Hostname: page-component-586b7cd67f-g8jcs Total loading time: 0 Render date: 2024-11-27T12:10:41.714Z Has data issue: false hasContentIssue false

Accuracy of anthropometric measurements and weight status perceptions reported by parents of 4-year-old children

Published online by Cambridge University Press:  05 November 2019

María D Esteban-Vasallo*
Affiliation:
Servicio de Informes de Salud y Estudios, Dirección General de Salud Pública, Consejería de Sanidad, San Martín de Porres 6, Madrid 28035, Spain
Ignacio Galán
Affiliation:
Centro Nacional de Epidemiología, Instituto de Salud Carlos III, Madrid, Spain Departamento de Medicina Preventiva y Salud Pública, Universidad Autónoma de Madrid/IdiPAZ, Madrid, Spain
Maira A Ortiz-Pinto
Affiliation:
Departamento de Medicina Preventiva y Salud Pública, Universidad Autónoma de Madrid/IdiPAZ, Madrid, Spain Departamento de Salud Pública, Universidad Del Norte, Barranquilla, Colombia
Amelia Astray San Martín
Affiliation:
Centro de Salud Soto del Real, Consejería de Sanidad, Madrid, Spain
Eva M Cabrero López
Affiliation:
Centro de Salud Adelfas, Consejería de Sanidad, Madrid, Spain
María Teresa Morales San José
Affiliation:
Centro de Salud La Paz, Consejería de Sanidad, Madrid, Spain
Honorato Ortiz-Marrón
Affiliation:
Servicio de Epidemiología, Dirección General de Salud Pública, Consejería de Sanidad, Madrid, Spain
*
*Corresponding author: Email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Objective:

To assess the validity of self-reported height and weight by parents of 4-year-old children and subjective weight perception.

Design:

Descriptive cross-sectional study.

Setting:

Paediatric population living in the Autonomous Community of Madrid.

Participants:

Children born in 2008–2009 examined at 47–59 months of age. Data were collected by paediatricians of the Madrid Primary Care Physicians Sentinel Network. Parents reported weight and height data. Prevalence of weight status categories was calculated using WHO and International Obesity Task Force (IOTF) reference criteria. Sensitivity, specificity and positive predictive value (PPV) were estimated. The appraisal of their child’s weight perception and parental misperception were assessed.

Results:

For 2914 children, reported height was underestimated by −1·38 cm, weight by −0·25 kg and BMI was overestimated by +0·41 kg/m2 on average. The prevalence of obesity estimated with reported data was 2·7 times higher than that calculated with measured data (16·2 v. 6·0 %) according to WHO classification, and 3·6 times higher with IOTF classification. Sensitivity to identify obesity was 70·5 %, specificity was 87·3 % and PPV was 26·2 % (WHO classification). Half of the parents of pre-schoolers with obesity failed to identify their child’s weight status. Parental misperception among children classified as having overweight or obesity reached 93·0 and 58·8 %, respectively.

Conclusions:

Parents underestimated children’s height and weight, leading to an overestimation of the prevalence of obesity. Small inaccuracies in reported measures have an important effect for the estimation of population prevalences. Parents’ report of child weight status is unreliable. Parental awareness and acknowledgement of child weight status should be improved.

Type
Research paper
Copyright
© The Authors 2019

Excess of weight at a young age is an important risk factor for overweight/obesity in adolescence and adult age(Reference Dietz1,Reference Freedman, Dietz and Srinivasan2) and increases the likelihood of early morbidity and mortality(Reference Kelsey, Zaepfel and Bjornstad3,Reference Must and Strauss4) . The prevalence of overweight and obesity in children and adolescents has become a public health problem in developed countries. Their estimated prevalence is about 20 % in the WHO European Region(Reference Branca, Nikogosian and Lobstein5).

Routine surveillance of overweight and obesity is essential to assess population changes and trends, and to evaluate the success of policies aimed to reduce the excess of weight in childhood and eventually bring to a halt to the ongoing obesity epidemic. Reliable data are crucial to estimate accurate prevalences of overweight and obesity and to allow comparisons. Measured weight and height would be the gold standard for surveillance, as for example in the Childhood Obesity Surveillance Initiative (COSI) established in 2006 by the WHO Regional Office for Europe to monitor changes in overweight in children between 6 and 9 years of age(Reference Wijnhoven, Van Raaij and Spinelli6). However, a recent review of studies reporting on overweight and obesity prevalence in children aged 0–5 years in the WHO European Region member states showed the need for an increased range of coverage and quality of data in surveillance on overweight and obesity in this age group(Reference Jones, Jewell and Saksena7).

However, measurements are expensive and they do not always have the desired availability or frequency. Parent-reported data can be an affordable alternative, and they are commonly used in population surveys, but published studies have shown poor accuracy of these measures. This effect seems to be even greater among the youngest. The obesity prevalence based on the parental-reported weight and height obtained by two national health surveys in the USA in the last decade was overestimated by a factor of 5 for children aged 2–3 years and by a factor of 3 for children aged 3–7 years(Reference Akinbami and Ogden8). Accordingly, the use of parental-reported height and weight and calculated BMI was discarded for children younger than 10 years(Reference Blumberg, Foster and Frasier9). Nevertheless, the Spanish National Health Survey (SNHS) keeps using reported measures and recently published the 2017 results, with an estimated prevalence of 12·0 % for overweight and 19·9 % for obesity in children 2–4 years of age(10).

