Assessments of diet in epidemiological studies are usually based on self-report methods but the validity of these methods is dependent on the accuracy with which participants record their dietary intake. Misreporting, particularly under-reporting (UR), of energy intake (EI) in self-reported dietary methods is a well-documented phenomenon (Prentice et al. Reference Prentice, Black, Coward, Davies, Goldberg, Murgatroyd, Ashford, Sawyer and Whitehead1986; Livingstone et al. Reference Livingstone, Prentice, Strain, Coward, Black, Barker, McKenna and Whitehead1990; Black et al. Reference Black, Prentice, Goldberg, Jebb, Bingham, Livingstone and Coward1993). It has been observed in adults (Livingstone et al. Reference Livingstone, Prentice, Strain, Coward, Black, Barker, McKenna and Whitehead1990; Black et al. Reference Black, Prentice, Goldberg, Jebb, Bingham, Livingstone and Coward1993) and children (Bandini et al. Reference Bandini, Schoeller, Cyr and Dietz1990; Livingstone et al. Reference Livingstone, Coward, Prentice, Davies, Strain, McKenna, Mahoney, White, Stewart and Kerr1992; Bratteby et al. Reference Bratteby, Sandhagen, Fan and Samuelson1997) and it has been frequently observed to be greater in overweight and obese individuals than those of healthy weight (Prentice et al. Reference Prentice, Black, Coward, Davies, Goldberg, Murgatroyd, Ashford, Sawyer and Whitehead1986; Lichtman et al. Reference Lichtman, Pisarska, Berman, Pestone, Dowling, Offenbacher, Weisel, Heshka, Matthews and Heymsfield1992). The assessment of UR is therefore an important consideration when examining associations between EI, macronutrients, micronutrients or toxic substances in foods and excess weight gain and/or obesity-related diseases.
The doubly-labelled water (DLW) method provides an accurate measure of total energy expenditure (TEE) (Schoeller & van Santen, Reference Schoeller and van Santen1982; Murgatroyd et al. Reference Murgatroyd, Shetty and Prentice1993) which, on the assumption that TEE equals EI, can be used as an indirect biomarker of EI and used to determine the extent of UR in self-report dietary measures (Schoeller, Reference Schoeller2002; Livingstone & Black, Reference Livingstone and Black2003). However, cost inhibits its use in large studies. Assessing UR in population-based studies thus usually relies on predictions of TEE requirements. Most commonly, reported dietary intake is expressed as a multiple of BMR estimated from equations and a cut-off applied, below which subjects are identified as low-energy reporters (Goldberg et al. Reference Goldberg, Black, Jebb, Cole, Murgatroyd, Coward and Prentice1991). Although it can be applied to individuals, the ‘Goldberg cut-off’ technique was devised primarily to evaluate UR at a group level. It displays high sensitivity in identifying UR in sedentary subjects, but is limited in detecting UR in subjects with higher energy expenditures. This method introduces systematic bias in the assessment of UR since it assumes a sedentary lifestyle and low TEE and thus is not able to identify UR in individuals with high TEE.
The present study compares a method of estimating UR, using individualised estimates of energy requirements, against the Goldberg cut-off method in evaluating UR of EI in the 2000 National Diet and Nutrition Survey (NDNS) and against DLW measures of TEE in the NDNS feasibility study.
Experimental methods
The NDNS is a programme of cross-sectional surveys of different population age groups designed to be representative of Great Britain. This analysis uses the sample of adults aged 19–64 years studied in the NDNS 2000 and also the NDNS feasibility study undertaken in 200 adults in 1999.
National Diet and Nutrition Survey: main survey
This analysis includes 1551 adults from the NDNS main survey who had complete diet and physical activity diaries and anthropometric measurements. The sample design and method for the survey have been described in more detail elsewhere (National Diet and Nutrition Survey Technical Report; Social Survey Division of the Office of National Statistics et al. Reference Bates, Quigley, Birch, Coward and Prentice2002).
