Temperature and force-velocity relationship of human muscles

Binkhorst, R. A.; Hoofd, Louis; Vissers, A. C. A.

doi:10.1152/jappl.1977.42.4.471

Cited by 87 publications

(64 citation statements)

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“…The maximal summer temperature predicted (32.5°C) 3834 speed-related traits are highly temperature dependent whereas forcerelated traits are less dependent on temperature. These different performance trait profiles are consistent with studies on the influence of temperature on muscle function (Bennett, 1980;Bergh and Ekblom, 1979;Binkhorst et al, 1977;Petrofsky et al, 1981;Anderson and Deban, 2012) and whole-organism performance (Herrel et al, 2007;Anderson and Deban, 2010). Furthermore, most of the differences found in the comparison of force-related traits involved temperatures under 25°C, whereas temperature independence of force generation by muscle is known to range from 25 to 40°C (Bergh and Ekblom, 1979;Binkhorst et al, 1977;Petrofsky et al, 1981).…”

Section: Discussionsupporting

confidence: 86%

“…The specific aim of this study was to determine the temperature dependence of selected performance traits (bite force, hand and tail force, and sprint speed) for each species. We predicted that speed-related performance traits should be highly temperature dependent (Bennett, 1980), yet force-related performance should be less temperature dependent (Bergh and Ekblom, 1979;Binkhorst et al, 1977;Herrel et al, 2007;Petrofsky et al, 1981), thus differentially affecting behavior. These predictions are based on previous results (e.g.…”

Section: Introductionmentioning

confidence: 99%

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Impacts of temperature on performance in two species of South African dwarf chameleons,Bradypodion pumilumandB. occidentale

Segall

Tolley

Vanhooydonck

et al. 2013

Journal of Experimental Biology

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SUMMARYTemperature is an extrinsic factor that influences reptile behavior because of its impact on reptile physiology. Understanding the impact of temperature on performance traits is important as it may affect the ecology and fitness of ectothermic animals such as reptiles. Here, we examined the temperature dependence of performance in two species of South African dwarf chameleon (Bradypodion): one adapted to a semi-arid environment and one to a mesic environment. Ecologically relevant performance traits were tested at different temperatures to evaluate their thermal dependence, and temperature-performance breadths for 80% and 90% of each performance trait were calculated. Our results show distinct differences in the thermal dependence of speed-versus force-related performance traits. Moreover, our results show that the semi-arid species is better adapted to higher temperatures and as such has a better chance of coping with the predicted increases in environmental temperature. The mesic area-adapted species seems to be more sensitive to an increase in temperature and could therefore potentially be threatened by the predicted future climate change. However, further studies investigating the potential for acclimation in chameleons are needed to better understand how animals may respond to future climate change.

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Section: Discussionsupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Impacts of temperature on performance in two species of South African dwarf chameleons,Bradypodion pumilumandB. occidentale

Segall

Tolley

Vanhooydonck

et al. 2013

Journal of Experimental Biology

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“…temperature decreases muscle stiffness and improves the forcevelocity relationship (Binkhorst et al, 1977;Bishop, 2003b;Febbraio et al, 1996;Ranatunga et al, 1987). Moreover, French et al (2003) suggested that a warm-up including a heavy load may induce a high-frequency stimulation of motor neurons and enhance motor neuron excitability.…”

Section: Discussionmentioning

confidence: 99%

Effect of Linear Polarized Near-infrared Light Irradiation and Light Exercise on Muscle Performance

Demura

Aoki

et al. 2011

J Physiol Anthropol

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This study aimed to determine the effect of active warm-up by local muscle light exercise and passive warm-up by polarized light irradiation on skin and muscle temperatures and forearm muscle performance (muscle strength, power, endurance, and controlled force-exertion). Ten healthy males performed various grip tests before and after active (local muscle light exercise) and passive (linear polarized nearinfrared light irradiation) warm-ups. An active warm-up involved intermittent gripping exercise (contraction: 1 second and relaxation: 1 second) for 10 minutes using a sponge. A passive warm-up consisted of polarized light irradiation to the forearm (superficial digital flexor) for 10 minutes (irradiation: 5 seconds and rest: 1 second). Skin and muscle temperatures were measured during both warm-ups. Skin and muscle temperatures increased significantly after 5 minutes of local muscle light exercise and after 10 minutes of polarized light irradiation. Temperatures were significantly higher after 6 minutes of local muscle light exercise than after 6 minutes of polarized light irradiation. There were no significant differences of muscle strength, power, and controlled forceexertion before and after either warm-up. Average force outputs in all conditions significantly decreased with exertion time, and at 30, 60, 90, and 120 seconds they were higher in both warm-up conditions than in the non-warm-up condition. In conclusion, both warm-ups may contribute to improve muscle endurance performance in the decreasing force phase.

