Influence of Fatigue on Hand Muscle Coordination and EMG-EMG Coherence During Three-Digit Grasping

Fingertip force control requires fine coordination of multiple hand muscles within and across the digits. While the modulation of neural drive to hand muscles as a function of force has been extensively studied, much less is known about the effects of fatigue on the coordination of simultaneously active hand muscles. We asked eight subjects to perform a fatiguing contraction by gripping a manipulandum with thumb, index, and middle fingers while matching an isometric target force (40% maximal voluntary force) for as long as possible. The coordination of 12 hand muscles was quantified as electromyographic (EMG) muscle activation pattern (MAP) vector and EMG-EMG coherence. We hypothesized that muscle fatigue would cause uniform changes in EMG amplitude across all muscles and an increase in EMG-EMG coherence in the higher frequency bands but with an invariant heterogeneous distribution across muscles. Muscle fatigue caused a 12.5% drop in the maximum voluntary contraction force ( P < 0.05) at task failure and an increase in the SD of force ( P < 0.01). Although EMG amplitude of all muscles increased during the fatiguing contraction ( P < 0.001), the MAP vector orientation did not change, indicating that a similar muscle coordination pattern was used throughout the fatiguing contraction. Last, EMG-EMG coherence (0–35 Hz) was significantly greater at the end than at the beginning of the fatiguing contraction ( P < 0.01) but was heterogeneously distributed across hand muscles. These findings suggest that similar mechanisms are involved for modulating and sustaining digit forces in nonfatiguing and fatiguing contractions, respectively.

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Neural and metabolic mechanisms of excessive muscle fatigue in maintenance hemodialysis patients

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.00187.2005 ◽

2005 ◽

Vol 289 (3) ◽

pp. R805-R813 ◽

Cited By ~ 51

Author(s):

Kirsten L. Johansen ◽

Julie Doyle ◽

Giorgos K. Sakkas ◽

Jane A. Kent-Braun

Keyword(s):

Muscle Fatigue ◽

Muscle Activation ◽

Voluntary Contraction ◽

Voluntary Activation ◽

Maintenance Hemodialysis ◽

Dialysis Patients ◽

Metabolic Disturbances ◽

Oxidative Potential ◽

Central Activation ◽

Peripheral Activation

Dialysis patients have severe exercise limitations related to metabolic disturbances, but muscle fatigue has not been well studied in this population. We investigated the magnitude and mechanisms of fatigue of the ankle dorsiflexor muscles in patients on maintenance hemodialysis. Thirty-three dialysis patients and twelve healthy control subjects performed incremental isometric dorsiflexion exercise, beginning at 10% of their maximal voluntary contraction (MVC) and increasing by 10% every 2 min. Muscle fatigue (fall of MVC), completeness of voluntary activation, and metabolic responses to exercise were measured. Before exercise, dialysis subjects exhibited reduced strength and impaired peripheral activation (lower compound muscle activation potential amplitude) but no metabolic perturbation. During exercise, dialysis subjects demonstrated threefold greater fatigue than controls with evidence of central activation failure but no change in peripheral activation. All metabolic parameters were significantly more perturbed at end exercise in dialysis subjects than in controls, including lower phosphocreatine (PCr) and pH, and higher Pi, Pi/PCr, and H2PO4−. Oxidative potential was markedly lower in patients than in controls [62.5 (SD 27.2) vs. 134.6 (SD 31.7), P < 0.0001]. Muscle fatigue was negatively correlated with oxidative potential among dialysis subjects ( r = −0.52, P = 0.04) but not controls. Changes in central activation ratio were also correlated with muscle fatigue in the dialysis subjects ( r = 0.59, P = 0.001) but not the controls. This study provides new information regarding the excessive muscular fatigue of dialysis patients and demonstrates that the mechanisms of this fatigue include both intramuscular energy metabolism and central activation failure.

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The strength of the corticospinal coherence depends on the predictability of modulated isometric forces

Journal of Neurophysiology ◽

10.1152/jn.00187.2012 ◽

2013 ◽

Vol 109 (6) ◽

pp. 1579-1588 ◽

Cited By ~ 4

Author(s):

Ignacio Mendez-Balbuena ◽

Jose Raul Naranjo ◽

Xi Wang ◽

Agnieska Andrykiewicz ◽

Frank Huethe ◽

...