National Diet and Nutrition Survey feasibility study
The feasibility study for the proposed NDNS survey of adults was carried out by the Social Survey Division of the Office of National Statistics and Medical Research Council Human Nutrition Research, with the University of Newcastle Dental School. The fieldwork for this feasibility study took place in 1999 before the main survey in order to test the feasibility of the proposed design and methods, including comparing the reported EI from the 7 d dietary record with TEE assessed by DLW to assess both the face and concurrent validity of the dietary assessment.
A sample of 200 subjects aged 19–64 years living in private households in Great Britain was selected. It was not representative of the population as a whole, but included equal numbers of men and women across the age groups in the main survey. Adults aged 19–64 years, not pregnant or breast-feeding, were eligible to take part. Eighty subjects were asked to undertake 10 d of DLW measurements whilst completing the 7 d dietary record and a physical activity diary. Seventy-six subjects agreed fully to the protocol (Social Survey Division of the Office of National Statistics et al. Reference Bates, Quigley, Birch, Coward and Prentice2002) and data on EI and TEE from DLW were available for sixty-four subjects. Four subjects with fewer than 6 d of physical activity data were excluded from these analyses. The present analyses are therefore based on sixty subjects (thirty-nine women and twenty-one men) with complete data.
Measurements
The following measurements were undertaken in both the main NDNS and the NDNS feasibility study.
Reported energy intake
Subjects were asked to complete a 7 d weighed dietary record. This consisted of a ‘home record’ diary and an ‘eating out’ diary to record all food and drink items consumed at home or prepared at home but eaten elsewhere and all food and drink items consumed outside of the home respectively. All leftovers were described and weighed. Subjects were asked to record a full description of the item including brand name, where and when it was eaten, portion size and details of any leftovers. Further information on unweighed foods purchased from food outlets was obtained by interviewers. Where necessary, duplicate items were purchased in order to weigh the product. For food or drink purchased at the workplace or college, the interviewer visited the canteen and collected further information from the catering manager.
After the first 24 h of dietary recording, interviewers called on the subjects to ensure that recording was being undertaken correctly. The interviewer made at least one further visit during the recording week, with the total number of visits depending on how much support the subject appeared to need.
A food code list, containing over 6000 item codes, was prepared by the nutritionists for use by the interviewers. All items recorded were assigned a code, which were linked to a nutrient composition database to assign nutrient intakes for each item. Total energy (kJ) consumed during the survey week from all food and drink items was calculated by nutritionists from the Office of National Statistics and mean daily EI computed. Further details of the recording and coding procedures can be found elsewhere (Henderson et al. Reference Henderson, Gregory, Irving and Swan2002).
Anthropometric measurements
Interviewers measured each subject's weight and height. Subjects were classified as having a healthy weight (BMI < 25 kg/m2), being overweight (BMI ≥ 25 and < 30 kg/m2) or obese (BMI ≥ 30 kg/m2).
Physical activity
Subjects completed a physical activity diary concurrently with the 7 d dietary record. The subjects were asked to record, to the nearest 10 min, how long they spent doing various activities on that day. This included time spent sleeping, walking, at work, participating in leisure-time and sports activities and any other activities not listed. The physical activity diary was adapted from a previous survey in young people and has not been validated against an objective measure of physical activity (Social Survey Division of the Office of National Statistics et al. Reference Bates, Quigley, Birch, Coward and Prentice2002). Time spent daily in sleep, light, moderate and vigorous intensity activities was computed for each day of recording. The time spent in each type of activity was multiplied by a metabolic equivalent (MET) value to give total MET hours of activity per d. The MET value reflects the intensity of the activity as a multiple of one MET (Ainsworth et al. Reference Ainsworth, Haskell, Leon, Jacobs, Montoye, Sallis and Paffenbarger1993, Reference Ainsworth, Haskell and Whitt2000). The MET values used were 1.0 for sleep, 2.0 for light-intensity, 3.5 for moderate-intensity and 6 for vigorous-intensity activities. These were summed to give a mean MET score for the week and were then divided by 24 h to give an activity physical activity level (aPAL). The aPAL is a multiple of BMR and therefore represents the activity level of each subject as a ratio of BMR.
