The purpose of this study was to use estimates of body composition from a four-component model to determine whether the density of the fat-free mass (DFFM) is affected by muscularity or musculoskeletal development in a heterogenous group of athletes and nonathletes. Measures of body density by hydrostatic weighing, body water by deuterium dilution, bone mineral by whole body dual-energy X-ray absorptiometry (DXA), total body skeletal muscle estimated from DXA, and musculoskeletal development as measured by the mesomorphy rating from the Heath-Carter anthropometric somatotype were obtained in 111 collegiate athletes (67 men and 44 women) and 61 nonathletes (24 men and 37 women). In the entire group, DFFM varied from 1.075 to 1.127 g/cm3 and was strongly related to the water and protein fractions of the fat-free mass (FFM; r = −0.96 and 0.89) and moderately related to the mineral fraction of the FFM ( r = 0.65). Skeletal muscle (%FFM) varied from 40 to 68%, and mesomorphy varied from 1.6 to 9.6, but neither was significantly related to DFFM( r = 0.11 and −0.14) or to the difference between percent fat estimated from the four-component model and from densitometry ( r = 0.09 and −0.16). We conclude that, in a heterogeneous group of young adult athletes and nonathletes, DFFM and the accuracy of estimates of body composition from body density using the Siri equation are not related to muscularity or musculoskeletal development. Athletes in selected sports may have systematic deviations in DFFM from the value of 1.1 g/cm3 assumed in the Siri equation, resulting in group mean errors in estimation of percent fat from densitometry of 2–5% body mass, but the cause of these deviations is complex and not simply a reflection of differences in muscularity or musculoskeletal development.
Scleraxis genes are required for normal musculoskeletal development and for rib growth and mineralization in zebrafish
