Spelling suggestions: "subject:"maximal aerobic capacity"" "subject:"maximal aerobic apacity""
1 |
The Relationship Between Maximal Aerobic Capacity and Left Ventricular Function with Respect to AgePage, Kimberly Ann 12 1900 (has links)
In this study, the relationship between maximal aerobic capacity (VO₂max) and left ventricular function was examined in two distinct age groups. A young group (20 - 30 years of age) and an elderly group (over 60 years of age) were compared. Left ventricular function was examined over wide variations in preload accomplished by 5º head-down tilt (TILT) for ninety minutes and lower body negative pressure (LBNP) to -40 mm Hg. with two-dimensional echocardiography. A greater response to an increase in preload (TILT) was related to high VO₂max levels in the young subjects but not in the elderly groups of subjects, suggesting that lower VO₂max levels of the elderly population affected the mechanism of response to the increased levels of preload. Additionally, in the elderly, greater reductions in ventricular volume reflected increased peripheral pooling due to decreased venous tone and/or increased venous compliance during LBNP and were related to increased VO₂max. In the young, VO₂max does not appear to affect the response to reduced preload.
|
2 |
Adult Phenotypic Plasticity in Thermogenesis: An Interpopulation Study using High and Low Altitude Deer MiceWall, Nastashya 11 1900 (has links)
High altitude is one of the most extreme environments experienced by terrestrial mammals due to both low ambient temperatures and oxygen availability. Deer mice native to high altitude have a greater thermogenic capacity in hypoxia compared to a lowland population, likely as a consequence of both genetic adaptations and phenotypic plasticity. To understand the adaptive variation in phenotypic plasticity, F1 generation lab-reared mice were acclimated to chronic warm-hypoxia, cold-normoxia, and cold-hypoxia.
Acclimation led to equal increases in thermogenic capacity in hypoxia for all stressors in high altitude deer mice. Low altitude mice also increased their thermogenic capacity after acclimation, with a distinct increase after acclimation to cold-hypoxia. The thermogenic capabilities of the high and low altitude mice tested in hypoxia were equal, suggesting that both populations of mice had reached a “metabolic ceiling”. Basal metabolic rate increased after acclimation to cold and cold-hypoxia. Nonshivering thermogenesis was not affected by acclimation or altitude ancestry. Shivering thermogenesis contributed 70 to 80 % of total heat produced during VO2summit across all acclimations, and in both populations. VO2summit in hypoxia was supported by lipids in deer mice even though carbohydrates would provide an oxygen saving advantage. Also, rates of lipid oxidation increased after acclimation to cold, and cold combined with hypoxia in the high altitude population.
Together these findings suggest that the increased thermogenic capacity of the high altitude wild mice is based both on differences in phenotypic plasticity, and on differences in genotype from the low altitude mice. Adult phenotypic plasticity is pivotal in the thermogenic capabilities of both populations, and it is likely that developmental plasticity also plays an important role. / Thesis / Master of Science (MSc)
|
3 |
RELATIONSHIP BETWEEN CHANGES IN MAXIMAL AEROBIC CAPACITY AND METABOLIC PROFILES IN OBESE YOUTHSWellbery, Laura Mary 30 June 2003 (has links)
No description available.
|
4 |
Associations of Blood and Performance Parameters with Signs of Periodontal Inflammation in Young Elite Athletes: An Explorative StudyMerle, Cordula Leonie, Richter, Lisa, Challakh, Nadia, Haak, Rainer, Schmalz, Gerhard, Needleman, Ian, Rüdrich, Peter, Wolfarth, Bernd, Ziebolz, Dirk, Wüstenfeld, Jan 24 January 2024 (has links)
This retrospective cross-sectional study aimed to explore interactions between signs of
periodontal inflammation and systemic parameters in athletes. Members of German squads with
available data on sports medical and oral examination were included. Groups were divided by
gingival inflammation (median of papillary bleeding index, PBI median) and signs of periodontitis
(Periodontal Screening Index, PSI 3). Age, gender, anthropometry, blood parameters, echocardiography,
sports performance on ergometer, and maximal aerobic capacity (VO2max) were evaluated.
Eighty-five athletes (f = 51%, 20.6 3.5 years) were included (PBI < 0.42: 45%; PSI 3: 38%).
Most associations were not statistically significant. Significant group differences were found for
body fat percentage and body mass index. All blood parameters were in reference ranges. Minor
differences in hematocrit, hemoglobin, basophils, erythrocyte sedimentation rates, urea, and HDL
cholesterol were found for PBI, in uric acid for PSI. Echocardiographic parameters (n = 40) did not
show any associations. Athletes with PSI 3 had lower VO2max values (55.9 6.7 mL/min/kg
vs. 59.3 7.0 mL/min/kg; p = 0.03). In exercise tests (n = 30), athletes with PBI < 0.42 achieved
higher relative maximal load on the cycling ergometer (5.0 0.5 W/kg vs. 4.4 0.3 W/kg; p = 0.03).
Despite the limitations of this study, potential associations between signs of periodontal inflammation
and body composition, blood parameters, and performance were identified. Further studies on the
systemic impact of oral inflammation in athletes, especially regarding performance, are necessary.
|
Page generated in 0.0551 seconds