Estimated energy requirements and dietary physical activity level
Estimated energy requirements (EER) for each subject were calculated using the 2002 Institute of Medicine of the National Academies published Default (Institute of Medicine of the National Academies, 2002). The equations are sex- and age-specific and are based on the age, weight and height of the subject and are derived from collated DLW energy expenditure data. They allow for four levels of activity; sedentary (aPAL ≥ 1·0 < 1·4), low activity (aPAL ≥ 1·4 < 1·6), active (aPAL ≥ 1·6 < 1·9) and very active (aPAL ≥ 1·9 < 2·5) with a corresponding activity coefficient in the EER equations. The equations developed for use in lean to obese adults were used. Each subject was assigned an activity level based on his or her aPAL score and EER calculated. Dietary PAL (dPAL) was calculated as reported EI:BMR and expressed as this ratio.
Estimated under-reporting
In the NDNS feasibility study measurements of TEE from DLW were used to calculate the extent of UR (TEE – EI) for each subject. In the main NDNS, no measures of TEE by DLW were undertaken and therefore two different methods were used to estimate potential UR in this population. The two estimation methods were also applied to the NDNS feasibility study so that they could be compared with the gold standard UR measure using DLW.
The first estimation method calculated the number of under-reporters using the established Goldberg cut-off based on dPAL (Goldberg et al. Reference Goldberg, Black, Jebb, Cole, Murgatroyd, Coward and Prentice1991). This cut-off is a population-based method that takes into account the size of the sample population and the number of days of dietary intake records. In the present study the value using the lower 95 % CI was applied. This lower confidence limit represents the value below which it is statistically unlikely that the reported mean intake represents either ‘habitual’ intake or a low intake obtained by chance. For the main NDNS this was dPAL < 1·54 and for the NDNS feasibility study was dPAL < 1·48, the differences reflecting differences in sample size.
The second method used the EER predictive Default (EER – reported EI) for each individual in kJ/d. Since normal day-to-day variation in EI and in energy expenditure exists, exact agreement between EI and expenditure over 7 d in an individual is unlikely. Therefore confidence limits of agreement between reported EI and EER, and thus the limitations of EER for identifying under-reporters at the individual level need to be calculated, using the method described by Black & Cole (Reference Black and Cole2000). This is calculated as follows:
where CVt is the CV for both energy expenditure and EI, d is the number of days of dietary recording and CVEE and CVEI are the CV for energy expenditure and EI respectively.
The CVEI calculated from the NDNS feasibility study was 27·9 % and the CVTEE for TEE measured by DLW was taken from DLW studies of 7 d duration (8·2 %) (Black & Cole, Reference Black and Cole2000). This gave a total value (CVt) of 13·4 %. The CVEI calculated from the main NDNS was 31 %, and since the EER equations were based on DLW studies, the CVEE for EER was also taken from DLW studies of 7 d duration (8·2 %). This gave a CVt of 14·3 % for the main NDNS.
Illness and dieting during the survey recording period
In the main NDNS subjects were asked for each day of the recording period, ‘did illness affect your eating?’. These questions were coded and a binary variable on whether illness affected eating during the 7 d recording period was calculated for each subject. In the main survey fifty-one (7 %) men and 126 (15 %) women reported that their eating was affected by illness during the recording period. Subjects who reported that they were dieting to lose weight during the recording period were also identified (eighty-one men and 202 women). This information was not available for the NDNS feasibility study.
In the main NDNS, all analyses were undertaken with and without two groups of subjects whose eating was affected by either illness or self-reported dieting during the period of diet recording.
