It is unclear how best to measure full-day dietary intake in school-age children. Two key considerations in the selection of a dietary assessment tool are accuracy and participant burden(Reference Foster and Bradley1,Reference Thompson, Subar, Coulston, Boushey and Ferruzzi2) . Accurate tools are fundamental to dietary assessment(Reference Foster and Bradley1,Reference Dhurandhar, Schoeller and Brown3) because estimates of dietary intake are used to characterise diet–disease relationships, develop dietary guidance, inform policy, evaluate interventions and identify groups at risk for poor nutrition. Dietary assessment tools with low participant burden are also essential because multi-day assessments are critical for evaluating habitual intake(Reference Dwyer, Picciano and Raiten4), and parents or children may be less likely to complete multi-day studies if the assessment tool is too burdensome(Reference Thompson, Dixit-Joshi and Potischman5). However, accuracy and burden are intertwined. Improving the accuracy of a dietary assessment tool often requires a concomitant increase in participant burden (e.g., time commitment, degree of invasiveness). The result is that assessment tools with multiple known threats to validity are frequently used to assess what children eat(Reference Dhurandhar, Schoeller and Brown3,Reference Burrows, Golley and Khambalia6) , presumably because they pose low burden and can be less expensive to administer. Tools are needed that simultaneously maximise accuracy and minimise burden.
Over the last 15 years, advancements in the science of dietary assessment focused on integrating technology into self-report tools. One of the most notable examples is the Automated Self-Administered 24-hour Dietary Assessment Tool (ASA24), a web-based dietary recall developed by the National Institutes of Health in the United States(Reference Subar, Kirkpatrick and Mittl7). Either respondents or a proxy reports intake on the preceding day from memory. The respondent website includes features designed to maximise accuracy and minimise burden: images to allow respondents to estimate portion size, a searchable food database with more than 7000 items, standardised prompts for frequently forgotten foods or meal gaps, branching logic to streamline reporting and the option to create recipes(Reference Subar, Kirkpatrick and Mittl7,Reference Timon, van den Barg and Blain8) . Yet, misreporting with the ASA24 is common(Reference Kirkpatrick, Subar and Douglass9,Reference Diep, Hingle and Chen10) , suggesting that poor recall and inaccurate estimates of portions consumed continue to threaten validity. While a few studies indicate that the ASA24 is well-accepted by respondents, opportunities may exist to reduce burden, especially related to technology use and website interface(Reference Kirkpatrick, Gilsing and Hobin11).
Another innovation in the field of dietary assessment is the Remote Food Photography Method (RFPM)(Reference Martin, Han and Coulon12). Participants’ photograph food selection and plate waste with an iOS-based smartphone and the images are converted into estimates of energy and nutrient intake(Reference Martin, Kaya and Gunturk13). The RFPM offers some advantages over the ASA24 and other self-report tools. Approximately 50 % of the error in self-report methods is due to participants’ inability to accurately estimate portion size(Reference Beasley, Riley and Jean-Mary14). This limitation is minimised with the RFPM because the portion size is estimated from the food images by a trained operator(Reference Martin, Kaya and Gunturk13). Many self-report tools require participants to recall past intake. The RFPM is a prospective record and thus eliminates measurement error due to poor recall because intake is captured in real time via photographs. The RFPM provides data on foods offered and plate waste, which can provide insight into the environmental conditions that shape what children eat(Reference Fisher, Liu and Birch15–Reference Johnson, Hughes and Cui17). Compared with other self-report methods, the RFPM may also be more viable and yield better accuracy if photographing foods is less burdensome.
Nutrition-related diseases are increasingly common among school-age children(Reference Mayer-Davis, Dabelea and Lawrence18,Reference Skinner, Ravanbakht and Skelton19) . Accurate estimates of intake are needed for this age group but may be difficult to obtain. School-age children are too young to accurately report their own intake but may have enough autonomy to consume some meals and snacks unsupervised(Reference McPherson20–Reference Raffoul, Hobin and Sacco22). Thus, parents may be proxy reporters for unobserved intake, such as foods consumed at school(Reference Bornhorst, Huybrechts and Ahrens23). It is unknown how well existing dietary assessments capture unobserved intake. Most studies with the ASA24 and RFPM have been conducted among adults or families with preschoolers(Reference Nicklas, Saab and Islam24–Reference Martin, Correa and Han26). More work is needed to understand the unique challenges for school-age children.
