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Metabolic Responses to the Yukon Arctic Ultra: Longest and Coldest in the World

TitleMetabolic Responses to the Yukon Arctic Ultra: Longest and Coldest in the World
Publication TypeJournal Article
Year of Publication2016
AuthorsCoker, RH, Weaver, AN, Coker, MS, Murphy, CJ, Gunga, H-C, Steinach, M
JournalMedicine and Science in Sports and Exercise
Volume49
Issue2
Pagination357-362
Date PublishedAugust 2016
Abstract

PURPOSE:

The Yukon Arctic Ultra is considered the longest and coldest ultraendurance event in the world. Cold exposure and exercise has been reported to influence circulating levels of myokines, adipokines, and hepatokines that may influence considerable alterations in the regulation of metabolism. The purpose of the study was to evaluate the influence of the Yukon Arctic Ultra (430-mile event) on potential activators of brown fat, metabolites, and body composition in healthy individuals.

METHODS:

Eight male and female participants (mean ± SEM: age, 44 ± 3 yr; body mass index, 23.4 ± 0.9) were recruited for participation. Blood samples were collected at pre-event, mid-event, and post-event checkpoints.

RESULTS:

The temperature during the event ranged from -45°C to -8°C. Because of these extremely challenging conditions, 50% of the participants withdrew from competition by the 300-mile mark, and those that surpassed 300 miles lost a significant (P = 0.002; P = 0.01) amount of body weight (76 ± 5 kg to 73 ± 4 kg) and fat mass (13 ± 1 kg to 12 ± 3 kg), respectively. With respect to serum irisin, there was a trend (P = 0.06) toward significance from pre-event (1033 ± 88 ng·mL), mid-event (1265 ± 23 ng·mL) to post-event (1289 ± 24 ng·mL). Serum meteorin-like and fibroblast growth factor-21 remained stable throughout the event. There were no changes in creatinine, acetoacetate, acetate, and valine. Serum lactate decreased (P = 0.04) during the event.

CONCLUSIONS:

The influence of cold exposure and extreme physical exertion may promote substantial increases in serum irisin, and specific alterations in substrate metabolism that largely preserve skeletal muscle and physiological resilience.

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