Because of the increasing prevalence of obesity in industrialised and developing countries(1), assessment of body composition and its variation has to be accurate to manage obesity better and its physiological, clinical and social consequences. One of the main objectives of obesity management is to reduce fat mass (FM) and to preserve fat-free mass (FFM) during weight loss in order to maintain the physical capacities and energy expenditure of obese subjects(Reference Lazzer, Boirie, Montaurier, Vernet, Meyer and Vermorel2).
Several studies have pointed out the potential of dual-energy X-ray absorptiometry (DXA) for the assessment of total and regional body composition, because of the relatively quick scan time, the minimal radiation dose and the good reproducibility of measurements(Reference Mazess, Barden, Bisek and Hanson3, Reference Svendsen, Haarbo, Hassager and Christiansen4). DXA has been validated against the four-compartment model(Reference Tylavsky, Lohman, Blunt, Schoeller, Fuerst, Cauley, Nevitt, Visser and Harris5, Reference Silva, Minderico, Teixeira, Pietrobelli and Sardinha6), underwater weighing(Reference Tataranni and Ravussin7) and direct chemical analysis(Reference Svendsen, Haarbo, Hassager and Christiansen4, Reference Mitchell, Conway and Scholz8). The CV of repeated measurements of FFM with DXA is 2 %(Reference Mazess, Barden, Bisek and Hanson3, Reference Pritchard, Nowson, Strauss, Carlson, Kaymakci and Wark9). For these reasons, DXA is often used as a reference method for body composition assessment in obese children and adolescents in clinical and research settings(Reference Gately, Radley, Cooke, Carroll, Oldroyd, Truscott, Coward and Wright10, Reference Radley, Gately, Cooke, Carroll, Oldroyd and Truscott11). Underwater weighing has long been considered the gold-standard for body composition assessment(Reference Dempster and Aitkens12) and, until recently, was considered the only reliable and valid technique for the measurement of body density in human subjects(Reference McCrory, Gomez, Bernauer and Mole13). However, estimation of body density using underwater weighing requires a lengthy and sometimes uncomfortable test, involving the measurement of residual volume in the lungs, as well as complete submersion in water. The development of air displacement plethysmography (ADP) provides another method to measure body density in research and clinical settings and ADP has been proposed as an alternative to underwater weighing(Reference McCrory, Gomez, Bernauer and Mole13). In addition, ADP has been validated in overweight and obese children(Reference Gately, Radley, Cooke, Carroll, Oldroyd, Truscott, Coward and Wright10, Reference Radley, Gately, Cooke, Carroll, Oldroyd and Truscott11) and adults(Reference Ginde, Geliebter, Rubiano, Silva, Wang, Heshka and Heymsfield14).
Bioelectrical impedance analysis (BIA), a safe, non-invasive and portable method, is also widely used for estimating body composition(Reference Houtkooper, Lohman, Going and Howell15, Reference Eisenkolbl, Kartasurya and Widhalm16). However, several factors limit its application to obese subjects: body geometry and body water distribution are in fact different from those of normal-weight subjects(Reference Wells, Fuller, Dewit, Fewtrell, Elia and Cole17). The prediction equations developed in normal-weight subjects generally overestimate FFM in obese adults(Reference Deurenberg18) and children(Reference Eisenkolbl, Kartasurya and Widhalm16). However, DXA and ADP are expensive methods for assessing body composition in the clinical setting so that a cheap, quick and reliable method is needed to assess body composition of severely obese subjects.
The objectives of the present study were (1) to compare body composition measured by DXA, ADP and BIA in severely obese Caucasian children and adolescents and (2) to develop and cross-validate prediction equations of body composition in obese children and adolescents from BIA measurements using DXA as the reference method.
