The Effects Of Voluntary Contraction Intensity On The Electromechanical Delay

The present study aimed to investigate the effect of isometric training on the elasticity of human tendon structures. Eight subjects completed 12 wk (4 days/wk) of isometric training that consisted of unilateral knee extension at 70% of maximal voluntary contraction (MVC) for 20 s per set (4 sets/day). Before and after training, the elongation of the tendon structures in the vastus lateralis muscle was directly measured using ultrasonography while the subjects performed ramp isometric knee extension up to MVC. The relationship between the estimated muscle force and tendon elongation ( L) was fitted to a linear regression, the slope of which was defined as stiffness of the tendon structures. The training increased significantly the volume (7.6±4.3%) and MVC torque (33.9±14.4%) of quadriceps femoris muscle. The L values at force production levels beyond 550 N were significantly shorter after training. The stiffness increased significantly from 67.5±21.3 to 106.2±33.4 N/mm. Furthermore, the training significantly increased the rate of torque development (35.8 ± 20.4%) and decreased electromechanical delay (−18.4±3.8%). Thus the present results indicate that isometric training increases the stiffness and Young's modulus of human tendon structures as well as muscle strength and size. This change in the tendon structures would be assumed to be an advantage for increasing the rate of torque development and shortening the electromechanical delay.

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Electromechanical delay measured during a voluntary contraction should be interpreted with caution

Muscle & Nerve ◽

10.1002/mus.22139 ◽

2011 ◽

Vol 44 (5) ◽

pp. 838-838 ◽

Cited By ~ 21

Author(s):

François Hug ◽

Lilian Lacourpaille ◽

Antoine Nordez

Keyword(s):

Voluntary Contraction ◽

Electromechanical Delay

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The influence of preceding activity and muscle length on voluntary and electrically evoked contractions

Applied Physiology Nutrition and Metabolism ◽

10.1139/apnm-2018-0104 ◽

2019 ◽

Vol 44 (3) ◽

pp. 301-308 ◽

Cited By ~ 1

Author(s):

Mathew I.B. Debenham ◽

Geoffrey A. Power

Keyword(s):

Protective Effect ◽

Maximal Voluntary Contraction ◽

Muscle Length ◽

Voluntary Contraction ◽

Electromechanical Delay ◽

Rate Of Torque Development ◽

Electrically Evoked Contractions ◽

Evoked Contractions ◽

Torque Development

Muscle length and preceding activity independently influence rate of torque development (RTD) and electromechanical delay (EMD), but it is unclear whether these parameters interact to optimize RTD and EMD. The purpose of this study was to determine the influence of muscle length and preceding activity on RTD and EMD during voluntary and electrically stimulated (e-stim) contractions. Participants (n = 17, males, 24 ± 3 years) performed isometric knee extensions on a dynamometer. Explosive maximal contractions were performed at 2 knee angles (35° and 100° referenced to a 0° straight leg) without preceding activity (unloaded, UNL) and with preceding activities of 20%, 40%, 60%, and 80% of maximal voluntary contraction (MVC) torque. Absolute and normalized voluntary RTD were slowed with preceding activities ≥40% MVC for long muscle lengths and all preceding activities for short muscle lengths compared with UNL (p < 0.001). Absolute and normalized e-stim RTD were slower with preceding activities ≥40% MVC compared with UNL (p < 0.001) for both muscle lengths. Normalized RTD was faster at short muscle lengths than at long muscle lengths (p < 0.001) for e-stim (∼50%) and voluntary (∼32%) UNL contractions, but this effect was not present for absolute RTD. Muscle length did not affect EMD (p > 0.05). EMD was shorter at 80% MVC compared with UNL (∼35%; p < 0.001) for both muscle lengths during voluntary but not e-stim contractions. While RTD is limited by preceding activity at both muscle lengths, long muscle lengths require greater preceding activity to limit RTD than short muscle lengths, which indicates long muscle lengths may offer a “protective effect” for RTD against preceding activity.

