16 research outputs found
Can Collegiate Hockey Players Accurately Predict Regional and Total Body Physiologic Changes throughout the Competitive Season?
A collegiate athlete’s body composition can fluctuate due to factors such as nutrition, sleep, and training load. As changes in body composition can affect an athlete’s level of performance, it may be beneficial if athlete’s can accurately predict these changes throughout a season. The purpose of this study was to determine how well a group of 23 male collegiate hockey players (age = 22.44 ± 1.16 years, height = 181.30 ± 6.99 cm, weight = 86.41 ± 8.32 kg) could predict their regional and total body lean and fat tissue mass throughout a hockey season (September to March). Total body, trunk, lower body, and upper body compositional changes were measured at the beginning and at the end of the competitive season using dual energy X-Ray absorptiometry (DXA). At the end of the season, a questionnaire was completed by each participant to explore how they perceived their body composition changes (losses or gains in lean tissue and fat mass) throughout the season. Overall, players had a difficult time identifying actual changes in lean tissue and fat mass throughout the season. Upper body fat and lean tissue changes were perceived most accurately, while perceptions of body fat were related to android adiposity but not visceral adiposity. These findings suggest that some regional areas of body composition changes may happen without being noticed. For strength and conditioning coaches, if athletes are made aware of these changes before they become exaggerated, proper dietary, and training adaptations can be made to enhance performance
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Sympathetic Responses to Isometric Handgrip Exercise in Women following Preeclamptic Pregnancies
Women who have had preeclamptic (PE) pregnancies are at increased risk for developing cardiovascular diseases later in life. One potential mechanism that may mediate this increased risk is sympathetic dysregulation. Indeed, there is evidence for elevated muscle sympathetic nerve activity (MSNA) both during and following PE pregnancies. Moreover, previously PE (PPE) women may demonstrate impaired MSNA responses during stress, although this has only been examined to a limited extent. Therefore, we tested the hypothesis that MSNA responses to isometric hand grip exercise (HG) would be greater in PPE women (n=6, age 31±6 years, BMI 29±5 kg/m
, 17±4 months postpartum) compared with women who had a healthy pregnancy (HP; n=8, age 29±2, BMI 25±4 kg/m
, 14±4 months postpartum). MSNA (peroneal nerve microneurography), mean arterial pressure (MAP; finger photoplethysmography), and total peripheral resistance (TPR; MAP/cardiac output), were assessed at baseline, during a 2-min HG protocol, and during 2-min post-exercise circulatory occlusion (PECO). As previously reported, baseline MSNA was higher in PPE than HP (22±7 vs 13±5 bursts/min, P=0.01). Baseline MAP was not different between PPE and HP (94±11 vs 89±9 mmHg, P=0.23), nor was TPR (13±3 vs 13±2 mmHg/L/min, P=0.63). During HG, MSNA was greater in PPE than HP (24±8 vs 16±6 bursts/min, P=0.03), whereas MAP was not different between PPE and HP (95±12 vs 95±11 mmHg, P=0.99), nor was TPR (13±3 vs 14±2 mmHg/L/min, P=0.39). During PECO, no differences were observed between PPE and HP women in MSNA (26±8 vs 18±6 bursts/min, P=0.08), MAP (93±12 vs 96±12 mmHg, P=0.70), or TPR (12±3 vs 15±2 mmHg/L/min, P=0.18). These findings indicate that PPE women demonstrate exaggerated MSNA during isometric HG exercise relative to HP women, although the role of the metaboreflex in mediating this effect, as assessed using PECO, remains unclear. Importantly, these data also demonstrate that young PPE women were able to buffer the deleterious cardiovascular outcomes of elevated MSNA such that MAP and TPR outcomes were similar to age-matched HP women during all conditions