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Estimating Resting Core Temperature Using Heart Rate

David P. Looney, Mark J. Buller, Andrei V. Gribok, Jayme L. Leger, Adam W. Potter, William V. Rumpler, William J. Tharion, Alexander P. Welles, Karl E. Friedl, and Reed W. Hoyt

In healthcare and in general living conditions body core temperature (CT) is considered one of the most informative indicators of thermal stress ( Montain, Sawka, Cadarette, Quigley, & McKay, 1994 ; Sawka et al., 2001 ), a key indicator in thermal comfort ( Gagge et al., 1967 ), and has a wide

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Core Temperature Responses to Elite Racewalking Competition

Christopher John Stevens, Megan L. Ross, Julien D. Périard, Brent S. Vallance, and Louise M. Burke

investigation were to present a brief summary of the core temperature responses of elite race walkers during competition, as well as the use of cooling strategies, and symptoms of heat illness. Methods Subjects A total of 14 elite/preelite racewalking athletes participated in this study including 9 females (age

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Changes in Core Temperature During an Elite Female Rugby Sevens Tournament

Mitchell J. Henderson, Bryna C.R. Chrismas, Christopher J. Stevens, Aaron J. Coutts, and Lee Taylor

.0 (37.8 to 38.6) 37.7 (37.2 to 38.0) 37.9 (37.7 to 38.2) 0.4 (0.3 to 0.7) 0.8 (0.6 to 1.2) 1.2 (0.7 to 1.6) 6.6 19:50–20:06 Abbreviations: BL, baseline; CWI, cold-water immersion; min, minimum; Tc, core temperature; WBGT, wet-bulb globe temperature; WU, warm-up. Note: Data are presented as median

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Limiting the Rise in Core Temperature During a Rugby Sevens Warm-Up With an Ice Vest

Lee Taylor, Christopher J. Stevens, Heidi R. Thornton, Nick Poulos, and Bryna C.R. Chrismas

During World Rugby Sevens Series (WRSS) match play in temperate (wet bulb globe temperature range: 14–19.2°C) and warm (wet bulb globe temperature range: 25–27°C) conditions, peak player core temperatures ( T c ) of 39.6°C and 39.9°C, respectively, have been observed. 1 When T c is >39°C

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Core Temperature Responses to Cold-Water Immersion Recovery: A Pooled-Data Analysis

Jessica M. Stephens, Ken Sharpe, Christopher Gore, Joanna Miller, Gary J. Slater, Nathan Versey, Jeremiah Peiffer, Rob Duffield, Geoffrey M. Minett, David Crampton, Alan Dunne, Christopher D. Askew, and Shona L. Halson

attributed the enhanced recovery of maximal voluntary contraction force to faster return of central activation, which is the result of larger CWI-induced reductions in core temperature ( T c ). 3 With hyperthermia-mediated fatigue being a key fatiguing factor for many forms of exercise, 1 a greater

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Analysis of Factors Associated With Continued Cooling of Core Temperature After Prolonged Cold-Water Swimming

Joffrey Drigny, Corentin Hingrand, Pauline Moysan, Thibaud Collet, and Benoit Mauvieux

. Water temperature ranged from 12.5 to 13 °C. Table 1 Baseline Characteristics of Participants (N = 14) and Data on Core Temperature Participants (N = 14) Demographic  Age, mean (SD), y 38.29 (10.84)  Gender, n (%)   Men 11 (79%)   Women 3 (21%) Anthropometric  Body mass, mean (SD), kg 85.99 (18

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Thermal Sensation After the 10-km Open-Water Swimming in Cool Water Depends on the Skin’s Thermal Sensitivity Rather Than Core Temperature

Tomomi Fujimoto, Yuiko Matsuura, Yasuhiro Baba, and Reira Hara

maintenance of body temperature is important for safety and performance improvement. Core temperature ( T core ) is determined by the balance between heat production and heat loss, specifically during exercise in water, the former being exercise-related heat production and shivering and so on, 2 and the

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Hydration and Performance in Young Triathletes During a Competition in Tropical Climate

Anita M. Rivera-Brown and Patricia Pagán-Lassalle

production combined with environmental heat and humidity challenges the body’s heat dissipation mechanisms. In addition, in summer months, heat dissipation during the swim phase may be affected by the warm water temperature (>29 °C) ( 11 ), which may lead to dangerous elevations in core temperature ( T c

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Limiting Rise in Heat Load With an Ice Vest During Elite Female Rugby Sevens Warm-Ups

Mitchell J. Henderson, Bryna C.R. Chrismas, Christopher J. Stevens, Job Fransen, Aaron J. Coutts, and Lee Taylor

 m·s −1 ), maximum speeds of 8.05 (0.55) m·s −1 , maximum accelerations of 3.49 (0.38) m·s −2 , and 12.6 (4.7) impacts greater than 10 g . 11 These demands have been shown to elicit high core temperatures (Tc; 37.9°C–39.8°C), even in temperate conditions (18.9°C–20.1°C wet bulb globe temperature

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Cooling During Endurance Cycling in the Heat: Blunted Core Temperature but Not Inflammatory Responses

Sebastian Keller, Simon Kohne, Hannah L. Notbohm, Wilhelm Bloch, and Moritz Schumann

temperature, humidity, baseline urine specific gravity, and body mass loss were similar in both exercise conditions (Table  1 ). Core Temperature For Tcore, a statistical main effect was observed for time ( P  < .001) and interaction ( P  = .004). Tcore statistically increased in ICE by +5.1% (1.1%) ( P