Physiologic and Perceptual Responses to Cold-Shower Cooling After Exercise-Induced Hyperthermia

Exercise conducted in hot, humid environments increases the risk for exertional heat stroke (EHS). The current recommended treatment of EHS is cold-water immersion; however, limitations may require the use of alternative resources such as a cold shower (CS) or dousing with a hose to cool EHS patient...

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Bibliographic Details
Published in:Journal of athletic training 2016-03, Vol.51 (3), p.252-257
Main Authors: Butts, Cory L, McDermott, Brendon P, Buening, Brian J, Bonacci, Jeffrey A, Ganio, Matthew S, Adams, J D, Tucker, Matthew A, Kavouras, Stavros A
Format: Article
Language:English
Subjects:
Adult
Anatomy
Body composition
Body temperature
Body Temperature - physiology
Climate
Cold
Cooling
Cross-Over Studies
Cryotherapy
Exercise - physiology
Exercise Test
Female
Fever
Heart Rate - physiology
Heat
Heat Stress Disorders - physiopathology
Heat Stress Disorders - psychology
Heat Stress Disorders - therapy
Heatstroke
Humans
Illnesses
Male
Muscle pain
Myalgia - psychology
Original Research
Outcome Measures
Patients
Perception - physiology
Research Methodology
Scientific Concepts
Skin
Studies
Thermosensing - physiology
Water
Young Adult
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Summary:Exercise conducted in hot, humid environments increases the risk for exertional heat stroke (EHS). The current recommended treatment of EHS is cold-water immersion; however, limitations may require the use of alternative resources such as a cold shower (CS) or dousing with a hose to cool EHS patients. To investigate the cooling effectiveness of a CS after exercise-induced hyperthermia. Randomized, crossover controlled study. Environmental chamber (temperature = 33.4°C ± 2.1°C; relative humidity = 27.1% ± 1.4%). Seventeen participants (10 male, 7 female; height = 1.75 ± 0.07 m, body mass = 70.4 ± 8.7 kg, body surface area = 1.85 ± 0.13 m(2), age range = 19-35 years) volunteered. On 2 occasions, participants completed matched-intensity volitional exercise on an ergometer or treadmill to elevate rectal temperature to ≥39°C or until participant fatigue prevented continuation (reaching at least 38.5°C). They were then either treated with a CS (20.8°C ± 0.80°C) or seated in the chamber (control [CON] condition) for 15 minutes. Rectal temperature, calculated cooling rate, heart rate, and perceptual measures (thermal sensation and perceived muscle pain). The rectal temperature (P = .98), heart rate (P = .85), thermal sensation (P = .69), and muscle pain (P = .31) were not different during exercise for the CS and CON trials (P > .05). Overall, the cooling rate was faster during CS (0.07°C/min ± 0.03°C/min) than during CON (0.04°C/min ± 0.03°C/min; t16 = 2.77, P = .01). Heart-rate changes were greater during CS (45 ± 20 beats per minute) compared with CON (27 ± 10 beats per minute; t16 = 3.32, P = .004). Thermal sensation was reduced to a greater extent with CS than with CON (F3,45 = 41.12, P < .001). Although the CS facilitated cooling rates faster than no treatment, clinicians should continue to advocate for accepted cooling modalities and use CS only if no other validated means of cooling are available.
ISSN:1062-6050
1938-162X
DOI:10.4085/1062-6050-51.4.01