Keyword(s):

Sensory Feedback ◽

Muscle Activation ◽

Maximum Voluntary Contraction ◽

Voluntary Contraction ◽

Visuomotor Task ◽

Gamma Range ◽

Cortical Motor ◽

Contralateral Hand ◽

Hand Motor Area ◽

Isometric Forces

Isometric compensation of predictably frequency-modulated low forces is associated with corticomuscular coherence (CMC) in beta and low gamma range. It remains unclear how the CMC is influenced by unpredictably modulated forces, which create a mismatch between expected and actual sensory feedback. We recorded electroencephalography from the contralateral hand motor area, electromyography (EMG), and the motor performance of 16 subjects during a visuomotor task in which they had to isometrically compensate target forces at 8% of the maximum voluntary contraction with their right index finger. The modulated forces were presented with predictable or unpredictable frequencies. We calculated the CMC, the cortical motor alpha-, beta-, and gamma-range spectral powers (SP), and the task-related desynchronization (TRD), as well as the EMG SP and the performance. We found that in the unpredictable condition the CMC was significantly lower and associated with lower cortical motor SP, stronger TRD, higher EMG SP, and worse performance. The findings suggest that due to the mismatch between predicted and actual sensory feedback leading to higher computational load and less stationary motor state, the unpredictable modulation of the force leads to a decrease in corticospinal synchrony, an increase in cortical and muscle activation, and a worse performance.

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Motor planning perturbation: muscle activation and reaction time

Journal of Neurophysiology ◽

10.1152/jn.00323.2018 ◽

2018 ◽

Vol 120 (4) ◽

pp. 2059-2065

Author(s):

Stefan Delmas ◽

Agostina Casamento-Moran ◽

Seoung Hoon Park ◽

Basma Yacoubi ◽

Evangelos A. Christou

Keyword(s):

Reaction Time ◽

Muscle Activity ◽

Muscle Activation ◽

Maximum Voluntary Contraction ◽

Motor Planning ◽

Reaction Time Task ◽

Voluntary Contraction ◽

Voluntary Activation ◽

Time Interval ◽

Voluntary Activity

Reaction time (RT) is the time interval between the appearance of a stimulus and initiation of a motor response. Within RT, two processes occur, selection of motor goals and motor planning. An unresolved question is whether perturbation to the motor planning component of RT slows the response and alters the voluntary activation of muscle. The purpose of this study was to determine how the modulation of muscle activity during an RT response changes with motor plan perturbation. Twenty-four young adults (20.5 ±1.1 yr, 13 women) performed 15 trials of an isometric RT task with ankle dorsiflexion using a sinusoidal anticipatory strategy (10–20% maximum voluntary contraction). We compared the processing part of the RT and modulation of muscle activity from 10 to 60 Hz of the tibialis anterior (primary agonist) when the stimulus appeared at the trough or at the peak of the sinusoidal task. We found that RT ( P = 0.003) was longer when the stimulus occurred at the peak compared with the trough. During the time of the reaction, the electromyography (EMG) power from 10 to 35 Hz was less at the peak than the trough ( P = 0.019), whereas the EMG power from 35 to 60 Hz was similar between the peak and trough ( P = 0.92). These results suggest that perturbation to motor planning lengthens the processing part of RT and alters the voluntary activation of the muscle by decreasing the relative amount of power from 10 to 35 Hz. NEW & NOTEWORTHY We aimed to determine whether perturbation to motor planning would alter the speed and muscle activity of the response. We compared trials when a stimulus appeared at the peak or trough of an oscillatory reaction time task. When the stimulus occurred at the trough, participants responded faster, with greater force, and less EMG power from 10-35 Hz. We provide evidence that motor planning perturbation slows the response and alters the voluntary activity of the muscle.

