Page 118 - JSOM Summer 2019

P. 118

60. Casa DJ, Becker SM, Ganio MS, et al. Validity of devices that 85. Hamilton S, Dickson SJ, Smith JE. Hyponatremia on an oper-
assess body temperature during outdoor exercise in the heat. J ational deploymenrt in Southern Iraq—a case series. J R Army
Athl Training. 2007;42(3):333–342. Med Corps. 2006;92:114–117.
61. Thim T, Krarup NHV, Grove EL, et al. Initial assessment and 86. Kantor ED, Rehm CD, Du M, et al. Trends in dietary supple-
treatment with the airway, breathing, circulation, diability, expo- ment use among US adults from 1999–2012. JAMA. 2016;316
sure (ABCDE) approach. Int J Gen Med. 2012;5:117–121. (14):1464–1474.
62. Zhang Y, Davis JK, Casa DJ, et al. Optimizing cold water immer- 87. Lieberman HR, Stavinoha TB, McGraw SM, et al. Use of di-
sion for exercise-induced hyperthermia: a meta-analysis. Med Sci etary supplements among active-duty US Army soldiers. Am J
Sports Exerc. 2015;47(11):2464–2472. Clin Nutr. 2010;92(4):985–995.
63. Proulx CI, Ducharme MB, Kenny GP. Safe cooling limits from 88. Knapik JJ, Steelman R, Hoedebecke S, et al. A systematic re-
exercise-induced hyperthermia. Eur J Appl Physiol. 2006;96: view and meta-analysis on the prevalence of dietary supple-
434–445. ment use by military personnel. BMC Complement Altern Med.
64. Costrini A. Emergency treatment of exertional heatstroke and 2014;14:143.
comparison of whole body cooling techniques. Med Sci Sports 89. Knapik JJ, Trone DW, Austin KG, et al. Prevalence, adverse ef-
Exerc. 1990;22(1):15–18. fects, and factors associated with dietary supplement and nutri-
65. Beller GA, Boyd AE. Heat stroke: a report of 13 consecutive cases tional supplement use by United States Navy and Marine Corps
without mortality despite severe hyperyrexia and neurological personnel. J Acad Nutr Diet. 2016;116(9):1423–1442.
dysfunction. Mil Med. 1975;140:464–467. 90. Vaughan RA, Conn CA, Mermier CM. Effects of commerically
66. Demartini JK, Casa DJ, Stearns R, et al. Effectiveness of cold wa- available dietary supplements on resting energy expenditure: a
ter immersion in the treatment of exertional heat stroke at the Fal- brief report. ISRN Nutr. 2014;2014:650264.
mouth Road Race. Med Sci Sports Exerc. 2015;47(2):240–245. 91. Diepvens K, Westerterp KR, Westerterp-Plantenga MS. Obe-
67. Armstrong LE, Crago AE, Adams R, Roberts WO, Maresh CM. sity and thermogenesis relatede to the consumption of caffeine,
Whole body cooling of hyperthermic runners: comparison of two ephedrine, capsaicin, and green tea. Am J Physiol Regul Integr
field methods. Am J Emergency Med. 1996;14:355–358. Comp Physiol. 2006;202:R77–R85.
68. Kielblock AJ, Rensburg JPV, Franz RM. Body cooling as a method 92. Oh RC, Henning JS. Exertional heatstroke in an infantry solder
for reducing hyperthermia. South Afr Med J. 1986;69(6):378–380. taking ephedra-containing dietary supplement. Mil Med. 2003;
69. Tan PMS, Teo EYN, Ali NB, et al. Evaluation of various cool- 168:429–430.
ing systems after exercise induced hyperthermia. J Athl Training. 93. Charatan F. Ephedra supplement may have contributed to
2017;52(2):2017. sportsman’s death. Br Med J. 2003;326:464.
70. Costrini AM, Pitt HA, Gustafson AB, Uddin DE. Cardiovascular 94. FDA acts to remove Ephedra-containing dietary supplements
and metabolic manifestations of heat strpoke and severe heat ex- from market. http://www.fda.gov/NwesEvents/Newsroom/Press
haustion. Am J Med. 1979;66:296–302. Announcements/2004/ucm108379.htm. Accessed 13 August,
71. Payen JF, Bourdon L, Reutenauer H, et al. Exertional heatstroke 2015
and muscle metabolism: an in vivo P-MRS study. Med Sci Sports 95. Soni MG, Carbin IG, Griffiths JC, et al. Safety of ephedra: les-
31
Exerc. 1992;24(4):420–425. sons learned. Toxicol Lett. 2004;150:97-110.
72. Johnson EC, Kolkhorst FW, Richburg A, et al. Specific exercise 96. Pitchford NW, Fell JW, Leveritt MD, et al. Effect of caffeine on