Statistical methods
Positive differences between EER and reported EI are described here as UREER and between TEE and reported EI as URTEE. Results for anthropometric variables and physical activity levels are expressed as mean values and standard deviations and for non-parametric variables, such as estimated UR (kJ/d), which could not be normalised, as medians and interquartile ranges. Inter-individual differences in the extent of UR, EI and energy expenditure were assessed using the Mann–Whitney U test and Kruskal–Wallis one-way ANOVA to test for differences between age groups and BMI status. Pearson χ2 was used to test for differences between the number of subjects identified as under-reporters by each method. In the main NDNS in the absence of a gold standard measure, the two methods of identifying UR were compared by calculating the positive and negative predictive value. Values of P < 0·05 were regarded as statistically significant and all statistical analyses were performed using SPSS (version 11.0; SPSS Inc., Chicago, IL, USA).
Results
National Diet and Nutrition Survey feasibility study
The mean age was 43 (sd 10·2) years in men and 43 (sd 12·7) years in women. The prevalence of obesity was 14 % in men and 18 % in women with a mean BMI of 26·3 (sd 3·1) and 26·9 (sd 5·8) kg/m2 in men and women respectively. Reported EI and TEE measured by DLW were significantly higher in men than in women (EI 11·4 v. 8·3 MJ/d respectively (P < 0·001); TEE 13·7 v. 10·0 MJ/d respectively (P < 0·001)).
When TEE was measured by DLW, there was evidence of UR in both men and women (median URTEE: men 1935 (interquartile range 804, 4365) kJ/d, women 1485 (interquartile range 895, 3571) kJ/d). When estimated, UREER was not significantly different between the sexes when expressed as a percentage of energy needs (100 × (EER – reported EI)/EER), equating to a median 18 and 19 % of energy needs in men and women respectively. There were no significant differences in the degree of URTEE with age or with obesity status in this small sample (data not shown). No subjects were identified as over-reporters by either the DLW or EER method.
Estimated UREER and UR using the Goldberg method were not significantly different from measured URTEE in either men or women. We undertook a sensitivity and specificity analysis for each method compared with the TEE measured by DLW. Sensitivity of the EER method compared with TEE measurements was 75 % in men and 92 % in women and specificity was 78 % in men and 67 % in women. By measured TEE 57 % of men and 62 % of women were identified as under-reporters, by the Goldberg cut-off method 62 % of men and 77 % of women and by the EER method, 52 % of men and 69 % of women respectively. These proportions by the different UR methods were not statistically different.
Main National Diet and Nutrition Survey
A total of 1612 subjects had valid weight and height measurements from which to calculate BMI. Complete data were available for 696 men and 855 women. Age was 42 (sd 12) years in both men and women and BMI was 27·1 (sd 4·3) kg/m2 in men and 26·5 (sd 5·7) kg/m2 in women. The prevalence of obesity was 24 % in men and 21 % in women. There were no significant differences between the main NDNS and the feasibility study in these characteristics.
EI was significantly higher in men than in women (9·8 v. 7·0 MJ/d respectively; P < 0·001) and significantly lower than the reported EI in the feasibility study in both men and women (P < 0·001). There was no association between reported EI with age group or with BMI status in men. These observations were unchanged when those reporting to be dieting or ill during the recording period were excluded (Tables 1 and 2). However, in women, reported EI was significantly lower in older women (P = 0·047) and in those that were overweight or obese compared with their lean counterparts (P = 0·02). When those who reported dieting or being ill during the recording period were removed, these associations with age and weight status in women were no longer significant (Table 2).
Trend was significant: * P < 0·05, ** P < 0·001.
† Total sample population.
‡ Excluding those who reported dieting or whose eating was affected by illness during the recording period.
Trend was significant: * P < 0·05, ** P < 0·001.
† Total sample population.
‡ Excluding those who reported dieting or whose eating was affected by illness during the recording period.
