Is the muscle–tendon architecture of non-athletic Kenyans different from that of Japanese and French males?

1. Human gastrocnemius medialis architecture was analysed in vivo, by ultrasonography, as a function of joint angle at rest and during voluntary isometric contractions up to the maximum force (MCV). maximum force (MVC). 2. At rest, as ankle joint angle increased from 90 to 150 deg, pennation increased from 15.8 to 27.7 deg, fibre length decreased from 57.0 to 34.0 mm and the physiological cross-sectional area (PCSA) increased from 42.1 to 63.5 cm2. 3. From rest to MVC, at a fixed ankle joint angle of 110 deg, pennation angle increased from 15.5 to 33.6 deg and fibre length decreased from 50.8 to 32.9 mm, with no significant change in the distance between the aponeuroses. As a result of these changes the PCSA increased by 34.8%. 4. Measurements of pennation angle, fibre length and distance between the aponeuroses of the gastrocnemius medialis were also performed by ultrasound on a cadaver leg and found to be in good agreement with direct anatomical measurements. 5. It is concluded that human gastrocnemius medialis architecture is significantly affected both by changes of joint angle at rest and by isometric contraction intensity. The remarkable shortening observed during isometric contraction suggests that, at rest, the gastrocnemius muscle and tendon are considerably slack. The extrapolation of muscle architectural data obtained from cadavers to in vivo conditions should be made only for matching muscle lengths.

To generate body mass index (weight/height(2) (kg/m(2)), BMI) reference values for 0 to 45-y-old Danes and compare these with published European reference values. A national sample used to generate the current Danish height and weight reference (29 106 measurements made 1965-1977; age 0-21 y; sample I), and four samples from Copenhagen (3391 measurements made 1981-1985; age 7-45 y; samples II-III and 2608 measurements made 1991-1994; age 6-45 y; samples IV-V). Using the LMS method, Danish BMI reference values by age and sex were constructed from samples I and II. These were compared with BMI reference values from Sweden (age 6-16 (girls) or 6-19 y (boys)), Germany (6-19 y), UK (0-23 y), and France (0-87 y). Two recently examined but smaller Danish cohorts (samples IV and V) were compared with the reference values to assess the secular trend in BMI. Overall, Danish BMI reference values (samples I and II) fitted best with French reference values and were systematically below UK, Swedish and German reference values. However, the BMI centiles of young adult Danish women were above French reference values and the BMI of Danes was substantially below French and UK reference values during the first months of life. The mean BMI Z-score of the recently examined samples was 0.24 (sample IV, P=0.0001) and 0.15 (sample V, P=0.0001) based on the French reference values and 0.19 (sample IV, P=0.0007) and 0.01 (sample V, P=0.49) based on the Danish reference values. For clinical purposes, we recommend comparing the BMI of Danish children and adolescents with the present Danish reference values and the new IOTF cut-off values and comparing the BMI of Danish adults with the WHO cut-off values. For research purposes, cut-off values and national or internationally used BMI reference values may be used, depending on the research questions.

Hopping, skipping, jumping and sprinting are common tasks in both active play and competitive sports. These movements utilise the stretch-shortening cycle (SSC), which is considered a naturally occurring muscle action for most forms of human locomotion. This muscle action results in more efficient movements and helps optimise relative force generated per motor unit recruited. Innate SSC development throughout childhood and adolescence enables children to increase power (jump higher and sprint faster) as they mature. Despite these improvements in physical performance, the underpinning mechanisms of SSC development during maturational years remain unclear. To the best of our knowledge, a comprehensive review of the potential structural and neuromuscular adaptations that underpin the SSC muscle action does not exist in the literature. Considering the importance of the SSC in human movement, it is imperative to understand how neural and structural adaptations throughout growth and maturation can influence this key muscle action. By understanding the factors that underpin functional SSC development, practitioners and clinicians will possess a better understanding of normal development processes, which will help differentiate between training-induced adaptations and those changes that occur naturally due to growth and maturation. Therefore, the focus of this article is to identify the potential underpinning mechanisms that drive development of SSC muscle action and to examine how SSC function is influenced by growth and maturation.