This study provides a novel comparison of two methods for measuring full-day dietary intake in school-age children: a parent proxy-reported ASA24(Reference Subar, Kirkpatrick and Mittl7) and the RFPM(Reference Martin, Nicklas and Gunturk27). Parent–child dyads completed two, 3-d assessments 1 week apart: one using an ASA24 and the other using the RFPM. A parent survey evaluated perceived burden with each method. The objective was three-fold: (1) to compare children’s dietary intake across methods; (2) to compare participant burden across methods and (3) to support the design of future validation studies by providing insight into data completeness, food source, eating location and reported energy intake relative to the calculated Estimated Energy Requirement (EER).
Methods
Participants
Dyads were drawn from a cohort in the Environmental influences on Child Health Outcomes (ECHO) Program (http://echochildren.org) and a community-based sample(Reference Gillman and Blaisdell28). Forty children aged 7–8 years and their parents were recruited at two sites. Thirty parent–child dyads who were part of the Healthy Start cohort(Reference Starling, Sauder and Kaar29) were recruited in the Denver metro area. Healthy Start is a prospective cohort study that recruited over 1400 pregnant women between 2009 and 2014 and is currently following offspring postnatally. The Healthy Start cohort is part of the ECHO Program(Reference Gillman and Blaisdell28). The goal of ECHO is to investigate the effects of environmental exposures on child health(Reference Tylavsky, Ferrara and Catellier30). Ten child–caregiver dyads were recruited from a single elementary school in Baton Rouge, Louisiana. The multi-site design was used to recruit the majority of participants from an ECHO cohort while also documenting feasibility among families recruited from a community-based sample. All interested dyads completed a screening questionnaire by phone and were eligible to participate if their school and school district provided institutional approval to have lunch meals photographed in the cafeteria, per the RFPM protocol.
Study design
Each parent–child dyad (n 40) participated in two, 3-d dietary assessments: a parent proxy-reported version of the ASA24 and the RFPM. The order of assessment was randomised to control for the effects of timing and fatigue. For the first assessment, consecutive or non-consecutive dates were selected a priori by the parent based on days perceived to be ‘typical’. For the second assessment, data collection occurred on the same days of the week as the first assessment. Data were collected in 2019 from January to June and September to October to avoid data collection during the school break. The study was approved by the Institutional Review Boards at the University of Colorado and the Pennington Biomedical Research Center. Parents provided written informed consent. Children provided written or verbal assent. Children attended twenty-one schools (four private, seventeen public) across three school districts. All school districts provided institutional approval. School principals provided written consent for research staff to photograph lunch meals in the school cafeteria, consistent with the RFPM protocol. Parent–child dyads were remunerated $40 for the ASA24, $40 for the RFPM and $20 for the survey.
Automated Self-Administered 24-hour Dietary Assessment Tool
The ASA24 is a web-based tool for estimating dietary intake in which participants recall all foods and beverages consumed on the preceding day, including food type, quantity, preparation mode and time of intake. Parents were proxy respondents for their children. Each parent self-administered the 2018 version of the ASA24 (ASA24-2018) to report their child’s intake on three occasions (two weekdays and one weekend day). Parents reported their perceptions of what children consumed at school, although intake was not observed, because this is consistent with the ASA24 protocol. The ASA24 provided estimates of energy and nutrient intake for each assessment day. The ASA24, utilised in over 6000 research studies, has been validated against the USDA’s Automated Multiple Pass Method and weighed food records(Reference Thompson, Dixit-Joshi and Potischman5,Reference Kirkpatrick, Subar and Douglass9) . Participants were asked to access the ASA24 website using a computer or mobile device. All parents received a 3-min training from the research team in how and when to log on to the website. No additional instructions were provided unless the participants asked for help because the ASA24 is designed to be self-administered using step-by-step instructions provided within the online platform.
