NARRATIVE REVIEW
Wearable and ingestible technology to evaluate and prevent exertional heat illness: A narrative review
Courtney N. Hintz MD,
Cody R. Butler DPT, PhD,
Corresponding Author
Courtney N. Hintz MD
Special Warfare Human Performance Support Group, USAF, San Antonio, Texas, USA
Correspondence
Courtney N. Hintz, Special Warfare Human Performance Support Group, USAF, 1170 Eagle Dr. Bldg 150, JBSA-Lackland, San Antonio, TX 78236, USA.
Email: [email protected]
Search for more papers by this authorCody R. Butler DPT, PhD
Special Warfare Human Performance Support Group, USAF, San Antonio, Texas, USA
Search for more papers by this authorCourtney N. Hintz MD,
Cody R. Butler DPT, PhD,
Corresponding Author
Courtney N. Hintz MD
Special Warfare Human Performance Support Group, USAF, San Antonio, Texas, USA
Correspondence
Courtney N. Hintz, Special Warfare Human Performance Support Group, USAF, 1170 Eagle Dr. Bldg 150, JBSA-Lackland, San Antonio, TX 78236, USA.
Email: [email protected]
Search for more papers by this authorCody R. Butler DPT, PhD
Special Warfare Human Performance Support Group, USAF, San Antonio, Texas, USA
Search for more papers by this authorFirst published: 19 March 2024
The views expressed are those of the authors and do not reflect the official policy or position of the US Air Force, Department of Defense or the US Government.
Abstract
Exertional heat illness remains a constant threat to the athlete, military service member, and laborer. Recent increases in the number and intensity of environmental heat waves places these populations at an ever increasing risk and can be deadly if not recognized and treated rapidly. For this reason, it is extremely important for medical providers to guide athletes, service members, and laborers in the implementation of awareness, education, and measures to reduce or mitigate the risk of exertional heat illness. Within the past 2 decades, a variety of wearable technology options have become commercially available to track an estimation of core temperature, yet questions continue to emerge as to its use, effectiveness, and practicality in athletics, the military, and the workforce. There is a paucity of data on the accuracy of many of these newer devices in the setting of true heat stroke physiology, and it is important to avoid overreliance on new wearable technology. Further research and improvement of this technology are critical to identify accuracy in the diagnosis and prevention of EHI.
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