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Reflex Responses in Upper Limb Muscles to Cutaneous Stimuli

Canadian Journal of Neurological Sciences / Journal Canadien des Sciences Neurologiques ◽

10.1017/s0317167100048174 ◽

1993 ◽

Vol 20 (04) ◽

pp. 271-278 ◽

Cited By ~ 30

Author(s):

R. Chen

Keyword(s):

Stimulus Intensity ◽

Upper Limb ◽

Healthy Subjects ◽

Voluntary Contraction ◽

Cutaneous Reflexes ◽

Focal Lesions ◽

Normal Ranges ◽

Conduction Velocities ◽

Limb Muscles ◽

Biphasic Responses

ABSTRACT:Cutaneous reflexes in the upper limb were elicited by stimulating digital nerves and recorded by averaging rectified EMG from proximal and distal upper limb muscles during voluntary contraction. Distal muscles often showed a triphasic response: an inhibition with onset about 50 ms (Il) followed by a facilitation with onset about 60 ms (E2) followed by another inhibition with onset about 80 ms (12). Proximal muscles generally showed biphasic responses beginning with facilitation or inhibition with onset at about 40 ms. Normal ranges for the amplitude of these components were established from recordings on 22 arms of 11 healthy subjects. An attempt was made to determine the alterent fibers responsible for the various components by varying the stimulus intensity, by causing ischemic block of larger fibers and by estimating the afferent conduction velocities. The central pathways mediating these reflexes were examined by estimating central delays and by studying patients with focal lesions

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Development of a trunk motor paradigm for use in neuroimaging

Translational Neuroscience ◽

10.1515/tnsci-2020-0116 ◽

2020 ◽

Vol 11 (1) ◽

pp. 193-200

Author(s):

Elizabeth Saunders ◽

Brian C. Clark ◽

Leatha A. Clark ◽

Dustin R. Grooms

Keyword(s):

Motor Control ◽

Maximum Voluntary Contraction ◽

Voluntary Contraction ◽

Erector Spinae ◽

Head Motion ◽

Low Back ◽

Cyclic Contraction ◽

Cyclic Contractions ◽

Measurement Units ◽

Healthy Participants

AbstractThe purpose of this study was to quantify head motion between isometric erector spinae (ES) contraction strategies, paradigms, and intensities in the development of a neuroimaging protocol for the study of neural activity associated with trunk motor control in individuals with low back pain. Ten healthy participants completed two contraction strategies; (1) a supine upper spine (US) press and (2) a supine lower extremity (LE) press. Each contraction strategy was performed at electromyographic (EMG) contraction intensities of 30, 40, 50, and 60% of an individually determined maximum voluntary contraction (MVC) (±10% range for each respective intensity) with real-time, EMG biofeedback. A cyclic contraction paradigm was performed at 30% of MVC with US and LE contraction strategies. Inertial measurement units (IMUs) quantified head motion to determine the viability of each paradigm for neuroimaging. US vs LE hold contractions induced no differences in head motion. Hold contractions elicited significantly less head motion relative to cyclic contractions. Contraction intensity increased head motion in a linear fashion with 30% MVC having the least head motion and 60% the highest. The LE hold contraction strategy, below 50% MVC, was found to be the most viable trunk motor control neuroimaging paradigm.

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Insights into the combination of neuromuscular electrical stimulation and motor imagery in a training-based approach

European Journal of Applied Physiology ◽

10.1007/s00421-020-04582-4 ◽

2021 ◽

Author(s):

Amandine Bouguetoch ◽

Alain Martin ◽

Sidney Grosprêtre

Keyword(s):

