The purpose of this study was to determine the effect of active heat acclimation on the sweat osmolality and sweat sodium ion concentration vs. sweat rate relationship in humans. Eight healthy male volunteers completed 10 days of exercise in the heat. The mean exercising heart rate and core temperature were significantly decreased (P < 0.05) by 18 beats/min and 0.6 degrees C, respectively, following heat acclimation. Furthermore, sweat osmolality and the sweat sodium ion concentration vs. sweat rate relationships were shifted to the right. Specifically, the slopes of the relationships were not affected by heat acclimation. Rather, heat acclimation significantly reduced the y-intercepts of the sweat osmolality and sweat sodium relationships with sweat rate by 28 mosmol/kgH(2)O and 15 mmol/l, respectively. Thus there was a significantly lower sweat sodium ion concentration for a given sweat rate following heat acclimation. These results suggest that heat acclimation increases the sodium ion reabsorption capacity of the human eccrine sweat gland.
Non-technical summary The mechanisms determining exercise intolerance are poorly understood. A reduction in work efficiency in the form of an additional energy cost and oxygen requirement occurs during high-intensity exercise and contributes to exercise limitation. Muscle fatigue and subsequent recruitment of poorly efficient muscle fibres has been proposed to mediate this decline. These data demonstrate in humans, that muscle fatigue, generated in the initial minutes of exercise, is correlated with the increasing energy demands of high-intensity exercise. Surprisingly, however, while muscle fatigue reached a plateau, oxygen uptake continued to increase throughout 8 min of exercise. This suggests that additional recruitment of inefficient muscle fibres may not be the sole mechanism contributing to the decline in work efficiency during high-intensity exercise.Abstract During constant work rate (CWR) exercise above the lactate threshold (LT), the exponential kinetics of oxygen uptake (V O 2 ) are supplemented by aV O 2 slow component (V O 2 sc ) which reduces work efficiency. This has been hypothesised to result from 'fatigue and recruitment' , where muscle fatigue during supra-LT exercise elicits recruitment of additional, but poorly efficient, fibres to maintain power production. To test this hypothesis we characterised changes in the power-velocity relationship during sub-and supra-LT cycle ergometry in concert withV O 2 kinetics. Eight healthy participants completed a randomized series of 18 experiments consisting of: (1) a CWR phase of 3 or 8 min followed immediately by; (2) a 5 s maximal isokinetic effort to characterize peak power at 60, 90 and 120 rpm. CWR bouts were: 20 W (Con); 80% LT (Mod); 20% (H); 60% (VH); where is the difference between the work rate at LT andV O 2 max . TheV O 2 sc was 238 ± 128 and 686 ± 194 ml min −1 during H and VH, with no discernibleV O 2 sc during Mod. Peak power in Con was 1025 ± 400, 1219 ± 167 and 1298 ± 233 W, at 60, 90 and 120 rpm, respectively, and was not different after Mod (P > 0.05). Velocity-specific peak power was significantly reduced (P < 0.05) by 3 min of H (−103 ± 46 W) and VH (−216 ± 60 W), with no further change by 8 min. TheV O 2 sc was correlated with the reduction in peak power (R 2 = 0.49; P < 0.05). These results suggest that muscle fatigue is requisite for theV O 2 sc . However, the maintenance of velocity-specific peak power between 3 and 8 min suggests that progressive muscle recruitment is not obligatory. Rather, a reduction in mechanical efficiency in fatigued fibres is implicated.
Given that ACTN3 XX genotype is negatively associated with elite sprint athlete status, the underlying low frequency in these populations eliminates the possibility of replicating this association in Jamaican and US African American sprinters. The finding of no excess in ACE DD or GG genotypes in elite sprint athletes relative to controls suggests that ACE genotype is not a determinant of elite sprint athlete status.
Rationale: ER stress dysregulates ER proteostasis, which activates the transcription factor, ATF6, an inducer of genes that enhance protein folding and restore proteostasis. Due to increased protein synthesis, it is possible that protein folding and, thus, ER proteostasis are challenged during cardiac myocyte growth. However, it is not known whether ATF6 is activated, and if so, what its function is during hypertrophic growth of cardiac myocytes. Objective: To examine the activity and function of ATF6 during cardiac hypertrophy. Methods and Results: We found that ATF6 was activated and ATF6-target genes were induced in mice subjected to an acute model of trans-aortic constriction (TAC), or to free-wheel exercise, which promote adaptive cardiac myocyte hypertrophy with preserved cardiac function. Cardiac myocyte-specific deletion of Atf6 (ATF6 cKO) blunted TAC- and exercise-induced cardiac myocyte hypertrophy and impaired cardiac function, demonstrating a role for ATF6 in compensatory myocyte growth. Transcript profiling and chromatin immunoprecipitation identified RHEB as an ATF6-target gene in the heart. RHEB is an activator of mTORC1, a major inducer of protein synthesis and subsequent cell growth. Both TAC and exercise upregulated RHEB, activated mTORC1, and induced cardiac hypertrophy in WT mouse hearts, but not in ATF6 cKO hearts. Mechanistically, knockdown of ATF6 in neonatal rat ventricular myocytes blocked phenylephrine (PE)-, and insulin-like growth factor 1 (IGF1)-mediated Rheb induction, mTORC1 activation, and myocyte growth, all of which were restored by ectopic RHEB expression. Moreover, AAV9-RHEB restored cardiac growth to ATF6 cKO mice subjected to TAC. Finally, ATF6 induced RHEB in response to growth factors, but not in response to other activators of ATF6 that do not induce growth, indicating that ATF6 target gene induction is stress-specific. Conclusions: Compensatory cardiac hypertrophy activates ATF6, which induces Rheb and activates mTORC1. Thus, ATF6 is a previously unrecognized link between growth stimuli and mTORC1-mediated cardiac growth.
Firefighters having higher cardiovascular fitness completed a series of simulated firefighting tasks more quickly than those having lower fitness. These results support the need of a high level of cardiovascular fitness for firefighters to ensure not only their safety, but that of fellow firefighters and rescue victims.
We developed an inquiry-based learning model to better stimulate undergraduate students’ cognitive development of exercise physiology laboratory concepts. The course core is the two independent research projects that students, working in small groups, complete during the last 9 wk of the semester. Student groups develop their own research question and hypothesis, design the experiment, collect and analyze the data, and report their findings to the rest of the class using presentation software. To help with success of the research projects, students are taken through a series of guided-inquiry laboratory activities during the initial 6 wk of the semester to develop laboratory skills and an understanding of the scientific process. Observations of student behaviors reflected a high level of enthusiasm and engagement in laboratory activities. Surveys, journal entries, and interviews indicated that students felt empowered by having ownership in their projects, which may be the key reason for the success of this model.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.