Remote Food Photography Method
The RFPM and SmartIntake® smartphone app were developed at the Pennington Biomedical Research Center. The SmartIntake app was compatible with iPhones only at the time this study was conducted. Participants borrowed a ‘loaner phone’ for the study period, if they did not own an iPhone. Participants placed a reference card next to their child’s food and photographed images of the foods offered by the parent or selected by the child (the ‘before’ image) and plate waste (the ‘after’ image). The app allowed participants to record food descriptors that were automatically tagged to the image (e.g., label a glass of milk as low-fat or non-fat). Customised text reminders were sent to participants 30 min prior to each child’s usual meal or snack times(Reference Stone and Shiffman31). Participants’ responses to the text reminders were tracked in the period surrounding their usual meal and snack times, but not outside those periods. Participants’ responses to the text reminders were used to troubleshoot potential problems in near real-time, when possible (e.g., the family ate in a restaurant and forgot to bring the reference card, or the research staff sent follow-up questions when parents did not provide enough detail in the food descriptor).
The app sent food images and accompanying data (e.g., food descriptions) to a server where the Pennington Biomedical team analysed the images. The analysis relied on a computer programme built at Pennington Biomedical called the Food Photography Application©. The programme allowed the operator to identify a match for each food from the Food and Nutrient Database for Dietary Studies(32) and manufacturer’s information, to calculate the energy and nutrient content of foods offered and plate waste. Intake was calculated as the difference. The operator also used the programme and validated methodology(Reference Martin, Han and Coulon12,Reference Martin, Correa and Han26,Reference Williamson, Allen and Martin33,Reference Williamson, Allen and Martin34) to estimate portion size by visually comparing participants’ images to images of foods with a known portion size. Parents received a 30-min in-person training in best practices for capturing and sending images and entering food descriptors. Parents captured food images on the weekend and during non-school hours on weekdays. For snacks sent from home and consumed during school hours, parents were asked to photograph snacks offered in the morning and plate waste (e.g., empty wrappers) after school. For eating occasions not observed by the parent (e.g., playdates, breakfast meals provided by the school), parents probed children or alternate caregivers for details and provided text descriptions only of foods consumed and plate waste.
Research staff photographed lunchtime intake at schools. Research staff arrived at schools 30 min prior to each child’s lunchtime, checked in at the main office and were either escorted by a school staff member or walked independently to the cafeteria. Once the child arrived, the research staff approached the child, verbally re-confirmed assent, took a ‘before’ photo and entered food descriptors. The research staff waited on the side of the lunchroom, while the child consumed their lunch. The ‘after’ image was captured when the child finished eating. Excluding commute time, this process took approximately 1 h per lunch meal.
Survey
After completing the dietary assessments, parents participated in an online, twelve-question survey. The first nine questions used a Likert scale. Six questions assessed perceived burden (1 = Always Burdensome to 6 = Never Burdensome), ease of use (1 = Very Difficult to 6 = Very Easy) and satisfaction (1 = Very Dissatisfied to 6 = Very Satisfied) for each method. Three questions assessed satisfaction with the reminder text messages, the app and the in-person training for the RFPM only. Higher scores represented higher satisfaction and ease of use and lower burden. In addition to the nine Likert scale questions described above, three additional questions asked participants to select which method was most preferable with respect to their overall experience, the technology platform (ASA24 website or RFPM app) and time spent documenting intake.
Derived variables
Healthy Eating Index-2015
The Healthy Eating Index-2015 (HEI-2015) is an index that compared each child’s intake to the Dietary Guidelines for Americans 2015-2020(Reference Krebs-Smith, Pannucci and Subar35). Individual diets were scored based on the intake of ten food categories, two nutrients and one nutrient ratio. The scores for all thirteen components were summed to compute an overall score (ranged from 1 to 100). Higher scores indicated greater adherence to the guidelines(Reference Reedy, Lerman and Krebs-Smith36).