Parents’ ability to identify their child’s overweight status has been also questioned in different studies. Pooled results from a systematic review found that 62·4 % of children with overweight were incorrectly perceived as having normal weight by their parents, with a higher misperception among parents with children aged 2–6 years(Reference Rietmeijer-Mentink, Paulis and Van Middelkoop11). Potential for success in overweight and obesity prevention may lie with family-based interventions. Parental misperceptions of overweight and associated health risks constitute unfavourable conditions for preventive actions(Reference Warschburger and Kroller12).

There is little evidence about the potential deviation of anthropometric data provided by parents of pre-schoolers in Spain and the bias that could produce in the prevalence of overweight and obesity estimated with them. These population prevalences are usually calculated with reported measures collected by surveys, and without objective measures to compare or any validation. Their inaccuracy could lead to biased results that even could affect some weight status categories more than others. In regard to parents’ weight perception, up to 60·8 % failed to recognize excess weight in their children according to the 2006–2007 SNHS (using reported measures as reference, since objective height and weight are not collected in this survey), rising to 71·4 % in the 2011–2012 SNHS(Reference Ramiro-González, Sanz-Barbero and Royo-Bordonada13). It would be necessary to compare parents’ weight perception with the objective measures of the children to assess the accuracy of that appraisal and the extent of weight status misperception.

The objective of the present study was to assess the validity of height, weight and subjective weight perception reported by parents of 4-year-old children and the accuracy of overweight/obesity classification based on that information.

Methods

Design and study population

This is a descriptive cross-sectional study. The data were drawn from the Longitudinal Childhood Obesity Study (ELOIN), a population-based children’s cohort in the Autonomous Community of Madrid, Spain. That study started in 2012 and aims to describe the prevalence and variations in childhood overweight and obesity, ascertaining their association with sociodemographic and lifestyle factors, as well as their impact on health. The design and characteristics of ELOIN have already been described elsewhere(Reference Ortíz-Marrón, Cuadrado-Gamarra and Esteban-Vasallo14). Inclusion criteria were being born between January 2008 and November 2009 and being registered in the health-care database with one of the thirty-one paediatricians who were part of the Madrid Primary Care Physicians Sentinel Surveillance Network(Reference Pérez-Farinos, Galán and Ordobás15). To ensure proportional distribution by socio-economic level of the assisted population, fourteen strata are defined according to sociodemographic variables that characterize the health areas (first-stage units). This guarantees the representativeness at regional level of the population assisted by the network. Participation in the study was offered via letter to parents of children who reached the age of 4 years between 2012 and 2013. Data of children examined at 47–59 months of age were included in the analysis.

Measures

Height and weight reported by parents

Parents of children who attended the paediatric revision consultation scheduled for the age of 4 years in the primary-care health centre were asked to report the current height and weight of their child (see online supplementary material, Supplemental Table S1).

Height and weight measured by professionals

A physical examination was performed on the children. Paediatricians were previously trained to obtain standardized measurements of weight and height. Weight was measured using a digital scale and height was measured using a telescopic stadiometer (SECA model 220, precision 0·1 kg and 1 mm, respectively). Two measurements of height (without shoes) and two of weight (in underwear) were obtained and registered in the electronic clinical record (recorded in centimetres and in kilograms with one decimal, respectively). The mean of the two measurements was used for the analyses. BMI, both for reported and for objective measures, was calculated with the formula: kg/m2.

Parents’ perception of child’s weight status obtained by telephonic survey

In the following weeks, a telephonic questionnaire was applied to those parents who agreed to participate in the ELOIN cohort, gathering information on sociodemographic characteristics, dietary patterns and lifestyles. Parents’ visual perception of the child’s weight status was assessed with the question ‘Compared to children of the same age, how do you think is your child?’, with a five-option answer: ‘I think he/she is fat’, ‘I think he/she has excessive weight’, ‘I think he/she has a normal weight’, ‘I think he/she is a little thin’ and ‘I think he/she is thin’.

Data analyses

Cleaning of reported data

Records with biologically implausible values for reported height and weight and calculated BMI were excluded, according to the WHO exclusion criteria (Z-score for gender-specific weight-for-height <−4·0 or >+5·0, height-for-age <−5·0 and >+3·0, and weight-for-age <−5·0 and >+5·0). A total of four weights and thirty-one heights were discarded as biologically implausible values (0·1 and 1·0 %, respectively). Of the 2931 BMI calculated with the remaining reported measures, seventeen were also discarded as biologically implausible values (0·6 %).

Comparisons between reported and measured data

The mean absolute and relative differences between reported and measured height, weight and BMI were calculated. To assess agreement between reported and measured height, weight and BMI, intraclass correlation coefficients were estimated.

