TY - JOUR
T1 - Brain and muscle activity during fatiguing maximum-speed knee movement
AU - Correia, Josè Pedro
AU - Domingos, Christophe
AU - Witvrouw, Erik
AU - Luís, Pedro
AU - Rosa, Agostinho
AU - Vaz, João R.
AU - Freitas, Sandro R.
N1 - Publisher Copyright:
Copyright © 2024 the American Physiological Society.
PY - 2024/1/1
Y1 - 2024/1/1
N2 - Although the underlying mechanisms behind upper limb (e.g., finger) motor slowing during movements performed at the maximum voluntary rate have been explored, the same cannot be said for the lower limb. This is especially relevant considering the lower limb’s larger joints and different functional patterns. Despite the similar motor control base, previously found differences in movement patterns and segment inertia may lead to distinct central and peripheral manifestations of fatigue in larger joint movement. Therefore, we aimed to explore these manifestations in a fatiguing knee maximum movement rate task by measuring brain and muscle activity, as well as brain-muscle coupling using corticomuscular coherence, during this task. A significant decrease in knee movement rate up to half the task duration was observed. After an early peak, brain activity showed a generalized decrease during the first half of the task, followed by a plateau, whereas knee flexor muscle activity showed a continuous decline. A similar decline was also seen in corticomuscular coherence but for both flexor and extensor muscles. The electrophysiological manifestations associated with knee motor slowing therefore showed some common and some distinct aspects compared with smaller joint tasks. Both central and peripheral manifestations of fatigue were observed; the changes seen in both EEG and electromyographic (EMG) variables suggest that multiple mechanisms were involved in exercise regulation and fatigue development. NEW & NOTEWORTHY The loss of knee movement rate with acute fatigue induced by high-speed movement is associated with both central and peripheral electrophysiological changes, such as a decrease in EEG power, increased agonist-antagonist cocontraction, and impaired brain-muscle coupling. These findings had not previously been reported for the knee joint, which shows functional and physiological differences compared with the existing findings for smaller upper limb joints.
AB - Although the underlying mechanisms behind upper limb (e.g., finger) motor slowing during movements performed at the maximum voluntary rate have been explored, the same cannot be said for the lower limb. This is especially relevant considering the lower limb’s larger joints and different functional patterns. Despite the similar motor control base, previously found differences in movement patterns and segment inertia may lead to distinct central and peripheral manifestations of fatigue in larger joint movement. Therefore, we aimed to explore these manifestations in a fatiguing knee maximum movement rate task by measuring brain and muscle activity, as well as brain-muscle coupling using corticomuscular coherence, during this task. A significant decrease in knee movement rate up to half the task duration was observed. After an early peak, brain activity showed a generalized decrease during the first half of the task, followed by a plateau, whereas knee flexor muscle activity showed a continuous decline. A similar decline was also seen in corticomuscular coherence but for both flexor and extensor muscles. The electrophysiological manifestations associated with knee motor slowing therefore showed some common and some distinct aspects compared with smaller joint tasks. Both central and peripheral manifestations of fatigue were observed; the changes seen in both EEG and electromyographic (EMG) variables suggest that multiple mechanisms were involved in exercise regulation and fatigue development. NEW & NOTEWORTHY The loss of knee movement rate with acute fatigue induced by high-speed movement is associated with both central and peripheral electrophysiological changes, such as a decrease in EEG power, increased agonist-antagonist cocontraction, and impaired brain-muscle coupling. These findings had not previously been reported for the knee joint, which shows functional and physiological differences compared with the existing findings for smaller upper limb joints.
KW - electroencephalography
KW - electromyography
KW - fatigue
KW - motor control
KW - movement rate
KW - Knee Joint/physiology
KW - Brain
KW - Humans
KW - Lower Extremity
KW - Electromyography
KW - Muscle, Skeletal/physiology
KW - Muscle Fatigue/physiology
KW - Movement/physiology
UR - http://www.scopus.com/inward/record.url?scp=85182501586&partnerID=8YFLogxK
U2 - 10.1152/japplphysiol.00145.2023
DO - 10.1152/japplphysiol.00145.2023
M3 - Article
C2 - 38059285
AN - SCOPUS:85182501586
SN - 8750-7587
VL - 136
SP - 200
EP - 212
JO - Journal of Applied Physiology
JF - Journal of Applied Physiology
IS - 1
ER -