EER calculated from the 2002 published equations were significantly higher in men than in women (median 13 281 v. 9770 kJ/d respectively; P < 0·001), decreased significantly in the older age groups (P < 0·001; Table 1) and were higher in overweight and obese subjects compared with their lean counterparts (P < 0·001; Table 2). dPAL was significantly higher in men than women (men 1·29 (sd 0·34); women 1·19 (sd 0·32); P < 0·001). Women in the older age groups had significantly higher dPAL than those in the younger age groups (P = 0·02), but no association with age was found in men (Table 1). dPAL was significantly lower in overweight and obese men and women compared with their lean counterparts (P < 0·001 in men and women; Table 2). When those who reported dieting or being ill during the recording period were removed, the higher dPAL in men compared with women remained (men 1·33 (sd 0·32), women 1·26 (sd 0·31); P < 0·001). However, the significant relationship observed in women between dPAL and age group was no longer apparent when those who reported dieting or being ill were removed and was also not observed in men (Table 1). However, the significant associations observed between the sexes and with weight status remained (P < 0·001) (Table 2).
Median estimated UREER was 3503 kJ/d in men and 2827 kJ/d in women, equivalent to a median 27 % of energy needs in men and 29 % in women. Expressed as absolute EI (kJ/d), estimated UREER was significantly higher in men than women (P < 0·001), but higher in women when expressed as a percentage of energy needs (P = 0·03). Only twenty-six (1·6 %) subjects (fifteen men and eleven women) were classified as over-reporters. UREER was lower in the older age groups in both men and women (P < 0·001; Fig. 1) and significantly higher in overweight and obese men and women compared with their lean counterparts (P < 0·001; Fig. 2). When those subjects who reported being unwell or dieting to lose weight during the dietary recording period were excluded from the analysis, UREER was still significantly higher in men than women in absolute terms (3230 v. 2384 kJ/d respectively; P < 0·001) but there was no longer a difference between the sexes when expressed as a percentage of energy needs (men 25·0 %, women 24·6 %; NS). The same significant relationships were observed, as identified in the whole sample, with UREER being lower in older age groups and higher in overweight and obese subjects compared with their lean counterparts (P < 0·001; Figs. 1 and 2 respectively). When subjects who reported being unwell or dieting were excluded, the number of men and women identified as under-reporters was lower (Table 3).
* Total sample population.
† Excluding those who reported dieting or whose eating was affected by illness during the recording period.
Comparison of the UREER method and Goldberg cut-off method showed that 89 % of men and 88 % of women identified as under-reporters by the UREER method were also identified as under-reporters by the Goldberg method. When those subjects who reported being unwell or dieting were excluded, the agreement between the two methods was similar (89 % in men and 86 % in women respectively). Similarly, 79 % of men and 94 % of women classified as adequate reporters by the EER method were also identified by the Goldberg cut-off, with little change when those unwell or dieting were excluded (80 % of men and 96 % of women respectively).
Discussion
In this analysis there was no difference in sensitivity and specificity between the Goldberg cut-off and EER method in classifying subjects as under-reporters or adequate reporters (between 79 and 96 %). However, the EER method has advantages over the Goldberg cut-off method as it allows a quantification of UR of EI, producing a continuous variable that can be used in analyses, whereas with a cut-off the only option is to exclude subjects who are classified as under-reporters. Given the extent of UR in dietary surveys, exclusion of a large proportion of under-reporters identified by a cut-off may introduce considerable bias. In addition, the UR method with EER, using individual reported activity data to estimate energy requirements, could be more sensitive than generalised predictions, for example in comparing levels of UR between populations with different levels of physical activity. This allows an assessment of subject-specific bias that is useful in interpreting data from dietary surveys, particularly in determining secular trends in UR and EI in surveys.