Categorization of weight status based on reported and measured data

The WHO growth charts for 2006 and the cut-off points of the International Obesity Task Force (IOTF) for 2000 were used to assign BMI categories. Based on the reported and measured children’s weight and height, the weight categories were calculated by sex. Using the WHO criteria(16), BMI Z-scores were calculated according to child growth standards for those aged 60 months or younger. Thereby, participants were classified into four categories by BMI Z-score: obesity (>+2); overweight (>+1 and ≤+2); normal weight (≥−2 and ≤+1); and low weight (<−2). The extended IOTF BMI cut-offs proposed by Cole et al.(Reference Cole, Bellizzi and Flegal17,Reference Cole and Lobstein18) to classify children aged from 2 to 18 years were used, with the interpolated biannual values.

Comparisons of weight status categories based on reported and measured data

We compared prevalence of weight status (obesity/overweight/normal weight/low weight) based on measured and reported data. The kappa test with quadratic weighting was used to determine the agreement between the weight status assigned through reported v. measured anthropometric data. The degree of misclassification that resulted from using reported measures was assessed. Sensitivity (children with overweight or obesity according to reported and measured data/children with overweight or obesity according to measured data), specificity (children without overweight or obesity according to reported and measured data/children without overweight or obesity according to measured data) and positive predictive value (PPV; children with overweight or obesity according to reported and measured data/children with overweight or obesity according to reported data) were calculated.

Parental misperception

For the assessment of parents’ visual perception of their child’s weight status, the parental misperception was defined as follows: children with overweight or obesity according to their measured height and weight but described by their parents as ‘normal weight’, ‘a little thin’ or ‘thin’. Children described as ‘fat’ or ‘having excessive weight’ were excluded from the definition of parental misperception.

The data were analysed using the statistical software package IBM SPSS Statistics version 22.

Results

In total, 2914 of the 4571 children screened at age 4 years had valid height and weight both reported and measured, representing a response rate of 63·7 %.

Comparisons between reported and measured data

On average, child height was underestimated by 1·38 cm and weight by 0·25 kg (Table 1). Overall, BMI was 0·41 kg/m2 higher when based on reported v. measured height and weight. The bias in BMI was larger for boys, due to a greater deviation of the reported height: the mean absolute differences between reported and measured height were −1·56 cm for boys v. −1·19 cm for girls, and the mean relative differences were −1·50 and −1·16 %, respectively. For weight the absolute differences were −0·23 kg for boys and −0·27 kg for girls (relative differences of −1·34 and −1·58 %, respectively), and for BMI the absolute differences were +0·46 kg/m2 for boys and +0·34 kg/m2 for girls (relative differences of +2·92 and +2·18 %, respectively). Nevertheless, these differences by sex were not statistically significant. There was no difference between BMI Z-scores estimated with reported and measured data for girls, meanwhile for boys the BMI Z-score estimated with reported data was significantly higher.

Table 1 Mean parent-reported and measured anthropometric data in 4-year-old children, by sex. Autonomous Community of Madrid, Spain, 2012 (n 2914)

Statistically significant differences are indicated in bold.

* No relative differences could be calculated due to measured BMI Z-score values equal to zero.

When children’s weight status was categorized according to the WHO or IOTF classification, a significant underrating of height was detected in all groups except those with low weight according to the WHO classification (see online supplementary material, Supplemental Table S2). This deviation was proportionately greater among children with obesity. Weight was significantly underestimated in children with overweight and normal weight, and among girls with obesity, according to the IOTF classification. A significant overestimation of BMI was appreciated in all categories except for low weight when the WHO classification was used, and in children with normal weight when the IOTF classification was used. By weight category, there were no statistically significant differences in the inaccuracy of height, weight or BMI, except in the height of girls classified as ‘low weight’ according to the IOTF classification, when compared with girls classified as ‘normal weight’.

Findings from intraclass correlation coefficients showed moderate correlation between reported and measured height: 0·543 (P < 0·01), 0·538 for boys (P < 0·01) and 0·542 for girls (P < 0·01). The correlation between reported and measured weight was the highest, 0·865 (P < 0·01), with good correlation both for boys and girls (0·860 and 0·868, respectively). The intraclass correlation coefficient between BMI calculated with reported and objective measures was 0·512 (P < 0·01; 0·514 for boys and 0·509 for girls).

Comparisons of weight status categories based on reported and measured data

The prevalence of obesity estimated with reported height and weight was 2·7 times higher than that calculated with measured height and weight (16·2 (95 % CI 14·9, 17·6) % v. 6·0 (95 % CI 5·2, 6·9) %) according to the WHO classification, and 3·6 times higher (12·1 (95 % CI 11·0, 13·4) % v. 3·3 (95 % CI 2·7, 4·0) %) when using the IOTF classification (Table 2). The overestimation of the prevalence in the extreme categories (obesity and low weight) was slightly higher among boys. The agreement between the assigned weight status through reported v. measured anthropometric data was moderate–low, with a weighted κ coefficient of 0·405 (95 % CI 0·371, 0·439) when using the WHO classification and 0·350 (95 % CI 0·313, 0·387) with the IOTF classification.

