effects (to include body weight, glucose intolerance and insulin sensitivity, type-2 diabetes, cardiovascular risk factors and dental caries)⁽¹³⁾. It is also anticipated that in this context EFSA will consider the general healthy population, including children, adolescents, adults and the elderly.

Safety and regulation

The safety of non-nutritive sweeteners is rigorously evaluated prior to approval for use; the responsibility for these evaluations lies with regulatory bodies such as EFSA, the Joint Expert Committee on Food Additives and the Food and Drug Administration and safety evaluations usually result in the assignment of an acceptable daily intake (ADI). The ADI, which is calculated following the application of large safety factors to the no observed adverse effect level (Fig. 1), is regarded as the quantity of a food additive that can be ingested on a daily basis over a lifetime without appreciable health risk. The ADI is an often mis-interpreted value; it does not represent a threshold between safe and unsafe but rather, it is a calculated value, derived by dividing the NOAEL (no observed adverse effect level) observed in toxicology studies by a safety factor^{(Reference Magnuson, Carakostas and Moore14)}. The NOAEL is the daily amount consumed in long-term, repeated-dose studies that was shown to have no adverse effects in the most sensitive animal model; in other words, it is a level of daily intake that is too low to cause any biological effects. The safety factor (often a factor of 100 times lower than the NOAEL) is then applied to ensure protection of the most susceptible and sensitive individuals in an entire population, including children and pregnant women (Fig. 1). This calculation for ADI represents a much greater safety factor than exists for most nutrients and other naturally occurring food components. Therefore, the ADI is a level of daily intake considered safe for everyone, including those with the highest potential exposure to an ingredient (or LES).^{(Reference Benford15)}

Fig. 1. (Colour online) Safety factors applied to establish the acceptable daily intake (ADI). NOAEL, no observed adverse effect level. Source: Logue et al.^{(Reference Logue, Dowey and Strain21)}

Within the EU there are currently eleven LES approved for use (Table 3) and, in accordance with the EU Regulation 1333/2008 on food additives⁽¹⁶⁾, the use of LES in a food or beverage, in most cases, must also result in an energy reduction of at least 30 % in the food/beverage product. For consumers this means that where LES are present a significant reduction in energy intake is possible with like-for-like product swaps. However, some regulatory constraints regarding the use of LES may limit the opportunities of food reformulation^{(Reference Gibson, Ashwell and Arthur17)}. For example, under EU Regulation 1333/2008, permitted use depends on the food category or categories into which the product falls and at present LES cannot be incorporated into fine baked products (e.g. cakes or biscuits).

Table 3. Intense sweeteners approved for use in Europe

ADI, acceptable daily intake; BW, body weight.

* Sweetness relative to sucrose.

Source: Adapted from Logue et al.^{(Reference Logue, Dowey and Strain21)}

Current intakes of low-energy sweeteners

The most recent review of available data on global intakes of LES^{(Reference Martyn, Darch and Roberts18)} raised no concerns with respect to exceedance of the ADI for individual LES across healthy population groups. However, the authors recommended that quality dietary data were needed and a more standardised approach be adopted to allow monitoring of potential changes in exposure over time (e.g. in response to sugar reduction strategies or change in product formulation). In particular, the authors recommended that consideration should be given to intakes in individuals likely to be higher consumers of LES, such as those with type-2 diabetes or those on weight-loss diets^{(Reference Martyn, Darch and Roberts18)}. Recent trend data from the US National Health and Nutrition Examination Survey cohort, collected in five 2-year cycles from 1999–2000 to 2007–2008 using a single 24-h recall, was used to determine trends in LES intakes over time^{(Reference Sylvetsky, Welsh and Brown19)}. Whilst no observed changes in energy intakes over time were observed, the percentage of children consuming foods and beverages containing LES nearly doubled (8·7 % in 1999–2000 to 14·9 % in 2007–2008) with the percentage of the adults consuming LES-containing foods/beverages increasing from 26·9 to 32·0 %^{(Reference Sylvetsky, Welsh and Brown19)}. The data also suggested that the consumption of LES-containing beverages also doubled among US children over the past decade with an estimated 12·5 % of children consuming beverages with LES in 2007–2008^{(Reference Sylvetsky, Welsh and Brown19)}. Increased consumption has been sustained with cross-sectional National Health and Nutrition Examination Survey data from 2009 to 2012 suggesting that 25·1 % of children and 41·4 % adults reported consuming foods/beverages containing LES (obtained from two 24-h recalls)^{(Reference Sylvetsky, Jin and Clark20)}. However, it was acknowledged that these self-reported intake data (obtained from one–two 24-h recalls), and the lack of information on the specific type or quantity of LES in foods or beverages in the US Department of Agriculture database, mean that it is not possible to determine actual intakes of LES (either as total LES intake or intakes of individual LES) within this cohort. European intake assessments generally do not indicate a concern among average or high-level healthy consumers of all ages in Europe under the typical conditions of use for all LES considered using tiered assessment approached (i.e. Tier 3 using estimates of actual food consumption and usage levels). More recent studies have generally indicated a reduction in LES intakes in various EU countries, although differences in study design limit comparisons between these studies and thus should be interpreted with caution^{(Reference Martyn, Darch and Roberts18)}. It has been highlighted that certain subgroups of the population such as young, individuals with diabetes, phenylketonuria or with severe cow's milk protein allergy and who are consumers of foods for special medical purposes that are sweetened to increase palatability may have higher intakes of specific LES^{(Reference Martyn, Darch and Roberts18)} and may thus warrant closer monitoring.