In large dietary surveys the extent of UR can only be estimated since measuring TEE by the DLW method is not feasible. As in this national survey, the use of the DLW method is inhibited by the expense of the method. Furthermore, the introduction of this measure with additional participant burden into surveys, which are designed to be nationally representative, may lead to a less representative population sample and thus introduce bias. Therefore, in this survey a feasibility study was undertaken before the main survey in which TEE was measured by DLW in a sub-sample to assess the level of UR. There was no difference in mean age, BMI or prevalence of obesity between the sub-sample in the feasibility study and the main survey. However, median reported EI was higher in the feasibility study sample than the main NDNS survey. This suggests that the level of UR or under-eating during the recording period may have been higher in the main survey compared with the feasibility study. A limitation of the present study is the estimation of TEE in the main survey rather than a direct measure of TEE by DLW. We have used predictive equations of energy requirements (Institute of Medicine of the National Academies, 2002) to estimate energy requirements in the main survey and have found the estimation of UREER using these equations comparable with URTEE measured by DLW. The predictive equations themselves were based on DLW, which provides objective measures of TEE over a period of at least 7 d. However, since 7 d measurements of EI and energy expenditure are not a true measure of habitual intake and expenditure, we have applied the lower 95 % CI on the absolute values of UR to allow for day-to-day variation.
The EER equations allow adjustment for physical activity level, with four categories. We used data from the physical activity diary, which was completed concurrently with the weighed dietary record, to calculate aPAL for each individual to determine the most appropriate activity category on an individual basis. However, as with dietary intake, there is the potential that physical activity may be under- or over-reported or altered during the recording period. Over-reporting of physical activity is probably the primary concern in surveys and this may introduce positive bias. Despite this limitation, the sensitivity and specificity with measured URTEE using DLW in the feasibility study suggest that this method gives a good estimate of the extent of UR in this population sample.
Huang et al. (Reference Huang, Roberts, Howarth and McCrory2005) recently used these predictive equations to assess UR in a dietary survey of adults where diet was assessed by 24 h dietary recalls. However, since no measure of physical activity was made in this survey, the authors were not able to assign an activity level on an individual basis. By categorising all subjects as low active, they reported that reported EI as a percentage of EER varied considerably with UR estimated as 19·1 % of EER and as 4·6 % of EER if a 1·0 sd cut-off was applied.
Using individualised EER, analyses from the present study suggest that there is substantial UR of EI in the NDNS, equivalent to 27 % of energy needs in men and 29 % in women. After excluding those subjects who reported their eating being affected by dieting or illness during the recording period, UR was approximately 25 % of energy needs in both men and women, with 73 % of men and women categorised as ‘under-reporters’. As reported in other studies, we observed higher UR in overweight and obese adults compared with those of healthy weight (Prentice et al. Reference Prentice, Black, Coward, Davies, Goldberg, Murgatroyd, Ashford, Sawyer and Whitehead1986; Lichtman et al. Reference Lichtman, Pisarska, Berman, Pestone, Dowling, Offenbacher, Weisel, Heshka, Matthews and Heymsfield1992; Heitmann & Lissner, Reference Heitmann and Lissner1995; Voss et al. Reference Voss, Kroke, Klipstein-Grobusch and Boeing1998), with estimated UR as percentage of energy needs being 39 % and 57 % higher in obese men and women respectively compared with their lean counterparts. In a review of DLW studies, mean UR of energy in normal-weight adults was 16 (range 0–25) %, whereas in obese subjects it was two-fold (41 (range 25–50) %) (Westerterp & Goris, Reference Westerterp and Goris2002). When reported EI was expressed as a ratio of BMR (dPAL), we found the ratio was lower in women than in men and in overweight and obese individuals than those of healthy weight, reaching physiologically implausible levels in overweight and obese women in particular. However, in the present study it is not possible to determine whether obese individuals systematically under-report specific foods than their lean counterparts or proportionately under-report all foods. This confounds attempts to analyse dietary factors associated with obesity.