Table 2 Prevalence of weight status estimated using parent-reported or measured height and weight, and prevalence ratio (PR), in 4-year-old children, by sex and weight status classification. Autonomous Community of Madrid, Spain, 2012 (n 2914)

IOTF, International Obesity Task Force.

The sensitivity of using reported height and weight to identify obesity according to the WHO classification was 70·5 (95 % CI 63·1, 77·1) %, specificity was 87·3 (95 % CI 85·9, 88·5) % and PPV was 26·2 (95 % CI 22·3, 30·4) % (Table 3). Thus, reported measures misclassified 29·5 % of children with obesity (32·3 % in boys and 26·5 % in girls). When using the IOTF classification, the effect of misclassification with reported measures was similar. By sex, the only statistically significant difference was detected for PPV (39·3 % in girls v. 28·3 % in boys) with the IOTF classification and grouping overweight and obesity. The weight category assigned using reported or objective measures was the same for 60·0 % of the children when the WHO classification was used and 62·9 % with the IOTF classification (Fig. 1). Using reported measures 27·5 % of children with overweight were classified as with obesity (30·1 % with the IOTF classification), while in 39·6 % (40·8 % with the IOTF classification) the category was underestimated. Among those children with normal weight, 22·8 % were erroneously assigned to excess weight (19·4 % with the IOTF classification). Of underweight children, 55·6 % were correctly classified using the reported measures (53·1 % with the IOTF classification). Findings from the weighted κ test showed moderate agreement between the weight status category assigned with reported v. measured data (0·4048 (95 % CI 0·3708, 0·4387), P < 0·01 using the WHO classification; 0·3498 (95 % CI 0·3129, 0·3867), P < 0·01 using the IOTF classification).

Table 3 Sensitivity, specificity and positive predictive value (PPV) of obesity and overweight using parent-reported measures in 4-year-old children, by sex and weight status classification. Autonomous Community of Madrid, Spain, 2012 (n 2914)

IOTF, International Obesity Task Force.

Fig. 1 Proportion of weight status misclassification (, same weight status category; , higher weight status category; , lower weight status category) with parent-reported data in children aged 4 years when compared with weight status calculated using measured data (WHO and International Obesity Task Force (IOTF) classifications). Autonomous Community of Madrid, Spain, 2012 (n 2529)

Parental misperception

The parental misperception among children classified as being with overweight or obesity according to the WHO classification reached 93·0 and 58·8 %, respectively (Fig. 2). When the IOTF classification was used, parental misperception was lower, affecting 82·9 % of parents of children with overweight and 48·0 % of parents of children with obesity. The parental misperception for boys with obesity was higher than for girls.

Fig. 2 Prevalence of overweight and obesity calculated with measured data in children aged 4 years (WHO and International Obesity Task Force (IOTF) classifications; values above bars), and proportion of parental misperception* (; values within bars), in total and by sex. Autonomous Community of Madrid, Spain, 2012 (n 2529). *Parental misperception: child described by parents as having ‘normal weight’, ‘a little thin’ or ‘thin’ and classified in the category ‘overweight’ or ‘obesity’ according to measured data

Discussion

The present study provides a global perspective on information sources of the weight status of pre-schoolers, by analysing data from objective measures, parent-reported measures and also parents’ subjective appraisal of their child’s weight status. The availability of standardized measures obtained by trained professionals provides a gold standard to evaluate the internal validity of parent-reported data and to assess the bias these data could generate. Parent-reported height and weight were found to be subject to errors that affect the ability to classify the weight status into the correct category and to identify overweight and obesity accurately among children 4 years of age. Inaccuracies apparently small in the reported measures of height and weight have an important effect for the estimation of population prevalences. Only 70 % of children with obesity were correctly classified using parent-reported data, meanwhile over 20 % of children with normal weight were erroneously assigned to excess weight. Therefore, the use of parent-reported measures could overestimate the real prevalence of obesity at this age by up to 2·7 times when using the WHO classification (3·6 times with the IOTF classification). The subjective perception about the child’s overweight and obesity was inadequate in a high proportion of parents.

Reported height and weight

Although in the published literature the deviation of the reported height and weight of pre-schoolers varies widely, previous studies in our country found, similarly to our data, an underestimation of both reported measures (up to 10 % in the case of weight) in children under 14 years of age(Reference Patiño-Villena, Chirlaque and Salmerón19,Reference Rajmil, López-Aguila and Mompart-Penina20) . This underestimation seemed to be even more marked in children under 4 years of age(Reference Patiño-Villena, Chirlaque and Salmerón19). The deviation of both reported height and weight observed in our sample was also found in international studies(Reference Gordon and Mellor21Reference Weden, Brownell and Rendall23). Apparently, parents are more likely to underestimate height than weight, as described among parents of children aged 2–8 years in the analysis of a sub-sample of the 2006 and 2008 waves of the National Longitudinal Survey of Youth 1979 Cohort (NLSY79-Child) in the USA(Reference Weden, Brownell and Rendall23). This could be because parents would be more likely to track children’s weight than height, at these ages. The fact that in children most drugs are dosed according to body weight could at least partially justify a better retention and/or update of this measure.