Estimated Energy Requirement
Each child’s EER was calculated based on age, sex, measured body weight and estimated physical activity level according to the established methods(Reference Trumbo, Schlicker and Yates37–Reference Henry40) to provide context for estimates of reported energy intake and preliminary data for statistical power calculations for future validation studies. The EER was calculated as the product of BMR and estimated physical activity level using two approaches: (1) the Schofield equation(Reference Schofield39) for calculating BMR and (2) the Henry equation(Reference Henry40) for calculating BMR. For both approaches, the PAL was set at a constant of 1·3, which reflects low activity levels. This physical activity level was selected based on three data sources. The first source was the 2016 Report Card on Physical Activity for Children and Youth which found low levels of sports participation, physical activity at school, health-related fitness and adherence to screen time recommendations in school-age children(Reference Katzmarzyk, Denstel and Beals41). The second source included studies among school-age children who used doubly labelled water or accelerometry to estimate physical activity and showed levels ranging from 1·1 to 1·6(Reference Brown, Katzmarzyk and Gotshalk42–Reference Komura, Nakae and Hirakawa44). In these studies, PAL of 1·1–1·4 were observed among elementary schoolchildren in the USA(Reference Brown, Katzmarzyk and Gotshalk42). Physical Activity Levels of 1·5 or 1·6 have also been observed in high-income countries, but mostly among older children and adolescents living in Europe and Asia(Reference Heydenreich, Schweter and Luhrmann43,Reference Komura, Nakae and Hirakawa44) . The third source was the Estimated Calorie Needs reported in the 2015–2020 Dietary Guidelines for Americans for children aged 7–8 years; EER calculated in the present study using a PAL of 1·3 fall within the range of Estimated Calorie Needs for children of similar sex and age(45).
Type of eating occasion, eating location and food source
Type of eating occasion, eating location and food source were assessed in both methods using drop-down menus with pre-selected answer choices. Each variable was harmonised across methods. Eating occasion was categorised as breakfast, lunch, dinner or snack. Eating location was categorised as home, school, restaurant or other (e.g., birthday party, sporting event). Food source was categorised as home-prepared, restaurant, other or do not know.
BMI
Standardised anthropometric procedures were used to assess height and weight(Reference Lohmann and Martorell46). BMI was calculated as weight (kg)/height (m2). Age- and sex-specific BMI z-scores were used to classify children as underweight (<5th percentile), healthy weight (5th percentile to less than the 85th percentile), overweight 85th percentile to less than the 95th percentile) and obese (95th percentile or greater)(47).
Statistical analysis
Power calculation
We examined power a priori for a clinically meaningful difference of 200 kcal/d between the ASA24 and RFPM. The standard deviation of the total daily energy intake (TDEI) measurements for children aged 2–9 years has been reported to be 500 kcal/d(Reference Bornhorst, Huybrechts and Hebestreit48). Since the range of ages in our study was smaller (7–8 years), we used a standard deviation that was half as large. We assumed that the ASA24 and RFPM would have a correlation of 0·9. With these inputs, at a Type I error rate of 0·05, we had power >0·95.
Descriptive analysis
We tabulated participant characteristics in the full sample and by site (Table 1). For both the ASA24 and the RFPM, we tabulated the proportion of days with at least one eating occasion documented, the proportion of days with no data and parent explanations for missing data (Table 2). For both the ASA24 and RFPM, we tabulated median (interquartile range) HEI-2015 total and component scores; macronutrient intake (g); the percentage of eating occasions consumed in each location; and the percentage of TDEI that was home-prepared, restaurant/convenience foods, other or unknown (Table 4). For survey questions on a six-point scale, we reported the median and interquartile range for each method (Table 5). A Wilcoxon signed-rank test(Reference Wilcoxon49) was used to compare median scores for burden, satisfaction and ease of use between methods. For the binary survey outcomes, we reported the proportion of participants who selected the ASA24 or RFPM as the preferred measure. Proportions were compared using McNemar’s test(Reference Eliasziw and Donner50).
* Percentages are based on the number of participants who had missing data.
Model-based statistics
For each day of intake, for each person, we computed the TDEI for both ASA24 and for RFPM. We fit a linear mixed model to assess differences between the dietary assessment methods, and differences between the dietary assessment methods and the EER. Each participant contributed seven outcomes. The outcomes included the EER and six measurements of reported TDEI – three from the ASA24 and three from the RFPM. The predictors included indicators for EER, ASA24 and RFPM. We fit an unstructured covariance structure to account for repeated measurements of reported TDEI within each participant. Model assumptions were tested using jackknife residuals. Using the Wald test with Kenward–Roger df and a Type I error rate of 0·05, we tested a series of three hypotheses. First, we tested if there were differences in reported TDEI between the ASA24 and RFPM. The contrast averaged ASA24 and RFPM measures and assessed the difference between the averages for each modality. Second, we tested if there were differences in reported TDEI with the ASA24 and the EER by comparing child-specific EER with averaged ASA24 measures. Third, we tested if there were differences between reported TDEI with the RFPM and the EER by comparing child-specific EER with averaged RFPM measures. To assess differences by sex, indicator variables for the between-participant factor of sex were added to the model and average outcome measures were computed, among girls, and among boys. The same modelling approach was used for two different EER calculations: using the Schofield equation and using the Henry equation. To examine differences in reported TDEI and EER by site, the model was further adjusted for site. Tests for differences between sites were conducted across the entire population and in subgroups stratified by site.