Subjects and methods
Study protocol
The study group comprised fifty-eight obese subjects (twenty-seven boys and thirty-one girls) aged 10–17 years with a BMI above the ninety-seventh percentile for sex and age(Reference Cacciari, Milani, Balsamo, Dammacco, De Luca, Chiarelli, Pasquino, Tonini and Vanelli19). The subjects were recruited from the Division of Auxology, Italian Institute for Auxology, IRCCS, Piancavallo (Verbania) Italy. Subjects who had overt metabolic and/or endocrine diseases or who were taking medications that would alter body water content were excluded from the study. The study protocol was approved by the Ethical Committee of the Italian Institute for Auxology, Milan (Italy). The purpose of the study was carefully explained to each subject and his or her parents, who gave their written informed consent. Anthropometry, DXA, ADP and BIA were performed on the same day by the same investigators.
An external group of sixty-one obese children and adolescents recruited at the Paediatrics Department of the Clermont-Ferrand Hospital (France), who had participated in previous studies(Reference Lazzer, Boirie, Meyer and Vermorel20, Reference Lazzer, Vermorel, Montaurier, Meyer and Boirie21), was used to validate the new body-composition equation developed in the present study.
Anthropometry and pubertal assessment
Body weight (BW) was measured to the nearest 0·1 kg with a mechanical weighing scale (Seca 709; Seca Ltd, Germany). Stature was measured to the nearest 0·1 cm using a floor-standing stadiometer (Model 220; Seca Ltd, UK). BMI was calculated as weight (kg) divided by height (m)2(Reference Quetelet22). The standard deviation score of BMI (BMI-SDS) was determined using the least-mean-square method with Italian reference values(Reference Cacciari, Milani, Balsamo, Dammacco, De Luca, Chiarelli, Pasquino, Tonini and Vanelli19). Circumferences at the waist and hip were measured in triplicate to the nearest 0·1 cm using an inelastic tape following the Anthropometric Standardization Reference Manual(Reference Lohman, Roche and Martorell23).
Pubertal stage was evaluated according to Tanner(Reference Tanner24) on a scale from 1 to 5, with stage 1 being prepubertal, and stage 5 being adult. The same paediatrician assessed Tanner staging during the study.
Dual-energy X-ray absorptiometry
Body composition was assessed using a GE/Lunar Prodigy densitometer (GE Lunar Medical Systems, Milwaukee, WI, USA)(Reference Mazess, Hanson, Payne, Nord and Wilson25). The scanner was calibrated daily against the standard calibration block supplied by the manufacturer in order to control for possible baseline drift. The subjects lay supine on the bed and were scanned from head to toe. The scanner utilises a narrow fan beam (4·5°) parallel to the longitudinal axis of the body. Scans were analysed using Paediatric software version 1.5. Manufacturer's algorithms provide a three-compartment analysis consisting of non-bone lean tissue mass, FM, and bone mineral content (BMC) ash. BMC was calculated as (BMC ash × 1·0436)(Reference Brozek, Grande, Anderson and Keys26). FFM was defined as the sum of lean tissue mass and BMC.
For ethical reasons, repeated measurements were not performed on the study children. In our laboratory, the within-day CV for measurement of percentage fat-mass (%FM) in eight obese adults measured twice (with repositioning) is 2·3 % (data not shown).
Air displacement plethysmography
Body density was assessed using BOD-POD (Life Measurement Incorporated, Concord, CA, USA) coupled with software version 1.69, according to the manufacturer's directions and procedures(Reference Dempster and Aitkens12). Before subject evaluation, a two-point chamber calibration was performed using the empty chamber and a 50·218 litre calibration cylinder. Subjects were clothed in a tight-fitting bathing suit and acrylic bathing cap and were weighed to the nearest 0·1 kg using the ADP system's electronic scale. The scale was calibrated daily using a 20 kg weight.