As in other studies, no significant differences by sex in height or weight misreporting were found for young children(Reference Weden, Brownell and Rendall23), despite a larger mean height error was found in boys. This effect has been described previously in boys between 2 and 17 years of age(Reference O’Connor and Gugenheim24), and also a Canadian study found that height errors varied by the child’s sex, with slight overestimation in boys and underestimation in girls(Reference Dubois and Girad25). However, when measures reported for children aged 6–11 years were analysed, the bias found in height did not differ significantly by the child’s sex or age group, but the bias in weight was significantly higher for girls than boys(Reference Shields, Connor and Janssen22).

Prevalences

Prevalence of overweight/obesity among pre-school children based on parent-reported data of height and weight was significantly higher than prevalence based on direct measurements, as other studies have found(Reference Akinbami and Ogden8,Reference Shields, Connor and Janssen22,Reference O’Connor and Gugenheim24Reference Huybrechts, De Bacquer and Van Trimpont29) . The bias in height was not offset by the bias in weight, and as a result BMI values based on reported measures were overestimated, as in other studies(Reference Patiño-Villena, Chirlaque and Salmerón19Reference Gordon and Mellor21,Reference Weden, Brownell and Rendall23,Reference O’Connor and Gugenheim24) . A simulation method developed to assess bias from using parent-reported data on heights and weights in two nationally representative US surveys estimated that the source of one-half to two-thirds of the overestimation in obesity prevalence in children aged 2–5 years was due to height reporting error manifest in the first height percentile(Reference Rendall, Weden and Lau30). The sensitivity and specificity of using reported height and weight to identify obesity status were slightly higher than the 55 and 79 %, respectively, described by O’Connor and Gugenheim among children between 2 and 5 years of age(Reference O’Connor and Gugenheim24), but lower than the 84·4 and 79·3 % described by Gordon and Mellor for the obesity classification (BMI-for-age percentile ≥95th) in children 3–5 years old(Reference Gordon and Mellor21). Therefore, the use of parent-reported height and weight does not guarantee the correct weight status classification for 4-year-old children and, at population level, leads to the overestimation of obesity and overweight prevalences, as a recent meta-analyses of similar studies showed(Reference He and Fan31). These circumstances discourage the use of reported measures for the surveillance and monitoring of pre-schoolers’ nutritional status, and highlight the need for objective measures, especially in this less studied age group, to have accurate data at either individual level or population level, and to facilitate comparisons with other populations(Reference Cattaneo, Monasta and Stamatakis32).

Parental misperception

In regard to parental misperception of the children’s weight status, the proportion of parents of children with overweight or obesity who perceived them as having a normal or low weight was high, similarly to other studies(Reference Rietmeijer-Mentink, Paulis and Van Middelkoop11,Reference Ramiro-González, Sanz-Barbero and Royo-Bordonada13,Reference Gordon and Mellor21,Reference Carnell, Edwards and Croker33Reference Manios, Moschonis and Karatzi38) . In Spain, a study assessing the wrong perception of excess weight among parents of children between 5 and 9 years old using data from the 2011–2012 SNHS found that 79·7 % of parents of children with overweight and 70·3 % of parents of children with obesity (according to the IOTF classification) considered their children’s weight as normal or lower than normal(Reference Ramiro-González, Sanz-Barbero and Royo-Bordonada13). The use in the present study of reported measures to estimate the child’s weight status could explain the higher misperception found among parents of children with obesity. When measured height and weight were used to assign a weight status (according to the WHO classification) in a sample of children aged 3–45 months, 70 % of parents of children with obesity failed to recognize the excess weight situation(Reference Patiño-Villena, Chirlaque and Salmerón19). Globally, a recent review estimated that the overall rate of parental underestimation of overweight/obesity was 67·5 (95 % CI 62·9, 71·7) %(Reference Lundahl, Kidwell and Nelson37). Parental misperception of child’s weight status seems to be more likely among younger children, especially under 6 years of age(Reference Ramiro-González, Sanz-Barbero and Royo-Bordonada13,Reference He and Fan31,Reference De Ruiter, Olmedo-Requena and Jiménez-Moleón34,Reference Lundahl, Kidwell and Nelson37) . Carnell et al. described that only 1·9 % of parents of children with overweight and 17·1 % of parents of children with obesity described their child as overweight, suggesting that parents of 3–5-year-old children show poor awareness of their child’s current weight status(Reference Carnell, Edwards and Croker33). At theses ages, excess weight could be more accepted because it is believed to be a transitory characteristic that will disappear with growth. Moreover, the prevailing health message to parents of young children is to encourage growth, and heaviness may even be viewed as an indicator of good health. Scepticism towards the identification of a child as being overweight has been justified in qualitative studies with parents because of the natural variety of body shape among children and the continuous changes that take place in growth and development during the maturation process(Reference Doolen, Alpert and Miller35). Parents failed to categorize their children’s weight according to medically defined definitions of overweight, they seemed to not understand, use or trust clinical measures, and used alternative approaches primarily reliant on extreme cases(Reference Carnell, Edwards and Croker33,Reference Jones, Parkinson and Drewett36) . Parental misperception about child weight status is relevant, since there is evidence that parents who perceive their child as overweight are more likely to view their child’s diet, physical activity patterns and risk of obesity as a health threat and childhood obesity as a serious problem(Reference Sylvetsky-Meni, Gillepsie and Hardy39), and parental concern about child weight is associated with specific actions to improve diet and increase physical activity(Reference Moore, Harris and Bradlyn40).

