TY - JOUR
T1 - Effects of exercise on alterations in redox homeostasis in elite male and female endurance athletes using a clinical point-of-care test
AU - Lewis, Nathan
AU - Towey, Colin
AU - Bruinvels, Georgie
AU - Howatson, Glyn
AU - Pedlar, Charles
PY - 2016/6/1
Y1 - 2016/6/1
N2 - Exercise causes alterations in redox homeostasis (ARH). Measuring ARH in elite athletes may aid in the identification of training tolerance, fatigued states, and underperformance. To the best of our knowledge, no studies have examined ARH in elite male and female distance runners at sea level. The monitoring of ARH in athletes is hindered by a lack of reliable and repeatable in-the-field testing tools and by the rapid turnaround of results. We examined the effects of various exercise intensities on ARH in healthy (non-over-reached) elite male and female endurance athletes using clinical point-of-care (POC) redox tests, referred to as the free oxygen radical test (FORT) (pro-oxidant) and the free oxygen radical defence (FORD) (antioxidant). Elite male and female endurance athletes (n = 22) completed a discontinuous incremental treadmill protocol at submaximal running speeds and a test to exhaustion. Redox measures were analyzed via blood sampling at rest, warm-up, submaximal exercise, exhaustion, and recovery. FORD was elevated above rest after submaximal and maximal exercise, and recovery (p <0.05, d = 0.87–1.55), with only maximal exercise and recovery increasing FORT (p <0.05, d = 0.23–0.32). Overall, a decrease in oxidative stress in response to submaximal and maximal exercise was evident (p <0.05, d = 0.46). There were no gender differences for ARH (p > 0.05). The velocity at lactate threshold (vLT) correlated with the FORD response at rest, maximal exercise, and recovery (p <0.05). Using the clinical POC redox test, an absence of oxidative stress after exhaustive exercise is evident in the nonfatigued elite endurance athlete. The blood antioxidant response (FORD) to exercise appears to be related to a key marker of aerobic fitness: vLT.
AB - Exercise causes alterations in redox homeostasis (ARH). Measuring ARH in elite athletes may aid in the identification of training tolerance, fatigued states, and underperformance. To the best of our knowledge, no studies have examined ARH in elite male and female distance runners at sea level. The monitoring of ARH in athletes is hindered by a lack of reliable and repeatable in-the-field testing tools and by the rapid turnaround of results. We examined the effects of various exercise intensities on ARH in healthy (non-over-reached) elite male and female endurance athletes using clinical point-of-care (POC) redox tests, referred to as the free oxygen radical test (FORT) (pro-oxidant) and the free oxygen radical defence (FORD) (antioxidant). Elite male and female endurance athletes (n = 22) completed a discontinuous incremental treadmill protocol at submaximal running speeds and a test to exhaustion. Redox measures were analyzed via blood sampling at rest, warm-up, submaximal exercise, exhaustion, and recovery. FORD was elevated above rest after submaximal and maximal exercise, and recovery (p <0.05, d = 0.87–1.55), with only maximal exercise and recovery increasing FORT (p <0.05, d = 0.23–0.32). Overall, a decrease in oxidative stress in response to submaximal and maximal exercise was evident (p <0.05, d = 0.46). There were no gender differences for ARH (p > 0.05). The velocity at lactate threshold (vLT) correlated with the FORD response at rest, maximal exercise, and recovery (p <0.05). Using the clinical POC redox test, an absence of oxidative stress after exhaustive exercise is evident in the nonfatigued elite endurance athlete. The blood antioxidant response (FORD) to exercise appears to be related to a key marker of aerobic fitness: vLT.
KW - oxidative stress
KW - monitoring
KW - biomarkers
KW - antioxidant
KW - fatigue
U2 - 10.1139/apnm-2016-0208
DO - 10.1139/apnm-2016-0208
M3 - Article
SN - 1066-7814
SN - 1543-2718
SN - 1715-5312
SN - 1715-5320
VL - 41
SP - 1026
EP - 1032
JO - Applied Physiology, Nutrition, and Metabolism
JF - Applied Physiology, Nutrition, and Metabolism
IS - 10
ER -