To support the design of follow-up studies, this study explored differences by race/ethnicity in the association between reported TDEI and the EER. All participants in Louisiana were non-Hispanic White, which meant that the effects of race/ethnicity and site could not be disentangled. Data reporting by race/ethnicity were thus restricted to Colorado children. Using the base model described above for the full sample, we added race/ethnicity as a binary predictor (non-Hispanic White or other). Each hypothesis was tested in subgroups cross-classified by both sex and race/ethnicity. All analyses were conducted in SAS 9.4.
Results
This study included forty parent–child dyads (Table 1), and 98 % of parents were mothers. Twenty-six percentage of children had a BMI at or above the 85th percentile.
Of the eighty lunches to be consumed at school during the ASA24 assessments (40 children × 2 weekday ASA24 assessments), parents provided data for fifty-seven lunches. Of the eighty lunches to be photographed in school cafeterias (40 children × 2 weekday RFPM assessments), research staff photographed sixty-one lunches. Of the nineteen weekday lunches not photographed by school staff, fourteen were consumed at home because the child was absent, the school was closed (e.g., snow day) or the child was home-schooled. The remaining five lunches were consumed at school, but not photographed because the child did not provide assent for his or her school lunch to be photographed (two lunches), no research staff were available (two lunches) or there was a miscommunication about the timing of lunch (one lunch).
Data completeness is shown in Table 2. Of 120 assigned days, the least frequently documented meal was lunch with the ASA24 (71·7 %). The most frequently documented meal was dinner with the RFPM (83·8 %). On days with any dietary data, the mean number of meals/d was 2·8 (sd 0·4) in the ASA24 and 2·6 (sd 0·7) in the RFPM; and the mean number of snacks/d was 1·1 (sd 0·3) in ASA24 and 1·5 (sd 0·7) in the RFPM.
In the full sample, reported TDEI was higher in the ASA24 compared with the RFPM (Δ (difference between the predicted means) = 379 kcal, P = 0·0002) (Table 3). In sub-group analyses by sex, reported TDEI was significantly higher in the ASA24 compared with the RFPM for boys (Δ = 567 kcal, P = 0·0002), but not girls (Δ = 190 kcal, P = 0·12). Supplementary Table 1 shows means and standard errors for reported energy intake for the ASA24 and RFPM by child sex and race/ethnicity and for two different EER calculations. Table 3 shows differences in TDEI and the EER using the EER calculated from the Schofield BMR equations. Reported energy intake with the ASA24 was 231 kcal higher than the EER (P = 0·008). Reported energy intake with the RFPM did not differ significantly from the EER (difference in predicted means = –148 kcal, P = 0·09). Findings were mostly similar when the Henry equation was used to calculate EER, although the difference between reported energy intake with the ASA24 and the EER was no longer significant among boys (online Supplemental Table 2). Differences in reported TDEI did not vary by site for the ASA24 (P = 0·85) or the RFPM (P = 0·14).
* The EER is based on the Schofield equation and a physical activity level of 1·3.
† All models included child sex.
‡ The analytic sample (n 205 d of dietary assessment) excluded days in which the participant did not report any dietary data (n 35 d).
Energy intake, macronutrient intake and HEI-2015 scores by dietary assessment method are shown in Table 4. HEI-2015 total score did not vary by assessment method (Δ = 3·0, P = 0·08) after adjustment for sex. After adjustment for sex, ethnicity and BMI category, reported intake, in g, was significantly higher in the ASA24 compared with the RFPM for protein (Δ = 16, P = 0·0001), carbohydrate (Δ = 52, P < 0·0001) and fat (Δ = 16, P = 0·0003).