Study strengths and limitations

Among the strengths of the present study, the large size of the sample, the high participation rate and its representativeness at population level should be mentioned. It focuses on a paediatric age group that is not well studied and with specific characteristics which recommend their study separately from other ages. It also gathers information from children’s caregivers other than the parents (grandparents, etc.), so data obtained are more assimilated to the real situation of data collected in paediatric revision visits. The use of both the WHO and the IOTF classifications to categorize the weight status of children facilitates comparisons with other studies. The analysis of data of children belonging to a cohort, with their correspondent follow-ups, will allow to assess changes in the same individuals and to identify related factors.

Some limitations of the study should be addressed. BMI, which was used to classify weight categories, can erroneously classify some children, especially those situated at the low ‘without excess weight’ level or those with BMI values close to the cut-off values of the weight categories. The analysis of reported and measured data covered all children assisted in the paediatric revision visit, regardless of their participation in the ELOIN cohort, but the parental misperception was estimated from data gathered in the questionnaires answered by parents who agreed to participate in the cohort, so it could be affected by a lower representativeness of children from families with a low educational attainment and those from families with foreign parents with language difficulties. The parental subjective perception of the child’s weight was provided after the paediatric revision visit in which anthropometric measures were collected, so it could be affected by the subsequent commentaries and recommendations from the health professional. Also, the stigma linked to the word ‘fat’ could have conditioned the response for some parents. The cultural factors that presumably condition subjective weight appraisal may also limit the data extrapolation to other populations.

Conclusions

Parent-reported measures underestimated children’s height and weight, leading to an overestimation of the BMI and of the attributed weight status. Both the individual classification of the weight status of pre-schoolers and the population estimation of overweight and obesity should be based on objective measures of weight and height. The sensitivity for identifying children with obesity using reported data was low, raising doubts regarding the accuracy of using these data for surveillance and investigation in childhood obesity. Studies with those objectives, including health surveys, should systematically incorporate the standardized collection of these measurements and stop using reported data. Parents’ report of child weight status is unreliable, half of the parents of pre-schoolers with obesity failed to identify their weight status. The collection of information on this issue should avoid the use of stigmatizing language. Parental misperception of child weight status is relevant and health professionals should be aware of it. Parental awareness and acknowledgement of child weight status should be improved. Health professionals have the responsibility to adequately inform parents about the weight status of their children and about the impact of excess weight on health from an early age. Factors related with misperception and strategies of intervention should be more deeply studied, as well as its implications for weight concern and its potential effects on the later evolution of a child’s weight status.

Acknowledgements

Acknowledgements: Thanks are due to the families, children and health staff of the Madrid Primary Care Physicians Sentinel Network for their participation. Financial support: This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Conflict of interest: The authors have no conflicts of interest to disclose. Authorship: M.D.E.-V., I.G. and H.O.-M. designed the study. A.A.S.M., E.M.C.L. and M.T.M.S.J. participated in data collection. I.G., H.O.-M. and M.A.O.-P. supervised the analysis. M.D.E.-V. undertook the initial analysis and prepared the first draft of the manuscript. All the authors contributed to the data interpretation, the drafting process and have approved the final manuscript. Ethics of human subject participation: This study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the ethics committee of the Hospital Ramón y Cajal de Madrid. Written informed consent was obtained from all subjects’ parents.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S1368980019003008

