Most cross-sectional studies exploring the association between physical activity and body fat have shown an inverse association between them. Thus, a multicenter study conducted on 1292 European children7 (aged 9–10 years) and another study conducted on 251 Canadian children (aged 8–11 years)8 noted that the time devoted to moderate or vigorous physical activity was inversely related to the amount of total body fat (measured as the sum of skinfolds).

Various studies suggest that vigorous physical activity may play a leading role in the prevention of obesity in children and adolescents.4 Gutin et al.9 noted that only vigorous physical activity was associated with a lower amount of body fat in North American adolescents (16 years), which agrees with the results reported in younger individuals.10–12 Dencker et al.11 in a sample of Swedish children (aged 8–11 years), and Butte et al.13 in a sample of Hispanic children/adolescents living in the USA (aged 4–19 years), also noted a negative association between vigorous physical activity and body fat. The results recorded by our group in Estonian and Swedish children aged 9–10 years participating in the European Youth Heart Study (EYHS) support the previously discussed results.12 This latter study showed that children who performed vigorous activity for 40min or longer had less body fat than those performing vigorous activity for a total of 10 to 18min daily. One of the most relevant studies conducted to date on this subject was the Avon Longitudinal Study of Parents and Children, where 5500 children aged 12 years were assessed using dual X-ray absorptiometry (DXA).14 The authors found an inverse relationship between physical activity and adiposity, which became even more noticeable in boys as compared to girls. They similarly showed that the amount of body fat was more strongly associated with vigorous physical activity than with total physical activity accumulated during the day. Our group recently studied the relationship between objectively measured physical activity (using accelerometers) and total body fat measured by reference (DXA and BodPod) and anthropometric methods in Spanish adolescents aged 12.5–17.5 years who participated in the Healthy Lifestyle in Europe by Nutrition in Adolescence study (HELENA, www.helenastudy.com).15 The results showed that vigorous physical activity appears to have a greater effect on total and central fat than less intense physical activity, which agrees with the results of the previously discussed studies.

Based on a joint assessment of the above reported studies, it may be concluded that adequate scientific evidence is available to state that an inverse relationship exists between physical activity level and body fat, and that this association is more consistent when vigorous (as compared to less intense, i.e. moderate) physical activity is performed. It should however be noted that assuming the same duration, high intensity physical exercise involves a greater calorie expenditure than moderate exercise. It is currently unknown whether the effect on fat seen with high intensity as compared to moderate intensity activities is due to effort intensity itself or simply to the greater calorie expenditure associated with such activity. Strictly speaking, this issue can only be solved by duly controlled and designed intervention studies which measure the effects of two types of activity of different intensity and duration but similar calorie expenditure.

Regardless of the total amount of fat mass of a person, its distribution in the body is also relevant for health. Several studies have shown that abdominal fat, measured by waist circumference, is associated with a significant number of cardiovascular disease risk factors in adolescents,16 even for a given weight category (normal weight, overweight, or obesity).17 Although accurate and sophisticated methods are now available for assessing central or abdominal fat (e.g. magnetic resonance imaging, computed tomography, DXA, etc.), waist perimeter has been shown to be a good marker of truncal fat and has been widely used in many epidemiological studies because of it low cost and easy measurement.18

Our group studied a sample of Swedish children (9 years) and adolescents (15 years) and noted that those showing low levels (first tertile) of vigorous physical activity had a greater risk of having a waist circumference suggesting higher cardiovascular risk as compared to those showing high levels of vigorous physical activity (third tertile).19 These results agree with data from more recent studies showing a negative association between physical activity, especially vigorous physical activity, and central fat.20–22 By contrast, conflicting results were found when physical activity was assessed using questionnaires. In Spanish adolescents (aged 13–18.5 years) participating in the study Alimentación y Valoración del Estado Nutricional en Adolescentes (AVENA), no association was seen between physical activity and waist circumference,23 while another study reported an inverse association in 12-year-old French children.24

It has been suggested that the level of physical fitness of a child, adolescent, or adult may influence the potential effect of physical activity on various health parameters. This hypothesis was initially analyzed by us in relation to truncal fat, measured using waist circumference, in 1075 Swedish children and adolescents.25 The results suggest that the association between physical activity and truncal fat varies depending on aerobic capacity (a marker of physical fitness level). In subjects with poor physical fitness, an inverse relationship was seen between physical activity and truncal fat. Moreover, the relationship became positive when analyzed in subjects with a good level of physical fitness. We are currently replicating this study in a cohort of European adolescents who participated in the HELENA study in order to confirm or refute these results and thus better understand the role played by this relationship in the achieving of physical fitness.

Information from longitudinal studies using objective measures of physical activity in children/adolescents is scarce but consistent. A recent systematic review on this subject suggested that an inverse relationship exists between physical activity levels at a given time in childhood and fat contents in the future (follow-up time ranging from ∼2 to 15 years).6 The BMI was the anthropometric variable used in most studies, and only two of them included the measurement of total body fat based on skinfold measurements and/or bioelectric impedanciometry.

Four studies explored longitudinal relations between physical activity measured by accelerometry and total body fat (Table 1).26–29 Three of the four studies mentioned noted an inverse relation between physical activity level and future body fat. Special mention should be made of the Janz et al. study, which assessed the time devoted to physical activities of different intensities and percent fat, measured by DXA, in 378 children (aged 4–6 years).29 The results supported those found in cross-sectional studies, i.e. that vigorous, but not moderate, physical activity was associated with lower body fat levels three years later.