After the calibration was completed, the subject entered the ADP. Body volume was corrected for lung air volume, with thoracic gas volume measured during tidal breathing and during exhalation against a mechanical obstruction. Subjects were excluded from the study if thoracic gas volume could not be measured. Body density was calculated as the ADP-measured body mass divided by (total body volume+0·40 × thoracic gas volume − surface area artefact). The surface area artefact was calculated by the ADP software to account for the changes in air temperature close to the subject's skin. Body fatness was then calculated by using the general equation of Siri (ADPSiri)(Reference Siri, Brozek and Henschel27), and the age- and sex-specific equations of Lohman (ADPLohman)(Reference Lohman28). In our laboratory, the CV for measurement of %FM in ten obese adolescents measured twice on the same day was 3·0 % (data not shown).
Bioelectrical impedance analysis
Whole-body impedance (Z) was measured using a multifrequency (from 5 to 250 kHz) impedance-meter (Human IM Plus II; DS Medica, Milan, Italy). Measurements were performed according to the method of Lukaski(Reference Lukaski29) after 25 min resting in a supine position with arms and legs relaxed and abducted at an angle of 45°. The impedance index (ZI) was calculated as (stature (cm)2 divided by Z at 50 kHz (Ω)). Estimates of body composition were obtained from the equipped software (unknown equations). FM was obtained by subtracting FFM from BW and %FM by dividing FM by BW. The within-day CV for three repeated measurements of FFM in ten obese adolescents (with repositioning) was 2·2 % (data not shown).
Statistical analysis
Statistical analysis was performed using STATA 9.2 (StataCorp, College Station, TX, USA). Statistical significance was set to a two-tailed P value of < 0·05. All continuous variables were normally distributed (Shapiro–Wilk test) and are given as means and standard deviations (sd). The Bland–Altman(Reference Bland and Altman30) method was used to calculate the limits of agreement ( ± 2 sd) between ADP and BIA v. DXA for the assessment of %FM and Pitman's test was used to evaluate proportional bias(Reference Ludbrook31). Bias was defined as the difference between %FM estimated by BIA or measured by ADP and %FM measured by DXA.
For the development of new BIA equations, selection of variables was performed by stepwise bootstrapped linear regression on 1000 random samples of the fifty-eight subjects(Reference Harrell32). Candidate predictors were sex, age, body mass, ZI and phase angle and Tanner staging. For internal cross-validation, the standard error and 95 % CI of the final prediction model were calculated by bootstrap analysis on 1000 random samples of the fifty-eight subjects(Reference Gonçalves and White33). Values of the adjusted coefficient of determination and of the root mean squared error of the estimate (RMSE) with bootstrapped 95 % CI were used to assess the accuracy of predictors.
An external cross-validation of the prediction equation was performed on an independent group of sixty-one obese children and adolescents enrolled in a previous study(Reference Lazzer, Boirie, Meyer and Vermorel20, Reference Lazzer, Vermorel, Montaurier, Meyer and Boirie21). Differences between FFM measured by DXA and FFM estimated from BIA were evaluated using the Bland–Altman method(Reference Bland and Altman30). In addition, we calculated the percentage of subjects whose FFM was predicted within 5 % of measured FFM. This limit was chosen as being consistent with technical measurement errors of 5 % or less.
Results
Subject characteristics
The physical characteristics of the study group are shown in Table 1. All subjects were obese, with BMI-SDS ranging from 2·1 to 4·1(Reference Cacciari, Milani, Balsamo, Dammacco, De Luca, Chiarelli, Pasquino, Tonini and Vanelli19). Age, BW, waist circumference and waist:hip ratio were not significantly different between boys and girls. Stature was significantly higher in boys than in girls (P < 0·001). However, pubertal stage, BMI, BMI-SDS and hip-circumferences were significantly lower in boys than in girls (P < 0·05).
BMI-SDS, standard deviation score for BMI.
Mean values were significantly different from those of the boys by ANOVA of the main effects of sex: *P < 0·05; **P < 0·001.
Mean values were significantly different between groups (Study group v. External group; ANOVA): †P < 0·001.
‡ For details of procedures, see Subjects and methods.