References

Dietz, WH (1998) Health consequences of obesity in youth: childhood predictors of adult disease. Pediatrics 101, 518525.Google ScholarPubMed
Freedman, DS, Dietz, WH, Srinivasan, SRet al. (1999) The relation of overweight to cardiovascular risk factors among children and adolescents: the Bogalusa Heart Study. Pediatrics 103, 11751182.CrossRefGoogle ScholarPubMed
Kelsey, MM, Zaepfel, A, Bjornstad, Pet al. (2014) Age-related consequences of childhood obesity. Gerontology 60, 222228.CrossRefGoogle ScholarPubMed
Must, A & Strauss, RS (1999) Risks and consequences of childhood and adolescent obesity. Int J Obes Relat Metab Disord 23, Suppl. 2, S2S11.CrossRefGoogle ScholarPubMed
Branca, F, Nikogosian, H & Lobstein, T (editors) (2007) The Challenge of Obesity in the WHO European Region and Strategies for Response. Copenhagen: Who Regional Office for Europe.Google Scholar
Wijnhoven, TM, Van Raaij, JM, Spinelli, Aet al. (2014) WHO European childhood obesity surveillance initiative: body mass index and level of overweight among 6–9-year-old children from school year 2007/2008 to school year 2009/2010. BMC Public Health 14, 806.CrossRefGoogle ScholarPubMed
Jones, RE, Jewell, J, Saksena, Ret al. (2017) Overweight and obesity in children under 5 years: surveillance opportunities and challenges for the WHO European Region. Front Public Health 5, 58.CrossRefGoogle ScholarPubMed
Akinbami, LJ & Ogden, CL (2009) Childhood overweight prevalence in the United States: the impact of parent-reported height and weight. Obesity (Silver Spring) 17, 15741580.CrossRefGoogle ScholarPubMed
Blumberg, SJ, Foster, EB, Frasier, AMet al. (2012) Design and operation of the National Survey of Children’s Health, 2007. Vital Health Stat 1 issue 55, 1149.Google Scholar
Ministry of Health, Consumer Affairs and Social Welfare (2018) National health survey 2017. https://www.mscbs.gob.es/estadEstudios/estadisticas/encuestaNacional/encuesta2017.htm (accessed June 2018).Google Scholar
Rietmeijer-Mentink, M, Paulis, WD, Van Middelkoop, Met al. (2013) Difference between parental perception and actual weight status of children: a systematic review. Matern Child Nutr 9, 322.CrossRefGoogle Scholar
Warschburger, P & Kroller, K (2012) Childhood overweight and obesity: maternal perceptions of the time for engaging in child weight management. BMC Public Health 12, 295.CrossRefGoogle ScholarPubMed
Ramiro-González, MD, Sanz-Barbero, B & Royo-Bordonada, MA (2017) Childhood excess weight in Spain from 2006 to 2012. Determinants and parental misperception. Rev Esp Cardiol (Engl Ed) 70, 656663.CrossRefGoogle ScholarPubMed
Ortíz-Marrón, H, Cuadrado-Gamarra, JI, Esteban-Vasallo, Met al. (2016) The Longitudinal Childhood Obesity Study (ELOIN): design, participation and characteristics of the baseline sample. Rev Esp Cardiol (Engl Ed) 69, 521523.Google ScholarPubMed
Pérez-Farinos, N, Galán, I, Ordobás, Met al. (2009) A sampling design for a sentinel general practitioner network. Gac Sanit 23, 186191.CrossRefGoogle ScholarPubMed
World Health Organization (2006) WHO Child Growth Standards: Length/Height-for-Age, Weight-for-Age, Weight-for-Length, Weight-for-Height and Body Mass Index-for-Age: Methods and Development. Geneva: WHO.Google Scholar
Cole, TJ, Bellizzi, MC, Flegal, KMet al. (2000) Establishing a standard definition for child overweight and obesity worldwide: international survey. BMJ 320, 12401243.CrossRefGoogle ScholarPubMed
Cole, TJ & Lobstein, T (2012) Extended international (IOTF) body mass index cut-offs for thinness, overweight and obesity. Pediatr Obes 7, 284294.CrossRefGoogle ScholarPubMed
Patiño-Villena, B, Chirlaque, MD, Salmerón, Det al. (2016) Validity of anthropometric measurements and weight perceptions reported by relatives of children under 4 years old. Gac Sanit 30, 300303.CrossRefGoogle ScholarPubMed
Rajmil, L, López-Aguila, S & Mompart-Penina, A (2011) Health-related quality of life and factors associated with overweight and obesity in the pediatric population of Catalonia, Spain. Med Clin (Barc) 137, Suppl. 2, 3741.CrossRefGoogle ScholarPubMed
Gordon, NP & Mellor, RG (2015) Accuracy of parent-reported information for estimating prevalence of overweight and obesity in a race-ethnically diverse pediatric clinic population aged 3 to 12. BMC Pediatr 15, 5.CrossRefGoogle Scholar
Shields, M, Connor, GS, Janssen, Iet al. (2011) Obesity estimates for children based on parent-reported versus direct measures. Health Rep 22, 4758.Google ScholarPubMed
Weden, MM, Brownell, PB, Rendall, MSet al. (2013) Parent-reported height and weight as sources of bias in survey estimates of childhood obesity. Am J Epidemiol 178, 461473.CrossRefGoogle ScholarPubMed
O’Connor, DP & Gugenheim, JJ (2011) Comparison of measured and parents’ reported height and weight in children and adolescents. Obesity (Silver Spring) 19, 10401046.CrossRefGoogle ScholarPubMed
Dubois, L & Girad, M (2007) Accuracy of maternal reports of pre-schoolers’ weights and heights as estimates of BMI values. Int J Epidemiol 36, 132138.CrossRefGoogle ScholarPubMed
Banach, A, Wade, TJ, Cairney, Jet al. (2007) Comparison of anthropometry and parent-reported height and weight among nine year olds. Can J Public Health 98, 251253.CrossRefGoogle ScholarPubMed
Brettschneider, AK, Rosario, AS & Ellert, U (2011) Validity and predictors of BMI derived from self-reported height and weight among 11- to 17-year-old German adolescents from the KiGGS study. BMC Res Notes 4, 414.CrossRefGoogle ScholarPubMed
Garcia-Marcos, L, Valverde-Molina, J, Sanchez-Solis, Met al. (2006) Validity of parent-reported height and weight for defining obesity among asthmatic and nonasthmatic school children. Int Arch Allergy Immunol 139, 139145.CrossRefGoogle Scholar
Huybrechts, I, De Bacquer, D, Van Trimpont, Iet al. (2006) Validity of parentally reported weight and height for preschool-aged children in Belgium and its impact on classification into body mass index categories. Pediatrics 118, 21092118.CrossRefGoogle ScholarPubMed
Rendall, MS, Weden, MM, Lau, Cet al. (2014) Evaluation of bias in estimates of early childhood obesity from parent-reported heights and weights. Am J Public Health 104, 12551262.CrossRefGoogle ScholarPubMed
He, J & Fan, X (2018) How accurate is using parent-reported height and weight for screening children and adolescents for overweight and obesity? Meta-analyses at both population and individual levels. Child Obes 14, 302315.CrossRefGoogle ScholarPubMed
Cattaneo, A, Monasta, L, Stamatakis, Eet al. (2010) Overweight and obesity in infants and pre-school children in the European Union: a review of existing data. Obes Rev 11, 389398.CrossRefGoogle ScholarPubMed
Carnell, S, Edwards, C, Croker, Het al. (2005) Parental perceptions of overweight in 3–5 y olds. Int J Obes (Lond) 29, 353355.CrossRefGoogle ScholarPubMed
De Ruiter, I, Olmedo-Requena, R & Jiménez-Moleón, JJ (2017) Parental and child factors associated with under-estimation of children with excess weight in Spain. Matern Child Health J 21, 20522060.CrossRefGoogle Scholar
Doolen, J, Alpert, PT & Miller, SK (2009) Parental disconnect between perceived and actual weight status of children: a metasynthesis of the current research. J Am Acad Nurse Pract 21, 160166.CrossRefGoogle ScholarPubMed
Jones, AR, Parkinson, KN, Drewett, RFet al. (2011) Parental perceptions of weight status in children: the Gateshead Millennium Study. Int J Obes (Lond) 35, 953962.CrossRefGoogle ScholarPubMed
Lundahl, A, Kidwell, KM & Nelson, TD (2014) Parental underestimates of child weight: a meta-analysis. Pediatrics 133, E689E703.CrossRefGoogle ScholarPubMed
Manios, Y, Moschonis, G, Karatzi, Ket al. (2015) Large proportions of overweight and obese children, as well as their parents, underestimate children’s weight status across Europe. The ENERGY (EuropeaN Energy balance Research to prevent excessive weight Gain among Youth) project. Public Health Nutr 18, 21832190.CrossRefGoogle ScholarPubMed
Sylvetsky-Meni, AC, Gillepsie, SE, Hardy, Tet al. (2015) The impact of parents’ categorization of their own weight and their child’s weight on healthy lifestyle promoting beliefs and practices. J Obes 2015, 307381.CrossRefGoogle ScholarPubMed
Moore, LC, Harris, CV & Bradlyn, AS (2012) Exploring the relationship between parental concern and the management of childhood obesity. Matern Child Health J 16, 902908.CrossRefGoogle ScholarPubMed
Figure 0

