Training, muscle volume, and energy expenditure in nonobese American girls

Little is known about the relationship among training,energy expenditure, muscle volume, and fitness in prepubertalgirls. Because physical activity is high in prepubertalchildren, we hypothesized that there would be no effect of training.Forty pre- and early pubertal (mean age 9.1 ± 0.1 yr) nonobesegirls enrolled in a 5 day/wk summer school program for 5 wk and were randomized to control (n = 20) or training groups(n = 20; 1.5 h/day, endurance-type exercise). Totalenergy expenditure (TEE) was measured using doubly labeled water, thighmuscle volume using magnetic resonance imaging, and peak O₂uptake (O_2 peak) using cycle ergometry.TEE was significantly greater (17%, P < 0.02) in thetraining girls. Training increased thigh muscle volume (+4.3 ± 0.9%, P < 0.005) andO_2 peak (+9.5 ± 6%,P < 0.05), effects surprisingly similar to thoseobserved in adolescent girls using the same protocol (Eliakim A,Barstow TJ, Brasel JA, Ajie H, Lee W-NP, Renslo R, Berman N, and CooperDM, J Pediatr 129: 537-543, 1996). We furthercompared these two sample populations: thigh muscle volume per weightwas much lower in adolescent compared with prepubertal girls (17.0 ± 0.3 vs. 27.8 ± 0.6 ml/kg body mass; P < 0.001), and allometric analysis revealed remarkably low scaling factorsrelating muscle volume (0.34 ± 0.05, P < 0.0001), TEE (0.24 ± 0.06, P < 0.0004), andO_2 peak (0.28 ± 0.07, P < 0.0001) to body mass in all subjects. Muscle andcardiorespiratory functions were quite responsive to brief training inprepubertal girls. Moreover, a retrospective, cross-sectional analysissuggests that increases in muscle mass andO_2 peak may be depressed in nonobeseAmerican girls as they mature.

     

Age of the menarche of girls in Thessaloniki, Greece

In 1982-1983 a total of 977 girls from Thessaloniki has been investigated for their menarcheal ages, using the retrospective and the status quo methods. 565 of these girls aged between 11 and 18.5 years (age classes 1964-1972) were found to menstruate. The mean menarcheal age amounts to 12.0 years. The results are compared with corresponding data from literature. They confirm a clear secular trend for the menarcheal age in Greek population.     

Zinc,copper, and sexual maturation in 9-18-year-old girls and boys

The relationships between serum levels of zinc and copper and sexual maturation were analyzed in 2291 9-18-yr-old Finnish girls and boys. Development of public hair, breasts, and genitalia were used to grade maturation according to Tanner's classification. Serum zinc and sexual maturation were not related. However, 15- and 18-yr-old girls who had matured most slowly had low serum levels of zinc compared with their age mates. Thus, sexual maturation seems not to be affected by zinc deficiency in Finland; effects of zinc status on maturation in some minor groups cannot, however, be excluded. Serum copper levels were associated with age and sexual maturation, which complicates the drawing of conclusions about possible deficiencies.     

Menarche in Newcastle upon Tyne girls

Using data for 699 white girls from Newcastle upon Tyne, England, who were born in 1962, the authors examine the relationship between age at menarche and selected social and anthropometric variables. Factors considered include family size, birth order, father's occupation, birth weight, and height and weight at five years of age and at menarche (SUMMARY IN FRE, GER)     

Fetal growth: boys before girls

At term birth, boys are heavier than girls. This difference is thought to be generated in part by androgen action; its time course has not been deciphered. Androgen action may not only increase weight gain, but may also alter its time course. We have tested this hypothesis by examining the difference in gestational age of 281,894 boys and girls with weights between 500-4,749 g. The age at which children are born with a given weight was found to depend on gender: boys were consistently younger than girls (p < 0.001), the age difference being most pronounced in the lower birth weight classes. Thus, the gender difference in fetal growth appears to be rather pronounced before the third trimester and relatively less marked towards term. In conclusion, the male conceptus seems to grow not only more, but also earlier than the female. Hence, some critical time windows of development may be slightly different in boys and girls, and this phenomenon may be one of the bases for gender differences in the sensitivity to fetal programming. Copyrightz1999S. KargerAG,Basel     

Why girls want to be boys

The mechanisms by which sex is genetically determined are bewilderingly diverse and appear to change rapidly during evolution.( 1 ) What makes the sex‐determining process so prone to perturbations? Two recent articles( 2 , 3 ) explore theoretically the role of genetic conflict in sex determination evolution. Both studies use the idea that selection on sex‐determining genes may act differently in parents and in offspring and they suggest that the resulting conflict can drive changes in sex‐determining mechanisms. BioEssays 23:477–480, 2001. © 2001 John Wiley & Sons, Inc.     

Diurnal and seasonal cortisol, testosterone, and DHEA rhythms in boys and girls during puberty

Diurnal and seasonal rhythms of cortisol, testosterone, and DHEA were examined, as little is known about the relationship between these rhythmicities and pubertal development. Salivary samples were obtained from 60 boys and 60 girls at approximately 07:45, 08:00, 08:30, 12:00, 16:50, and 21:00 h. The participants' ages ranged from 8-14 yrs, and each participant was tested three times at six-month intervals. The study was conducted at a General Clinical Research Center (GCRC) and at the homes of the participants. All hormones showed diurnal fluctuations. The acrophase (peak time) of cortisol occurred earlier than for testosterone or DHEA and showed a seasonal effect, with the acrophase occurring earlier in spring than in summer. The cortisol acrophase also occurred later in the day for boys than for girls during later puberty. Seasonal effects were found only for cortisol with higher concentrations in the spring and summer. Cortisol concentrations were relatively stable across pubertal maturation, but significantly lower concentrations were observed at pubertal stage 3 compared to the other stages. Morning cortisol levels were also higher in boys at pubertal stage 2. Testosterone concentrations were higher in boys at pubertal stages 3 and 4, and DHEA was lower at pubertal stage 1 than 3 and 4 for both boys and girls. For the total sample, there was a positive correlation between DHEA and testosterone during early puberty (stages 1-3) but not later puberty (stages 4-5). Awakening secretory activity correlated with daytime secretory activity for testosterone and DHEA, but not for cortisol. These data provide novel chronobiological information on cortisol, testosterone, and DHEA as it relates to sexual maturation and encourage further study on both normal and abnormal endocrine rhythms.