An assessment of UR in the NDNS of young people in 1997, estimated using similar methods, found that young individuals under-reported their EI by 20–21 % of energy needs (Rennie et al. Reference Rennie, Jebb, Wright and Coward2005). The extent of UR in the NDNS is comparable with other studies. A review of DLW validation studies of reported intake found UR of EI in free-living adults was substantial but individually variable, with a mean reported EI of >20 % below TEE (Livingstone & Black, Reference Livingstone and Black2003). Expressed as a percentage of energy needs, UREER was significantly higher in women, but when expressed as absolute values was higher in men, reflecting their higher energy needs. In contrast, a review of DLW found no difference between the sexes when expressed as absolute values (kJ/d) (Westerterp & Goris, Reference Westerterp and Goris2002).
Comparison with the 1986–7 Dietary and Nutritional Survey of British Adults shows that reported EI has not increased between the 1986–7 and the 1997 survey (Pryer et al. Reference Pryer, Vrijheid, Nochols, Kiggins and Elliott1997). Mean EI were 10·3 MJ/d in men and 7·0 MJ/d in women in 1986–7 and 9·8 MJ/d in men and 7·0 MJ/d in women in NDNS. The absence of an increase in reported EI has also been observed in US dietary surveys (Borrud et al. Reference Borrud, Wilkinson-Enns and Mickle1997; Norris et al. Reference Norris, Harnack, Carmichael, Pouane, Wakimoto and Block1997), which could be interpreted as evidence that decreasing activity lies at the root of the rising prevalence of obesity. However, this does not take into account a possible increasing trend of UR of EI over time.
Mean dPAL reported in population-based studies in the last two decades ranges from 1·22 to 1·48 in women and 1·38 and 1·58 in men (Smith et al. Reference Smith, Webb and Heywood1994; Briefel et al. Reference Briefel, Sempos, McDowell, Chien and Alaimo1997; Lafay et al. Reference Lafay, Basdevant, Charles, Vray, Balkau, Borys, Eschwege and Romon1997; Pryer et al. Reference Pryer, Vrijheid, Nochols, Kiggins and Elliott1997; Johansson et al. Reference Johansson, Solvoll, Bjorneboe and Drevon1998), with no apparent trend in dPAL values. However, to investigate secular trends in UR, a measure of physical activity concurrent with the dietary recording is necessary. Unfortunately there are no objective data available on which to evaluate secular trends in physical activity.
The under-estimation of EI in comparison with TEE or EER cannot distinguish between UR and under-eating during the recording period (Goris et al. Reference Goris, Westerterp-Plantenga and Westerterp2000). Under-eating while recording food intake has been observed in lean and obese adults (Westerterp & Goris, Reference Westerterp and Goris2002), since subjects take the opportunity to change their eating behaviour during recording, particularly dieting to lose weight. This could be identified by weighing the subjects before and after the dietary recording period if the recording period is sufficiently long enough to detect weight changes rather than day-to-day fluctuations. To partially adjust for this, analyses were undertaken with the whole sample and then excluding those who reported to be trying to lose weight during the recording week. Second, there may be errors in the dietary intake measurements, including the weighing of food and liquid intake and in the analysis of the nutrient intake of food. For example, the accuracy of the energy content of reported foods and drinks are dependent on the nutrient database from which the energy values are derived. However, errors in the energy content might be anticipated to be random rather than systematic underestimation.
Conclusions
UR of EI must be taken into account when assessing dietary intake in population-based studies. UR introduces systematic bias and affects not only analyses of the major components of EI, macronutrients, but also of micronutrients and toxic substances in foods. Although this bias cannot be removed in data analysis, it needs to be taken into consideration when interpreting dietary data. Including measurements of physical activity and questions to identify under-eating during the dietary recording period may help in evaluating UR especially when comparing data from different population groups with variable activity levels. Improvements in methods to evaluate UR will help in interpreting diet–health relationships, especially in the context of obesity.
Acknowledgements
The present study was funded by the Food Standards Agency and the Medical Research Council. We thank Antony Wright for the analyses of the DLW samples and data in the NDNS feasibility study.