Table 1 Mean parent-reported and measured anthropometric data in 4-year-old children, by sex. Autonomous Community of Madrid, Spain, 2012 (n 2914)

Figure 1

Table 2 Prevalence of weight status estimated using parent-reported or measured height and weight, and prevalence ratio (PR), in 4-year-old children, by sex and weight status classification. Autonomous Community of Madrid, Spain, 2012 (n 2914)

Figure 2

Table 3 Sensitivity, specificity and positive predictive value (PPV) of obesity and overweight using parent-reported measures in 4-year-old children, by sex and weight status classification. Autonomous Community of Madrid, Spain, 2012 (n 2914)

Figure 3

Fig. 1 Proportion of weight status misclassification (, same weight status category; , higher weight status category; , lower weight status category) with parent-reported data in children aged 4 years when compared with weight status calculated using measured data (WHO and International Obesity Task Force (IOTF) classifications). Autonomous Community of Madrid, Spain, 2012 (n 2529)

Figure 4

Fig. 2 Prevalence of overweight and obesity calculated with measured data in children aged 4 years (WHO and International Obesity Task Force (IOTF) classifications; values above bars), and proportion of parental misperception* (; values within bars), in total and by sex. Autonomous Community of Madrid, Spain, 2012 (n 2529). *Parental misperception: child described by parents as having ‘normal weight’, ‘a little thin’ or ‘thin’ and classified in the category ‘overweight’ or ‘obesity’ according to measured data

Supplementary material: File

Esteban-Vasallo et al. supplementary material

Table S1

Download Esteban-Vasallo et al. supplementary material(File)
File 27 KB
Supplementary material: File

Esteban-Vasallo et al. supplementary material

Table S2

Download Esteban-Vasallo et al. supplementary material(File)
File 25.5 KB