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Hand Dominance Effect During right (Accelerator) Throttle Gripping in Riding Simulation

International Journal of Engineering & Technology ◽

10.14419/ijet.v7i4.27.22502 ◽

2018 ◽

Vol 7 (4.27) ◽

pp. 141

Author(s):

Nursalbiah Nasir ◽

Asyraf Hakimi Azmi ◽

Helmi Rashid

Keyword(s):

Muscle Activation ◽

Dominance Effect ◽

Maximum Voluntary Contraction ◽

Voluntary Contraction ◽

Hand Dominance ◽

Surface Electromyogram ◽

Flexor Carpi Radialis ◽

Left Handed ◽

The Difference

This study investigated the difference in muscle activation of the muscles in right handed (RH) and left handed (LH) participants during riding of motorcycle simulator. Five participants (3 RH and 2 LH) with average age of 24.2±0.447 years old were recruited and they were requested to ride the simulator for certain period of times for three days. Two surface electromyogram (sEMG) electrodes were attached to right flexor carpi radialis (RFCR) and left flexor carpi radialis (LFCR) of the participants forearm. Electromyography (EMG) of flexor carpi radialis (FCR) are measured at both hands during the task. The results showed that muscle activation during first 5 minutes of riding task in day 1 of experiment (percentage of maximum voluntary contraction, %MVC) for RFCR in LH (non-dominant) participants was 97.4% and 87.7% in RH (dominant) participants. Therefore, this result indicates that non-dominant person needs to activate more muscle than RH person during control the accelerator throttle while riding.

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Factors Affecting Force Loss With Prolonged Stretching

Canadian Journal of Applied Physiology ◽

10.1139/h01-017 ◽

2001 ◽

Vol 26 (3) ◽

pp. 262-272 ◽

Cited By ~ 140

Author(s):

David G. Behm ◽

Duane C. Button ◽

Jeremy C. Butt

Keyword(s):

Maximal Voluntary Contraction ◽

Muscle Activation ◽

Maximum Voluntary Contraction ◽

Voluntary Contraction ◽

Control Group ◽

Tetanic Force ◽

Factors Affecting ◽

Passive Stretching ◽

Interpolated Twitch Technique ◽

Muscle Compliance

The purpose of this study was to investigate factors underlying the force loss occurring after prolonged, static, passive stretching. Subjects were tested before and 5-10 min following 20 min of static, passive stretching of the quadriceps (N = 12) or a similar period of no stretch (control, N = 6). Measurements included isometric maximal voluntary contraction (MVC) force, surface integrated electromyographic (iEMG) activity of the quadriceps and hamstrings, evoked contractile properties (twitch and tetanic force), and quadriceps inactivation as measured by the interpolated twitch technique (ITT). Following stretching, there was a significant 12% decrement in MVC with no significant changes in the control group. Muscle inactivation as measured by the ITT and iEMG increased by 2.8% and 20.2%, respectively. While twitch forces significantly decreased 11.7%, there was no change in tetanic force post-stretch. Although possible increases in muscle compliance affected twitch force, a lack of tetanic force change would suggest that post-stretch force decrements are more affected by muscle inactivation than changes in muscle elasticity. Key Words: antagonist, electromyography, maximum voluntary contraction, muscle activation, twitch, tetanus

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Muscle Activation Sequence in Flywheel Squats

International Journal of Environmental Research and Public Health ◽

10.3390/ijerph18063168 ◽

2021 ◽

Vol 18 (6) ◽

pp. 3168

Author(s):

Darjan Spudić ◽

Darjan Smajla ◽

Michael David Burnard ◽

Nejc Šarabon

Keyword(s):

Muscle Activation ◽

Coordination Pattern ◽

Muscle Coordination ◽

Kendall’S Tau ◽

Kendall's Tau ◽

Exercise Interventions ◽

Leg Muscles ◽

Sequential Rank ◽

Functional Movements

Background: Muscle coordination is important for rational and effective planning of therapeutic and exercise interventions using equipment that mimics functional movements. Our study was the first to assess muscle coordination during flywheel (FW) squats. Methods: Time-of-peak electromyographic activation order was assessed separately for 8, 4, and 3 leg muscles under four FW loads. A sequential rank agreement permutations tests (SRA) were conducted to assess activation order and Kendall’s tau was used to assess the concordance of activation order across subjects, loads and expected order of activation. Results: SRA revealed a latent muscle activation order at loads 0.05, 0.075, and 0.1, but not at 0.025 kg·m2. Kendall’s tau showed moderate-to-strong concordance between the expected (proximal-to-distal) and the observed muscle activation order only at a load 0.025 kg·m2, regardless of the number of muscles analyzed. Muscle activation order was highly concordant between loads 0.05, 0.075, and 0.1 kg·m2. Conclusions: The results show a specific role of each muscle during the FW squat that is load-dependent. While the lowest load follows the proximal-to-distal principle of muscle activation, higher loads lead to a reorganization of the underlying muscle coordination mechanisms. They require a specific and stable muscle coordination pattern that is not proximal-to-distal.