No longitudinal studies have been found exploring the long-term effect of objectively measured physical activity on central fat in children and adolescents. Future research to study this subject in greater depth is needed.

Recent research has demonstrated the amount of interest there now is in knowing the physical fitness of children and/or adolescents.5,32 The results of the EYHS study showed that even in healthy children aged 9–10 years, those who had greater aerobic capacity also had lower levels of total adiposity as measured based on skinfolds.5,32 Our group also showed an inverse relationship between aerobic capacity and waist circumference in Swedish children and adolescents participating in the same study.25 Data from the AVENA study also suggested that aerobic capacity was associated with waist circumference in Spanish adolescents.25

These data agree with those from other studies where body fat was assessed using more sophisticated techniques.5 In line with this, we examined the relationship between physical fitness (i.e. aerobic capacity and muscle strength) and total and central body fat measured by DXA in Spanish adolescents participating in the HELENA study. The results showed that both aerobic capacity and muscle strength in the upper body were inversely associated with all body fat parameters after adjusting for different confounding variables, including objectively measured physical fitness.35 In this regard, Ara et al.36 reported very similar results in a sample of prepubertal Spanish children (∼9 years). Winsley et al.37 measured central fat by magnetic resonance imaging and noted that children with greater physical fitness levels also had lower truncal fat levels.

The role of muscle strength in the practice of exercise and the activities of daily life, and in the prevention of various diseases, has been paid increasing attention in recent years.31,32 The inverse relationship between the muscle strength of the lower body and body fat seen in the HELENA study agrees with the results obtained in the AVENA38 and other studies.39,40

Several studies have shown that aerobic capacity in childhood and adolescence predicts for total and central adiposity of a person years later, and also in adulthood (Table 2).41–51 The Amsterdam Growth and Health Longitudinal Study was one of the pioneering studies providing additional information concerning the longitudinal associations between physical fitness in childhood/adolescence and health parameters in adulthood. In this regard, Twisk et al.48 analyzed the association between the aerobic capacity of adolescents aged 13–16 years and their body fat at the age of 32 years. The results showed that adolescents with higher aerobic capacity levels also had lower levels of total body fat (the sum of four skinfolds) and truncal fat (waist to hip ratio) at 32 years of age.

Data from longitudinal studies with less years of follow-up show very similar results. McMurray et al.44 conducted a seven-year longitudinal study and noted that children (aged 7–10 years) with low aerobic capacity (first tertile) had a 5.5–6-fold greater chance of having overweight and obesity, as well as metabolic syndrome, at adolescence (14–17 years) as compared to the group having better physical fitness levels. Byrd-Williams et al.46 similarly found in a four-year longitudinal study (Study of Latino Adolescents at Risk) that children aged 11 years with greater physical fitness levels had a lower increase in total body fat measured by DXA at 15 years.

Three longitudinal studies analyzed the relationship between muscle strength and total and central body fat.49–51 Barnekow-Bergkvist et al.50 measured muscle strength in adolescents aged 15–18 years and the BMI, waist circumference, and waist-hip ratio 18 years later. The results suggested that muscle strength predicted BMI in males and females at 34 years, so that those who had greater muscle strength levels in adolescence had lower BMI values at 34 years. However, the results for the central fat markers were not so clear. Janz et al.51 (The Muscatine Study) and Hasselstrøm et al.49 (Danish Youth and Sports Study) analyzed the relationship between changes in muscle strength and body fat parameters over several years. Both studies concluded that changes in muscle strength from childhood to adolescence (10–15 years)51 or from adolescence to adulthood (15–19 to 23–27 years)49 were negatively related to total body fat levels (measured by skinfolds) and waist circumference. Twisk et al.48 calculated a physical fitness index including measurements of muscle strength, flexibility, speed, and coordination. The results showed a negative relationship between the physical fitness index and mean total body fat measured by the sum of four subcutaneous skinfolds.

The prestigious group of Professor Blair was the first to note that people overweight or obese who had acceptably high physical fitness levels could have a better state of health than those who had the same level of overweight but poorer physical fitness. In fact, people rated as “fat but fit” (with excess fat but fit) had a similar cardiovascular risk profile as those with a normal weight for their age and sex but who had low physical fitness levels.

Our group conducted several studies in children and adolescents using data derived from the AVENA and EYHS cohorts and noted that adolescents with overweight and high muscle strength levels (third tertile) had lower body mass levels (the sum of six skinfolds) as compared to the group with overweight and low muscle strength levels (first tertile) (Fig. 3).52 Similarly, children with high body fat levels were found, as expected, to have a poorer lipid profile,53 higher blood pressure levels,54 and insulin resistance.55 However, these cardiovascular health parameters were attenuated in the group also having high aerobic capacity. This suggests that an improved aerobic capacity may counteract the negative effects of body fat on cardiovascular health parameters. Physical exercise programs aimed at improving physical fitness in children and adolescents with overweight and/or obesity may therefore be of great social, economic, and health interest.

Figure 3.

Body fat in adolescents with overweight-obesity and low (first tertile) or high (third tertile) muscle strength levels (hand grip strength index and the standing broad jump test). Adapted from Ruiz et al.52

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