§ Study group subjects were recruited from the Division of Auxology, Italian Institute for Auxology, IRCCS, Piancavallo (VB), Italy.
∥ External group subjects were recruited from the Paediatrics Department of the Clermont-Ferrand Hospital, France(Reference Lazzer, Boirie, Meyer and Vermorel20, Reference Lazzer, Vermorel, Montaurier, Meyer and Boirie21).
¶ Pubertal stage according to Tanner(Reference Tanner24).
FFM obtained by DXA was significantly higher in boys than in girls (P < 0·05) while FM and %FM were significantly lower in boys than in girls (P < 0·005). BMC, Z and phase angle were not significantly different between boys and girls.
The external and the internal study group had similar values of age, stature and FFM but the external group had lower values of BW, BMI, BMI-SDS, FM, %FM and BMC (P < 0·001) (Table 1).
Comparison of dual-energy X-ray absorptiometry and other methods
The mean difference between BW measured by DXA and BW measured by scale was − 0·2 (sd 0·8) kg (P = 0·025) and the corresponding value for ADP was − 0·2 (sd 0·6) kg (P = 0·005). Even if the mean differences were significantly different from 0, the bias values are low and of no practical relevance.
The Bland–Altman method(Reference Bland and Altman30) revealed wide limits of agreement between DXA and ADP or BIA for the assessment of %FM so that the methods could not be considered interchangeable (Table 2 and Fig. 1).
* For details of procedures, see Subjects and methods.
† t test between measured %FM by DXA v. air-displacement plethysmography (ADPSiri and ADPLohman) and BIA.
‡ r-Pitman, Pearson's correlation coefficient for the Pitman's test; P-Pitman, P value corresponding to r value for the Pitman's test.
As compared to DXA, the ADPSiri method underestimated %FM by 2·1 (sd 3·4) percent units in the whole group (P < 0·001, Fig. 1 (a)). In boys, the difference was not significant ( − 1·2 (sd 3·8) percent units, P = 0·097), but in girls a significant underestimation of − 2·9 (sd 2·9) percent units (P < 0·001) was found. In addition, the ADPLohman method underestimated %FM by 3·8 (sd 3·3) percent units in the whole group (P < 0·001, Fig. 1 (b)). In boys and in girls %FM was significantly underestimated by − 2·8 (sd 3·6) and − 4·7 (sd 2·7) percent units, respectively, (P < 0·001). Moreover, %FM estimated by the ADPSiri method was significantly higher than %FM estimated by the ADPLohman method (+1·7 (sd 1·4) percent units, P < 0·001) (Table 2).
BIA underestimated %FM by 5·8 (sd 4·6) percent units (P < 0·001, Fig. 1 (c)). In boys and girls, %FM was underestimated to a similar degree (6·1 (sd 4·2) and 5·6 (sd 4·2) percent units, respectively, P < 0·001).
The ADP–DXA bias tended however to increase for increasing levels of %FM (Pitman's r 0·401, P = 0·002 for Siri and r 0·315, P < 0·001 for Lohman) so that the agreement between APD and DXA was influenced by the underlying level of adiposity. This was not apparent however for the BIA–DXA relationship (Pitman's r 0·103, P < 0·441).
Development and validation of bioelectrical impedance analysis equations
To identify predictors of FFM for BIA algorithms, we performed a bootstrapped stepwise linear regression using FFM assessed by DXA as the outcome variable and sex, age, Tanner stage, weight, ZI and phase angle as predictors. ZI was a predictor in 1000 out of 1000 bootstrap samples, weight in 868, sex in 584, Tanner staging in 414, age in 115 and phase angle in 265. Thus, we focused on ZI and weight as predictors for the BIA algorithm.