* Median (interquartile range) was reported for energy, macronutrients and HEI scores because these variables were not normally distributed.
** The ‘do not know’ response option is only available in the ASA24.
Survey results are shown in Table 5. For the ASA24, mean ease of use score was higher in Colorado compared with Louisiana (4·8 v. 4·0, P = 0·03). No other survey responses differed by site. When asked which method they would rather use for 7 d, the majority of parents preferred the RFPM (Table 5). When asked which method required more time to complete, 74·4 % of parents reported that the ASA24 was more time-consuming (P = 0·002). Mean completion time for the ASA24 was 26 (sd 23) min. The in-person training for the RFPM was ‘very useful’ or ‘absolutely useful’ for 82 % of participants. Reminder text messages were ‘very useful’ or ‘absolutely useful’ for 64 % of participants. Seventy-two percentage of participants were ‘moderately satisfied’ or ‘very satisfied’ with sending photos using the app.
* Proportions compared using McNemar’s test(Reference Eliasziw and Donner50).
† Median scores compared using Wilcoxon signed-rank test(Reference Wilcoxon49). Higher scores (maximum score = 6) represent higher satisfaction and ease of use, and lower burden.
Discussion
This study was the first to conduct full-day dietary assessment with the RFPM among school-age children. We compared the RFPM and ASA24 with respect to estimates of dietary intake and participant burden. Reported TDEI and intake of carbohydrate, fat and protein were higher in the ASA24 compared with the RFPM. HEI-2015 score did not differ by assessment method. Compared with the EER, reported TDEI was overestimated with the ASA24 by 231 kcal. The difference between the EER and reported TDEI with the RFPM was not significant. Satisfaction and ease of use with both methods were high, but most parents reported that the RFPM was less time-consuming. Technological barriers to accessing the ASA24 website and parents forgetting to capture images with the RFPM contributed to missing data.
Our finding that energy intake estimates differed between the RFPM and ASA24 among boys only raises questions about whether child sex may affect the accuracy of dietary intake estimates. If future validation studies that are powered to detect differences between reported energy intake and a gold standard by sex replicate the findings observed here, this will provide an impetus for investigating the causes of sex differences in the accuracy of parent proxy-reported dietary assessments. Few studies have examined whether common sources of measurement error in dietary assessment (e.g., recall bias, social desirability bias) may be more pronounced for parents of children of a particular sex(Reference McKenzie, Coyle and Burrows51). One source of measurement error that may be specific to paediatric populations is unobserved intake, but future studies will need to determine if misreporting due to unobserved intake varies by sex. Additionally, qualitative studies could help provide insight into the causes of sex differences in measurement error, such as sex differences in social desirability bias, which has been observed among adult males v. females completing dietary recalls(Reference Hebert, Ma and Clemow52).
Scores on the HEI-2015 were remarkably similar in the ASA24 and RFPM and also closely mirrored HEI-2015 scores for a nationally representative sample of school-age children(Reference Thomson, Tussing-Humphreys and Goodman53). Thus, the type of assessment tool may have minimal impact on estimates of adherence to federal dietary guidance. Our expectation was that children would consume 3 meals/d on each assessment day, yet children consumed, on average, <3 meals/d. This may reveal a potential source of misreporting (undocumented intake) or may indicate that children in this age group are not consuming 3 meals every day. Meal skipping, possibly due to increases in snacking, was documented among adolescents in Minnesota whose intake frequencies were 4 times/week for breakfast, 5 times/week for lunch and 6 times/week for dinner(Reference Larson, Story and Eisenberg54). Nevertheless, it is likely that undocumented intake contributed to missing meal data given that parents reported barriers to accessing the ASA24 website or forgetting to capture RFPM images.
In some previous validation studies, the ASA24 under-reported energy intake when compared against weighed food records or direct observation(Reference Foster and Bradley1,Reference Kirkpatrick, Subar and Douglass9,Reference Baxter, Hitchcock and Royer21,Reference Krehbiel, DuPaul and Hoffman55) . In contrast, other ASA24 validation studies demonstrated an overestimation of energy intake when parents were proxy reporters for their children(Reference Wallace, Kirkpatrick and Darlington56). Here, we found that reported energy intake with the ASA24 was 1675 kcal, which was significantly higher than the RFPM by 379 kcal. One possible explanation for higher reported energy intake in the ASA24 compared with the RFPM is parents’ overestimation of portions consumed by children during school lunches. Substantial food waste has been documented during lunch meals at school, but parents may be unaware that some lunch foods are left unconsumed(Reference Cohen, Richardson and Austin57,Reference Smith and Cunningham-Sabo58) . Thus, the higher estimated energy intake from the ASA24 may be due to parents’ overestimation of children’s intake, particularly if parents reported intake was based on the school cafeteria menu or they did not account for lunchbox food waste.