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Comparing neck extensor muscle function in asymptomatic Canadian adults and adults with tension-type headache: a cross-sectional study

BMJ Open ◽

10.1136/bmjopen-2017-020984 ◽

2019 ◽

Vol 9 (5) ◽

pp. e020984 ◽

Cited By ~ 1

Author(s):

Andrée-Anne Marchand ◽

Mariève Houle ◽

Marie-Pier Girard ◽

Marie-Ève Hébert ◽

Martin Descarreaux

Keyword(s):

Muscle Fatigue ◽

Maximum Voluntary Contraction ◽

Tension Type Headache ◽

Voluntary Contraction ◽

Extensor Muscle ◽

Control Group ◽

Physical Parameters ◽

Cross Sectional ◽

Neck Extension ◽

Type Headache

AimTo further the understanding of the pathophysiological mechanisms underlying tension-type headache (TTH) by comparing the endurance and strength of neck extensor muscles under acute muscle fatigue in participants with TTH and asymptomatic participants.MethodsWe conducted a cross-sectional analysis of neck extensor muscle performance. Asymptomatic participants and participants with TTH were recruited via social media platforms and from the Université du Québec à Trois-Rivières community and employees. A total of 44 participants with TTH and 40 asymptomatic participants took part in an isometric neck extensor endurance task performed at 60% of their maximum voluntary contraction. Inclusion criteria for the headache group were to be older than 18 years old and to fulfil the International Headache Society classification’s criteria for either frequent episodic or chronic TTH. Clinical (self-efficacy, anxiety, neck disability and kinesiophobia) and physical parameters (neck extensors maximum voluntary contraction, endurance time, muscle fatigue) as well as characteristics of headache episodes (intensity, frequency and associated disability) were collected for all participants. Surface electromyography was used to document upper trapezius, splenius capitis and sternocleidomastoids muscle activity and muscle fatigue.ResultsBoth groups displayed similar neck extensor muscle endurance capacity with a mean difference of 6.2 s (p>0.05) in favour of the control group (control=68.1±32.3; TTH=61.9±20.1). Similarly, participants in the headache group showed comparable neck extensor muscle strength (95.9±30.4 N) to the control group (111.3±38.7 N). Among participants with TTH, those scoring as severely incapacitated by headaches were the ones with higher neck-related disability (F[1,44]=10.77; p=0.002), the more frequent headache episodes (F[1,44]=6.70; p=0.01) and higher maximum headache intensity (F[1,44]=10.81; p=0.002).ConclusionA fatigue task consisting of isometric neck extension cannot efficiently differentiate participants with TTH from asymptomatic participants.

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Older adults can maximally activate the biceps brachii muscle by voluntary command

Journal of Applied Physiology ◽

10.1152/jappl.1998.84.1.284 ◽

1998 ◽

Vol 84 (1) ◽

pp. 284-291 ◽

Cited By ~ 79

Author(s):

Sophie J. De Serres ◽

Roger M. Enoka

Keyword(s):

Older Adults ◽

Muscle Activation ◽

Biceps Brachii ◽

Maximum Voluntary Contraction ◽

The Elderly ◽

Voluntary Contraction ◽

Elderly Subjects ◽

Biceps Brachii Muscle ◽

Activation Level ◽

Voluntary Command

De Serres, Sophie J., and Roger M. Enoka. Older adults can maximally activate the biceps brachii muscle by voluntary command. J. Appl. Physiol. 84(1): 284–291, 1998.—Because some of the decline in strength with age may be explained by an impairment of muscle activation, the purpose of this study was to determine the activation level achieved in biceps brachii by older adults during a maximum voluntary contraction (MVC). This capability was assessed with two superimposition techniques: one calculated the activation level that was achieved during an MVC, and the other provided an estimate of the expected MVC force based on extrapolation with submaximal forces. The activation level in biceps brachii was incomplete (<100%) for the young ( n = 16) and elderly ( n = 16) subjects, with the elderly subjects exhibiting the greater deficit. In contrast, there was no difference between the measured and expected MVC forces for either group of subjects, whether the extrapolation involved a third-order polynomial or linearization of the data. Because of the lower signal-to-noise ratio associated with the measurement of activation level and the greater number of measurements that contributed to the estimate of the expected MVC force, we conclude that the older adults were able to achieve complete activation of the biceps brachii muscle during an MVC.