Because weight explained only 50 % of the variance of FFM assessed by DXA (RMSE = 6·4 kg, P < 0·001) as compared to a value of 91 % for ZI (RMSE = 2·7 kg, P < 0·001) and the addition of weight to ZI did not improve the prediction (adjusted coefficient of determination = 0·92, RMSE = 2·6 kg, P < 0·001), we considered only ZI as predictor, with the following algorithm:
The 95 % bootstrapped CI of the regression coefficients are 0·81 to 0·92 (P < 0·0001) for ZI and 0·29 to 5·87 (P = 0·03) for intercept.
In the external cross-validation group, the mean estimated FFM was significantly lower than assessed FFM (48·9 (sd 8·7) v. 50·4 (sd 9·9) kg, P < 0·001), with limits of agreement between +4·1 and − 7·2 kg. FFM was predicted within 5 % of the true value in 75 % of subjects, overestimated in 3 % and underestimated in 22 % (Fig. 2).
Discussion
The results of the present study show that the methods used (DXA, ADP and BIA) are not interchangeable for the assessment of body composition of obese children and adolescents. The suitable alternative approach to DXA to assess body composition, in these subjects, was BIA using a new prediction equation based on the ZI parameter.
The results of validation tests against the four-compartment model(Reference Tylavsky, Lohman, Blunt, Schoeller, Fuerst, Cauley, Nevitt, Visser and Harris5, Reference Silva, Minderico, Teixeira, Pietrobelli and Sardinha6), hydrodensitometry(Reference Tataranni and Ravussin7), and chemical analysis(Reference Svendsen, Haarbo, Hassager and Christiansen4, Reference Mitchell, Conway and Scholz8) as well as the good repeatability of measurements of FFM(Reference Mazess, Barden, Bisek and Hanson3, Reference Pritchard, Nowson, Strauss, Carlson, Kaymakci and Wark9) show that DXA is an accurate and precise method for measuring soft-tissue body composition in cross-sectional and longitudinal studies in human subjects(Reference Going, Massett, Hall, Bare, Root, Williams and Lohman34).
The ADP method was well correlated with DXA in athletes and in adults and children(Reference Miyatake, Nonaka and Fujii35–Reference Maddalozzo, Cardinal and Snow37). However, the results of our study suggest that ADPSiri and ADPLohman underestimate %FM in obese individuals, compared to DXA and this is in agreement with previous studies(Reference Levenhagen, Borel, Welch, Piasecki, Piasecki, Chen and Flakoll38, Reference Lockner, Heyward, Baumgartner and Jenkins39). The major disadvantage of techniques based on the two-compartment model (FFM and FM) is the assumption concerning density of FFM(Reference Lohman40). In children and adolescents, FFM is sensitive to variability in hydration status resulting in an unstable density of FFM in relation to growth(Reference Wells, Fuller, Dewit, Fewtrell, Elia and Cole17). Further uncertainty arises in obese subjects as the result of excess fat(Reference Waki, Kral, Mazariegos, Wang, Pierson and Heymsfield41). In addition, there was a trend towards the underestimation of %FM assessed by ADPSiri and ADPLohman particularly in girls ( − 2·9 and − 4·7 percent units). This is similar to the findings of other studies, which reported that %FM assessed by ADP was significantly underestimated by 3·0 percent units, particularly in girls(Reference Nicholson, McDuffie and Bonat42, Reference Buchholz, Majchrzak, Chen, Shankar and Buchowski43). In addition, the age- and sex-specific equations of Lohman(Reference Lohman28) showed a higher %FM difference than the Siri(Reference Siri, Brozek and Henschel27) equation when compared with DXA, as observed by Radley et al. (Reference Radley, Gately, Cooke, Carroll, Oldroyd and Truscott11) in a previous study, which suggest that the reasons for the slight underestimation of %FM by ADP relative to DXA in obese children and adolescents therefore remain to be elucidated.