The RFPM has not yet been validated for assessing full-day dietary intake among school-age children under free-living conditions. The present study provides preliminary data on intake estimates for future RFPM validation studies. A sex-specific analysis showed that reported energy intake with the RFPM was lower than the EER among boys for all 3 EER calculations. This is consistent with a study among urban preschoolers from underrepresented racial/ethnic groups, in which the RFPM underestimated energy intake by 16 % under free-living conditions(Reference Nicklas, Saab and Islam24). The validity of the RFPM for estimating energy intake among preschoolers from underrepresented racial/ethnic groups was also tested against directly weighed food on a research unit(Reference Nicklas, Islam and Saab59). The RFPM overestimated energy intake by 7·5 %(Reference Nicklas, Islam and Saab59), suggesting that underestimation in the real world is likely due to missing photos, not error in the process of converting images to estimates of intake. Efforts to improve the accuracy of the RFPM should identify opportunities to ensure that each meal and snack is photographed. For adults, reliance on Ecological Momentary Assessment methods has been shown to address this problem very effectively, yielding accurate estimates of energy intake even in free-living conditions(Reference Martin, Correa and Han26).
Median satisfaction and ease of use scores were five on a scale of six for both tools. Acceptability was similarly high among school-age children and parents of preschoolers who used the ASA24 in Canada(Reference Kirkpatrick, Gilsing and Hobin11). For the RFPM, the only studies that examined parents’ experience with the method focused on the perceived burden of documenting a single type of meal across 7–8 d(Reference Rose, Streisand and Aronow60,Reference McCloskey, Johnson and Bekelman61) . One study among nine families demonstrated that parents found the app easy to use for capturing breakfast meals(Reference Rose, Streisand and Aronow60). Another study among twenty families found that many participants would be willing to use the RFPM again in a future study(Reference McCloskey, Johnson and Bekelman61). The data presented here build on these findings by showing that satisfaction with the RFPM remains high, even when parents are asked to participate for three full days.
When asked which of the two methods they would prefer to use in future studies, almost two-thirds of parents preferred the RFPM. This finding may be due to the lower perceived time commitment. Two meals were photographed by research staff in the school cafeteria, and this may have reduced parents’ overall time commitment and burden with the RFPM. Time commitment is an important dimension of participant burden in nutrition research(Reference Magarey, Watson and Golley62,Reference Naska, Lagiou and Lagiou63) . Objectively measured completion time for a single ASA24 in this study was 26 min on average, which closely matched the ASA24 completion times reported by others(64). Thus, the daily time commitment for the RFPM may be <26 min, if participant perceptions of the relative time commitment were accurate.
Both the ASA24 and RFPM are technology-based measures that are frequently updated in ways that may improve accuracy and reduce participant burden. For example, the ASA24-2020 was released in the short period since the present study was conducted. The ASA24-2020 has new features that may reduce misreporting and burden (e.g., enhanced capability to find misspelled foods in the database, new portion size food images and an updated food and nutrient database, HTML5 interface that facilitates the use of additional browsers). Similarly, at the time this study was conducted, the SmartIntake app was solely compatible with the iOS platform, which might limit who can use the RFPM without using a device provided by the research team. Yet, the SmartIntake app is expected to be compatible with Android devices in the near term.
This study contributes an innovative comparison of two dietary assessment tools and shows low participant burden when assessing full-day intake among school-age children with the ASA24 and RFPM under free-living conditions. The findings provide intake estimates by sex and race/ethnicity that can be used to design future studies to validate full-day intake with the RFPM and ASA24 against a gold standard for energy expenditure, such as doubly labelled water or accelerometry, among school-age children. The results raise questions about whether the accuracy of dietary assessments varies depending on the population characteristics, highlighting the importance of pilot testing assessment tools. In addition, this study highlighted the need to consider eating location and food source in future validation studies, given that where and what children eat may vary as a function of measurement type. Finally, this study was funded by the ECHO Program(Reference Gillman and Blaisdell28), which has as an explicit goal the development of new methods to improve the quality of observational data in children. Results from the present study have the potential to inform the selection of dietary assessments in the ECHO Program, and the broader child health community.