heat stress protocol for a triathlete’s return from exertional heat cycle time-trial performance in the heat. J Sci Med Sports. 2014;
stroke. Curr Sports Med Rep. 2013;12(2):106–109. 17:445–449.
73. O’Connor FG, Heled Y, Deuster PA. Exertional heat stroke, re- 97. Beaumont RE, James LJ. Effect of a moderate caffeine dose on
turn to play decision, and the role of heat tolerance testing: a endurance cycle performance and thermoregulation during pro-
clinician’s dilemma. Curr Sports Med Rep. 2018;17(7):244–248. longed exercise in the heat. J Sci Med Sports. 2017;20:1024–1028.
74. Moran DS, Heled Y, Still L, et al. Assessment of heat tolerance for 98. Roelands B, Buyse L, Pauwels F, et al. No effect of caffeine on
post exertional heat-stroke individuals. Med Sci Monit. 2004;10 exercise performance in high ambient temperature. Eur J Appl
(6):CR252–CR257. Physiol. 2011;111:3089–3095.
75. Schermann H, Heled Y, Fleischmann C, et al. The validity of the 99. Hanson NJ, Martinez SC, Byl EN, et al. Increased rate of heat
heat tolerance test in prediction of recurrent exertional heat ill- storage, and no performance benefits, with caffeine injestion be-
ness events. J Med Sci Sports. 2018;21:549–552. fore a 10-km run in hot, humid conditions. Int J Sports Physiol
76. Ketko I, Eliyahu U, Epstein Y, et al. The thermo-circulatory ra- Perform. 2019;14(2):196–202.
tio (TCR). An index to evaluate tolerance to heat. Temperature. 100. Kent GL. Effect of dietary nitrate supplementation on thermo-
2014;1(2):101–106. regulatory and cardiovascular responses to submaximal cycling
77. Periard JD, Travers GJS, Racinais S, et al. Cardiovascular adapta- in the heat. Eur J Appl Physiol. 2018;118:657–668.
tions supporting human exercise-heat acclimation. Auton Neuro- 101. Kuennen M, Jansen L, Gillum T, et al. Dietary nitrate reduces
sci. 2016. the O2 cost of desert marching but elevates the rise in core tem-
78. Wenger CB. Human heat acclimatization. In Human Preformance perature. Eur J Appl Physiol. 2015;115:2557–2569.
Physiology and Environmental Medicine at Terrestrial Extremes. 102. Zuhl M, Dokladny K, Mermier C, et al. The effects of acute
Edited by Pandolf KB, Sawka MN, Gonzalez RR. Indianapolis: oral glutamine supplementation on exercise-induced gastroin-
Benchmark Press; 1988:153–197. testinal permeability and heat shoch protien expression in per-
79. Daanen HAM, Racinais S, Periard JD. Heat acclimation decay pheral blood mononuclear cells. Cell Stress Chaperones. 2015;
and reinduction: a ststematic review and meta-analysis. Sports 20:85–93.
Med. 2018;48:409–430. 103. Kuennen M, Gillum T, Dokladny K, et al. Thermotolerance and
80. Budd GM. Wet-blub glob temperature (WGBT)—its history and heat acclimation may share a common mechanism in humans.
limitations. J Sci Med Sports. 2008;11(1):20–32. Am J Physiol Regul Integr Comp Physiol. 2011;301:R524–R533.
81. Stauber R. What should you know when you purchase a WBGT 104. Szymanski MC, Gillum TL, Gould LM, et al. Short-term di-
instrument? Occup Health Safety. 2016;85(9):40–41. etary curcumin supplementation reduces gastrointestinal barrier
82. Montain SJ, Latzka WA, Sawka MN. Fluid replacement rec- damage and physiological strain response during exertional heat
ommendations for training in hot weather. Mil Med. 1999;164: stress. J Appl Physiol. 2018;124:330–340.
502–508. 105. Maron MB, Wagner JA, Horvath SM. Thermoregulatory re-
83. O’Brien KK, Montain SJ, Corr WP, et al. Hyponatremia associ- sponse during competitive marathon running. J Appl Physiol.
ated with overhydration in U.S. Army trainees. Mil Med. 2001; 1977;42(6):909–914.
166:405–410. 106. Robinson S, Wiley SL, Boudurant LG, et al. Temperature regula-
84. Update: exertional hyponatremia, active component, U.S. Armed tion of men following heatstroke. Isr J Med Sci. 1976;12:786–795.
Forces, 2002–2017 MSMR. 2018;25(4):18–22.

116 | JSOM Volume 19, Edition 2 / Summer 2019

113 114 115 116 117 118 119 120 121 122 123