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Developing a Practical Application of the Isometric Squat and Surface Electromyography

Biomechanics ◽

10.3390/biomechanics1010011 ◽

2021 ◽

Vol 1 (1) ◽

pp. 145-151

Author(s):

David Alan Phillips ◽

Angelic Rose Del Vecchio ◽

Kevin Carroll ◽

Evan Lee Matthews

Keyword(s):

Muscle Activation ◽

Relative Increase ◽

Clinical Settings ◽

Muscle Coordination ◽

Isometric Handgrip ◽

Antagonist Activity ◽

Activation Patterns ◽

Emg Amplitude ◽

Cross Education ◽

Education Effects

Electromyography (EMG) is a research tool used in gait analysis, muscle coordination evaluation, clinical evaluation and sports techniques. Electromyography can provide an insight into neural adaptations, cross education effects, bilateral contraction deficiencies, and antagonist activity in exercise-related movements. While there are clear benefits to using EMG in exercise-related professions, accessibility, cost, and difficulty interpreting the data limit its use in strength and clinical settings. We propose a practical EMG assessment using the isometric squat to identify compensatory activation patterns and report early observations. Ten healthy participants were recruited. Participants performed a 2-min isometric handgrip protocol and an isometric squat protocol. The isometric handgrip was used to identify the expected EMG amplitude response solely due to fatigue. There was a significant increase in EMG amplitude after 2 min (p < 0.05), with the relative increase of 95% CI (1.4%; 27.4%). This indicates the relative increase in EMG amplitude expected if the only influence was fatigue in the 2-min protocol. In the isometric squat protocol, we identified a number of different muscle activation compensation strategies with relative EMG amplitude increases outside of this bandwidth. One subject demonstrated a quadricep compensation strategy with a 188% increase in activation, while reducing activation in both the hamstrings and lower back by 12%. Exercise professionals can use this information to design exercise programs specifically targeting the unloaded muscles during the isometric squat.

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Passive stretching decreases muscle efficiency in balance tasks

PLoS ONE ◽

10.1371/journal.pone.0256656 ◽

2021 ◽

Vol 16 (9) ◽

pp. e0256656

Author(s):

Giuseppe Coratella ◽

Stefano Longo ◽

Susanna Rampichini ◽

Christian Doria ◽

Marta Borrelli ◽

...

Keyword(s):

Muscle Activation ◽

Balance Control ◽

Vastus Lateralis ◽

Maximum Voluntary Contraction ◽

Knee Extensor ◽

Biceps Femoris ◽

Voluntary Contraction ◽

Static Stretching ◽

Balance Tests ◽

Flexion Extension

The current study aimed to verify whether or not passive static stretching affects balance control capacity. Thirty-eight participants (19 women and 19 men) underwent a passive static stretching session, involving the knee extensor/flexor and dorsi/plantarflexor muscles, and a control session (no stretching, CTRL). Before (PRE), immediately after (POST), after 15 (POST15) and 30 min (POST30) from stretching (or rest in CTRL), balance control was evaluated under static and dynamic conditions, with open/closed eyes, and with/without somatosensory perturbation (foam under the feet). During tests, centre of pressure (CoP) sway area and perimeter and antero-posterior and medio-lateral sway mean speed were computed. Surface electromyography root mean square (sEMG RMS) was calculated from the vastus lateralis, biceps femoris, gastrocnemius medialis, and tibialis anterior muscles during MVC and during the balance tests. Hip flexion/extension and dorsi/plantarflexion range of motion (ROM), maximum voluntary contraction (MVC) and sEMG RMS during MVC were measured at the same time points. After stretching, ROM increased (≈6.5%; P<0.05), while MVC and sEMG RMS decreased (≈9% and ≈7.5%, respectively; P<0.05). Regardless of the testing condition, CoP sway area and the perimeter remained similar, while antero-posterior and medio-lateral sway mean speed decreased by ≈8% and ≈12%, respectively (P<0.05). sEMG RMS during the balance tests increased in all muscles in POST (≈7%, P<0.05). All variables recovered in POST30. No changes occurred in CTRL. Passive static stretching did not affect the overall balance control ability. However, greater muscle activation was required to maintain similar CoP sway, thus suggesting a decrease in muscle efficiency.

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