Compared to DXA, BIA underestimated %FM in a similar way to the results of previous studies(Reference Eisenkolbl, Kartasurya and Widhalm16, Reference Okasora, Takaya, Tokuda, Fukunaga, Oguni, Tanaka, Konishi and Tamai44). The differences in %FM between BIA and DXA might result both from overestimation of FFM hydration in obese subjects(Reference Wells, Fuller, Dewit, Fewtrell, Elia and Cole17, Reference Waki, Kral, Mazariegos, Wang, Pierson and Heymsfield41), and from the peculiar distribution of FM in the body(Reference Deurenberg18). The assumption that 73·2 % lean body mass consists of total body water is possibly not correct. In healthy persons the water content of FFM is constant only after age 20 years(Reference Schoeller45). In the obese, however, FFM hydration may be up to 75 %(Reference Wells, Fuller, Dewit, Fewtrell, Elia and Cole17, Reference Waki, Kral, Mazariegos, Wang, Pierson and Heymsfield41). This finding could cause an overestimation of the FFM which in turn could underestimate the FM(Reference Deurenberg18).
The second objective of this study was to develop and validate new prediction equations of body composition in obese adolescents from BIA using DXA as the reference method. The present study focused on the prediction of FFM rather than FM, because of the necessity of preserving FFM in weight-reduction programmes, and the ability of BIA to predict FFM from its high water and electrolyte content(Reference Houtkooper, Lohman, Going and Hall46). BIA is a popular, simple, rapid, and non-invasive method to estimate total body water and FFM in healthy people. This technique has been cross-validated in children against methods using measurements of total body water by deuterium dilution(Reference Wabitsch, Braun, Heinze, Muche, Mayer, Teller and Fusch47) and total body K(Reference Schaefer, Georgi, Zieger and Scharer48). However, several factors limit its application to obese subjects: assumption of constancy in the hydration factor of FFM, and body water distribution and body geometry. Therefore, the use of the prediction equations must be limited to the type of population in which they have been validated(Reference Houtkooper, Lohman, Going and Howell15, Reference Deurenberg18). Thus, when prediction equations developed in non-obese subjects are used for obese subjects, FFM is overestimated and consequently FM is underestimated(Reference Eisenkolbl, Kartasurya and Widhalm16, Reference McNeill, Fowler, Maughan, McGaw, Fuller, Gvozdanovic and Gvozdanovic49–Reference de Lorenzo, Sorge, Iacopino, Andreoli, de Luca and Sasso51). The prediction equation developed in the present study allowed a satisfactory estimation of body composition in obese adolescents from measurements of stature and body impedance. In addition, the high accuracy observed in an external validation group (75 % of subjects with predicted values within 5 % of true values), shows that the new equation may be useful for health care professionals, who have access to BIA equipment, for the estimation of FFM in severely obese children and adolescents.
Strengths of this study include the use of DXA, a robust and well-accepted measure as the criterion method and the use of Bland–Altman comparisons in the interpretation of results. Limitations include the relatively small sample size and the fact that the new equation is only applicable for overweight and obese Caucasian children and adolescents. In addition, the results obtained from the comparison between methods may not be applicable to other BIA and ADP devices or software.
In conclusion, the results of the present study show that DXA, ADP and BIA are not interchangeable for the assessment of body composition in obese children and adolescents and that a population-specific BIA equation may be a suitable approach for assessing body composition in these children and adolescents.
Acknowledgements
The authors are grateful to the children and adolescents who participated in this study and their parents. We thank all the doctors and nurses at the Division of Auxology, Italian Institute for Auxology, IRCCS, and the staff at the UMR 1019, INRA, Human Nutrition Research Centre (Clermont-Ferrand, France) for their kind assistance during the study. We also thank Dr C. Lafortuna and Dr M. Vermorel for their valuable advice to improve the manuscript and Dr J. M. H. Buckler for revising the English. The study was supported by Progetti di Ricerca Corrente, Italian Institute for Auxology, Milan, Italy.
There are no real or potential conflicts of financial or personal interest with authors and the financial sponsors of the scientific project.