It is worth noting that LES are now more commonly used as part of blends in food/beverage products to achieve desired taste profiles of products. This should be of interest when investigating the potential health impacts of LES-use as LES have different biological fates following ingestion^{(Reference Magnuson, Carakostas and Moore14)}. As such, research approaches should aim to discern intakes of individual and blends of LES so that potential relationships with health can be properly explored. However, achieving this in practice using traditional methods of intake assessment may prove challenging as the use of LES is continuously evolving and manufacturers in most countries are not required to reveal the quantities of LES used in products.

Several methodologic issues have been highlighted in relation to assessing LES intakes^{(Reference Logue, Dowey and Strain21)}. In addition to foods/beverages, LES may also be present in a variety of personal care products such as toothpaste, mouthwash, dietary supplements and over-the-counter medications^{(Reference Logue, Dowey and Strain21)}. This can pose difficulties for researchers who may wish to include a non-consumer group in that instructions to avoid LES need to consider both dietary and non-dietary sources (e.g. personal care products)^{(Reference Sylvetsky, Blau and Rother22)}. For example, a recent study which aims to recruit healthy volunteers who self-reported to be non-consumers of LES, found that over 30 % were exposed to sucralose at baseline and/or before randomisation, and nearly half were exposed after assignment to the control^{(Reference Sylvetsky, Walter and Garraffo23)}. This shows that instructions to avoid LES are not effective and that non-dietary sources (e.g. personal care products) may be important contributors to overall exposure. In a small study of twenty lactating mothers, LES (namely sucralose, acesulfame-K and saccharin) have also been shown to pass into breast milk^{(Reference Sylvetsky, Gardner and Bauman24)}. In addition, these LES were found in the breast milk of 65 % of these lactating women who had been enrolled in the study, irrespective of their history of LES usage; again highlighting the ubiquitous nature of LES. Furthermore, several LES have gained attention as potential environmental contaminants owing to their persistence in the environment, which in turn may, over time, lead to further inadvertent exposure to certain LES. Concentrations of some LES (e.g. sucralose, acesulfame-K) of up to µg/l have been observed in soil, waste water and surface water with the measured concentrations^{(Reference Lange, Scheurer and Brauch25)}. For LES with the highest environmental concentrations (namely acesulfame-K and sucralose), levels in drinking-water (and other tested matrices) are three to four orders of magnitude below the ADI values for LES^{(Reference Lange, Scheurer and Brauch25)}. However, with the persistence of these LES within the environment, along with increasing use, this source of inadvertent exposure may become more significant in the coming years and therefore be of interest as part of investigations of the health impacts of LES.

Health impacts of low-energy sweeteners

The potential health impacts of using LES is a topic of ongoing debate despite the stringent safety evaluations prior to their approval for use. A significant number of reviews have been published dealing with a range of health outcomes such as weight status^{(Reference Rogers, Hogenkamp and de Graaf26,Reference Azad, Abou-Setta and Chauhan27)} , type-2 diabetes^{(Reference Imamura, O'Connor and Ye28)}, cancer^{(Reference Weihrauch and Diehl29)} and preterm delivery^{(Reference La Vecchia30)}. However, to date, adverse health impacts of LES use have not been conclusively established, although significant gaps in the literature exist that should be addressed going forward. One important and widely accepted benefit that has been endorsed by EFSA⁽³¹⁾ is the reduction in tooth demineralisation when LES are used in place of nutritive sweeteners.