This study has several limitations. First, we may have under- or overestimated each child’s energy requirement because daily physical activity level and change in body weight during the dietary assessment period were not measured. However, EER were calculated based on other measured variables (sex, age, body weight); thus, error in the estimated EER would be similar across dietary assessment methods. Further, the EER calculated in the present study fall within the range of Estimated Calorie Needs reported in the 2015–2020 Dietary Guidelines for Americans for children aged 7–8 years, which supports the plausibility of our estimates(45). Second, our population was limited to parents reporting their child’s intake, so findings cannot be generalised to adults or children reporting their own intake. Another limitation is that all participants were drawn from urban areas, which means that findings may not be generalisable to rural populations where broadband Internet, which is needed for both the ASA24 and RFPM, may be less accessible. Finally, there are multiple considerations when selecting an assessment tool, and only two were considered in this study: accuracy (including missingness) and participant burden. Future studies should compare cost, child burden and researcher burden across methods, and how burden and accuracy vary by individual sociodemographic characteristics, such as sex or race/ethnicity. The present study was not powered to draw conclusions about any differences by sex or race/ethnicity but does provide preliminary estimates. Future studies should also compare potential sources of social desirability bias in the ASA24 and RFPM.
In conclusion, we provided novel data that can inform method selection and interpretation of findings in dietary assessment studies among school-age children. Continued effort to improve the accuracy of both the ASA24 and RFPM is justified given their high acceptability. Future efforts should focus on reducing under- and over-estimation of intake in the ASA24 and missing images in the RFPM.
Acknowledgements
The authors wish to thank our ECHO colleagues, the medical, nursing and programme staff, as well as the children and families participating in the ECHO cohorts. We also acknowledge the contribution of the following ECHO programme collaborators: ECHO Components – Coordinating Center: Duke Clinical Research Institute, Durham, North Carolina: Smith PB, Newby KL, Benjamin DK; Data Analysis Center: Johns Hopkins University Bloomberg School of Public Health, Baltimore, Maryland: Jacobson LP; Research Triangle Institute, Durham, North Carolina: Parker CB.
Research reported in this publication was supported by the Environmental influences on Child Health Outcomes (ECHO) programme, Office of The Director, National Institutes of Health, under Award Numbers U2COD023375 (Coordinating Center), U24OD023382 (Data Analysis Center), U24OD023319 (PRO Core), UH3OD023248 (University of Colorado Anschutz Medical Campus) and 5U2COD023375 (ECHO Opportunities and Infrastructure Fund). This work was partially supported by NORC Center grant P30 DK072476 entitled ‘Nutrition and Metabolic Health Through the Lifespan’ sponsored by NIDDK and grant U54 GM104940 from the National Institute of General Medical Sciences, which funds the Louisiana Clinical and Translational Science Center. Dr. Glueck was supported by R01GM121081. Daniel Hsia was supported in part by 2UG1OD024959, which funds the Louisiana site of the ECHO IDeA States Pediatric Clinical Trials Network.
T. A. B., C. K. M., S. L. J., D. H. G., K. A. S., D. S. H. and D. D. conceptualised the project; T. A. B., C. K. M. and R. A. S. carried out the study; T. A. B., C. K. M., K. K. H. and D. H. G. analysed the data; T. A. B. wrote the paper and had primary responsibility for the final content. All authors read and approved the final manuscript.
Pennington Biomedical Research Center/Louisiana State University has interest in the intellectual property surrounding the Remote Food Photography Method© and SmartIntake® app, and author C. Martin is an inventor of the technology. T. Bekelman, S. Johnson, D. Glueck, K. Sauder, K. Harrall, R. Steinberg, D. Hsia and D. Dabelea have no conflicts of interest to declare.
The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.
Supplementary material
For supplementary material referred to in this article, please visit https://doi.org/10.1017/S0007114521001951