TY - JOUR
T1 - Trade-Off Between Maximal Power Output and Fatigue Resistance of the Knee Extensors for Older Men
AU - Akagi, Ryota
AU - Nomura, Yuta
AU - Kawashima, Chiho
AU - Ito, Mari
AU - Oba, Kosuke
AU - Tsuchiya, Yuma
AU - Power, Geoffrey A.
AU - Hirata, Kosuke
N1 - Funding Information:
This study was partly supported by JSPS KAKENHI Grant Number JP17KK0174 (Fund for the Promotion of Joint International Research, Fostering Joint International Research).
Publisher Copyright:
© 2022 The Authors. Published by Human Kinetics, Inc.
PY - 2022/12
Y1 - 2022/12
N2 - This study investigated associations of fatigue resistance determined by an exercise-induced decrease in neuromuscular power with prefatigue neuromuscular strength and power of the knee extensors in 31 older men (65–88 years). A fatigue task consisted of 50 consecutive maximal effort isotonic knee extensions (resistance: 20% of prefatigue isometric maximal voluntary contraction torque) over a 70° range of motion. The average of the peak power values calculated from the 46th to 50th contractions during the fatigue task was normalized to the prefatigue peak power value, which was defined as neuromuscular fatigue resistance. Neuromuscular fatigue resistance was negatively associated with prefatigue maximal power output (r = −.530) but not with prefatigue maximal voluntary contraction torque (r = −.252). This result highlights a trade-off between prefatigue maximal power output and neuromuscular fatigue resistance, implying that an improvement in maximal power output might have a negative impact on neuromuscular fatigue resistance.
AB - This study investigated associations of fatigue resistance determined by an exercise-induced decrease in neuromuscular power with prefatigue neuromuscular strength and power of the knee extensors in 31 older men (65–88 years). A fatigue task consisted of 50 consecutive maximal effort isotonic knee extensions (resistance: 20% of prefatigue isometric maximal voluntary contraction torque) over a 70° range of motion. The average of the peak power values calculated from the 46th to 50th contractions during the fatigue task was normalized to the prefatigue peak power value, which was defined as neuromuscular fatigue resistance. Neuromuscular fatigue resistance was negatively associated with prefatigue maximal power output (r = −.530) but not with prefatigue maximal voluntary contraction torque (r = −.252). This result highlights a trade-off between prefatigue maximal power output and neuromuscular fatigue resistance, implying that an improvement in maximal power output might have a negative impact on neuromuscular fatigue resistance.
KW - interpolated twitch technique
KW - isometric contraction
KW - isotonic contraction
KW - muscle shear modulus
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U2 - 10.1123/japa.2021-0384
DO - 10.1123/japa.2021-0384
M3 - Article
C2 - 35453123
AN - SCOPUS:85143180160
SN - 1063-8652
VL - 30
SP - 1003
EP - 1013
JO - Journal of Aging and Physical Activity
JF - Journal of Aging and Physical Activity
IS - 6
ER -