A brief summary of the evidence in relation to several selected health outcomes is provided below.

Limitations of current approaches to investigating the health impacts of low-energy sweeteners

As highlighted by ANSES⁽⁴⁰⁾ future research should aim to more effectively evaluate the intakes of individual LES with consideration given to the potential effects of individual LES as well as multiple LES use. Since current assessment investigations of LES intakes in relation to health often only consider certain sources of LES (such as LES-beverages) and/or consider LES as a homogeneous group despite their known differing biological fates^{(Reference Magnuson, Carakostas and Moore14)}, it is unlikely that these approaches adequately capture intakes of individual LES, or allow reliable estimation of overall intakes, thus limiting the possibility of robust evaluation of their potential impact of health. Biomarker approaches for sugar consumption and LES consumption and represent interesting developments in an area of significant public health interest^{(Reference Logue, Dowey and Strain42)}.

Estimation of δ ¹³C value

The first approach is based on different discrimination against carbon dioxide formed from the ¹³C and ¹²C isotopes in plants^{(Reference Jahren, Saudek and Yeung44)}. In brief, crop species have been classified as C3 and C4 plants depending on their photosynthetic pathway. The photosynthetic pathway of C3 plants, such as sugarbeet, discriminates against ¹³CO₂ compared with ¹²CO₂, and the resulting plant mass carbon has a lower δ ¹³C than atmospheric CO₂. In contrast, the photosynthetic pathway of C4 plants, such as sugarcane and maize, is almost all is almost non-discriminating against ¹³C, resulting in a plant mass higher in ¹³C compared with C3 plants. In the USA added sugar is mostly derived (78 %) from maize or maize derivatives (such as high-fructose maize sugar) or sugarcane (i.e. C4 plants) whereas in Europe it is the opposite with the majority of added sugar (80 %). Thus as a biomarker of added sugar intake, blood plasma or finger prick δ ¹³C has been largely limited to use in US populations^{(Reference Hedrick, Davy and Wilburn45)} since in the US added sugar is mostly derived (78 %) from sugarcane or maize (i.e. coming from C4 crops), whereas in Europe it is the opposite with the majority of added sugar (80 %) derived from sugarbeet which are C3 crops.

Estimation of urinary sugars

The second approach for estimating sugar intake uses urinary sucrose and fructose as exposure markers^{(Reference Luceri, Caderni and Lodovici46)}. Urinary sugars have been validated^{(Reference Tasevska, Runswick and McTaggart47)} as dietary biomarkers of total sugars (i.e. the sum of intrinsic, milk and free sugars) and sucrose^{(Reference Tasevska48)}, and can help to resolve the discrepancy between self-reported and actual intake. This biomarker relies on the total excretion of sucrose and fructose within 24-h and therefore requires complete 24-h urine samples. More recently, Campbell et al.^{(Reference Campbell, Tasevska and Jackson49)} used this urinary biomarker in a nationally-representative sample of the UK adults and demonstrated positive associations between total sugar intake, measures of obesity and likelihood of being obese within the cohort. The authors noted that this was the first time such an association has been demonstrated using a validated biomarker approach^{(Reference Campbell, Tasevska and Jackson49)}. However, it is worth noting that no comprehensive dietary intake data was collected in this study and it did not set out as a validation study and as acknowledged by the authors this biomarker of total sugars is potentially useful but remains to be fully validated and characterised in different population groups and to be characterised further in terms of its biases, performance, reliability, sensitivity etc. A metabolomics-based strategy was applied to objectively assess intakes of SSB and identified a panel of four urinary biomarkers (formate, citrulline, taurine and isocitrate) indicative of SSB consumption from a national food consumption survey and have subsequently validated this panel of urinary biomarkers in an acute intervention study as markers of SSB intake showing that following acute consumption of an SSB drink, all four metabolites increased in the urine^{(Reference Gibbons, McNulty and Nugent50)}. However, future work is needed to ascertain how to translate this panel of markers for use in nutrition epidemiology. More recently, metabolomics to investigate the metabolic impact of acute sucrose exposure and highlighted sixteen major metabolite signals in urine and twenty-five metabolite signals in plasma that were discriminatory and correlated with acute exposure to sucrose intake^{(Reference Beckmann, Joosen and Clarke51)}. However, as only one component of total/added/free sugars, the application of this method in relation to sugar intakes is perhaps limited.