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“…For instance, increases in body and muscle temperatures following a warm-up are thought to increase nerve impulse transmission, and hence increase muscular contraction speed (Woods et al, 2007). Increasing muscle temperature was accompanied with elevation in maximal velocity, maximal power, and an improvement in the force-velocity relationship (Binkhorst et al, 1977). Also, warm-up-induced elevated muscle temp 2max resulted in greater ATP and inosine 5`-monophosphate degradation during exercise, lower post-exercise muscle glycogen content, and higher post-exercise lactate concentration, indicating elevation in glycogenolysis, glycolysis, and high energy phosphate degradation (Febbraio et al, 1996) O 2max , one leg was heated and the other was cooled prior to and during exercise using water-perfused cuffs.…”

Section: Mechanisms Of Warm-up Effects On Performancementioning

confidence: 99%

“…Such muscle function includes twitch tension, maximal force, and rate and velocity of muscle contraction, all of which have been reported to decrease with reduced local temperature (Binkhorst et al, 1977;Sargeant, 1987;Ranatunga et al, 1987;Bigland-Ritchie et al, 1992;Racinais & Oksa, 2010;Cheuvront et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Precooling and Warm-up Effects on Time Trial Cycling Performance During Heat Stress

Al-Horani

Wingo

2015

Medicine &Amp; Science in Sports &Amp; Exercise

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The aim of this study was to investigate the separate and combined effects of precooling and warm-up on a subsequent cycling time trial in a hot environment. Nine healthy men (mean±SD age=24±5 years; body mass=74.7±4.5 kg; height=171.4±7.7 cm; body fat=12.9±5.2%) completed 3 simulated 16.1-km time trials on a cycle ergometer in a hot environment (~33 °C, 45% relative humidity) after: 1) 20 min of fluid ingestion (10 °C ) followed by 30 min of ice-slurry ingestion (-1 °C ) coupled with ice-vest (PREC), 2) 30 min of ice-slurry ingestion coupled with ice-vest followed by 20 min of warm-up including ice-slurry and ice-vest (COMBO), 3) 30 min of fluid ingestion (10 °C) followed by 20 min of warm-up (WU). At baseline, rectal temperature (T re ), mean skin temperature ( sk ), and mean body temperature ( b ) were similar among treatments (all P>0.05). After treatment administration and before the start of the time trial, T re was lower in PREC (36.1±0.3) and COMBO (36.9±0.4) compared to WU (37.6±0.2) (all P<0.05). sk and b were all lower in PREC than COMBO and WU, and were lower in COMBO than WU (all P<0.05). T re remained lower in PREC than WU throughout exercise and was lower in PREC than COMBO for the first 12 km (all P<0.01), while T re in COMBO remained lower than WU for the first 4 km. sk during PREC was lower than COMBO at 4 and 8 km and lower than WU at 0 and 4 km, while during COMBO it was lower than WU at 0 and 4 km (all P<0.05). Heart rate (HR) at baseline was lower in PREC than COMBO and WU (68±10, 106±12, 101±13 beats/min, respectively; P<0.001). During exercise, HR increased similarly among all treatments throughout exercise (all P>0.05). Local sweat rate (SR) was lower in PREC than COMBO and WU for the first 4 km (P < iv ACKNOWLEDGMENTS All praise is due to Allah, the entirely merciful; I thank him and praise him. He is the one who protects and guards me in the days when I work, and in the nights when I sleep. He amply bestowed his favors and bounties upon me, and gave me from all I asked of him, and if I should count his favors, surely I could not enumerate.Then, I would like to express my deepest gratitude to my advisor Dr. Jonathan Wingo for his guidance, knowledge, patience, diligence, and dedication throughout this dissertation stages.He was very generous in teaching the procedures of research, from how to professionally use the laboratory equipment, to how to write a solid work of research. He has been sincere, respectful, and hardworking. I am also thankful to my dissertation committee, Dr. Philip Bishop, Dr. Mark Richardson, Dr. Edward Mansfield, and Dr. John Vincent. Their inputs, suggestions, and recommendations were very effective in directing the research into the right way. Also I thank them for their cooperation and sacrifices to finish this dissertation successfully.

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Temperature and force-velocity relationship of human muscles

Cited by 87 publications

References 0 publications

Impacts of temperature on performance in two species of South African dwarf chameleons,Bradypodion pumilumandB. occidentale

Impacts of temperature on performance in two species of South African dwarf chameleons,Bradypodion pumilumandB. occidentale

Effect of Linear Polarized Near-infrared Light Irradiation and Light Exercise on Muscle Performance

Precooling and Warm-up Effects on Time Trial Cycling Performance During Heat Stress

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