Electrical Stimulation ◽

Motor Imagery ◽

Neural Plasticity ◽

Neuromuscular Electrical Stimulation ◽

Voluntary Contraction ◽

Muscle Architecture ◽

Fascicle Length ◽

Before And After ◽

V Wave ◽

And Control

Abstract Introduction Training stimuli that partially activate the neuromuscular system, such as motor imagery (MI) or neuromuscular electrical stimulation (NMES), have been previously shown as efficient tools to induce strength gains. Here the efficacy of MI, NMES or NMES + MI trainings has been compared. Methods Thirty-seven participants were enrolled in a training program of ten sessions in 2 weeks targeting plantar flexor muscles, distributed in four groups: MI, NMES, NMES + MI and control. Each group underwent forty contractions in each session, NMES + MI group doing 20 contractions of each modality. Before and after, the neuromuscular function was tested through the recording of maximal voluntary contraction (MVC), but also electrophysiological and mechanical responses associated with electrical nerve stimulation. Muscle architecture was assessed by ultrasonography. Results MVC increased by 11.3 ± 3.5% in NMES group, by 13.8 ± 5.6% in MI, while unchanged for NMES + MI and control. During MVC, a significant increase in V-wave without associated changes in superimposed H-reflex has been observed for NMES and MI, suggesting that neural adaptations occurred at supraspinal level. Rest spinal excitability was increased in the MI group while decreased in the NMES group. No change in muscle architecture (pennation angle, fascicle length) has been found in any group but muscular peak twitch and soleus maximal M-wave increased in the NMES group only. Conclusion Finally, MI and NMES seem to be efficient stimuli to improve strength, although both exhibited different and specific neural plasticity. On its side, NMES + MI combination did not provide the expected gains, suggesting that their effects are not simply cumulative, or even are competitive.

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Comparison of single and multiple joint muscle functions and neural drive of trained athletes and untrained individuals

Isokinetics and Exercise Science ◽

10.3233/ies-203225 ◽

2021 ◽

pp. 1-11

Author(s):

Kale Mehmet

Keyword(s):

Muscle Activation ◽

Time Windows ◽

Knee Extension ◽

Electromechanical Delay ◽

Neural Drive ◽

Lower Limb Muscles ◽

Explosive Force ◽

Biarticular Muscle ◽

Voluntary Contractions ◽

Maximum Voluntary Force

BACKGROUND: There is insufficient knowledge about the rate of force development (RFD) characteristics over both single and multiple joint movements and the electromechanical delay (EMD) values obtained in athletes and untrained individuals. OBJECTIVE: To compare single and multiple joint functions and the neural drive of trained athletes and untrained individuals. METHODS: Eight trained athletes and 10 untrained individuals voluntarily participated to the study. The neuromuscular performance was assessed during explosive and maximum voluntary isometric contractions during leg press and knee extension related to single and multiple joint. Explosive force and surface electromyography of eight superficial lower limb muscles were measured in five 50-ms time windows from their onset, and normalized to peak force and electromyography activity at maximum voluntary force, respectively. The EMD was determined from explosive voluntary contractions (EVC’s). RESULTS: The results showed that there were significant differences in absolute forces during knee extension maximum voluntary force and EVC’s (p< 0.01) while trained athletes achieved greater relative forces than untrained individuals of EVC at all five time points (p< 0.05). CONCLUSIONS: The differences in explosive performance between trained athletes and untrained individuals in both movements may be explained by different levels of muscle activation within groups, attributed to variation in biarticular muscle function over both activities.

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Physiologic changes of compound muscle action potentials related to voluntary contraction and muscle length in carpal tunnel syndrome

Journal of Electromyography and Kinesiology ◽

10.1016/j.jelekin.2004.09.002 ◽

2005 ◽

Vol 15 (3) ◽

pp. 275-281 ◽

Cited By ~ 13

Author(s):

Byung-Jo Kim ◽

Elaine S. Date ◽

Byung Kyu Park ◽

Bryan Y. Choi ◽

Sang-Heon Lee

Keyword(s):

Carpal Tunnel Syndrome ◽

Carpal Tunnel ◽

Action Potentials ◽

Muscle Length ◽

Voluntary Contraction ◽

Muscle Action ◽

Compound Muscle Action Potentials ◽

Tunnel Syndrome

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Assessment of muscle activity using electrical stimulation and mechanomyography: a systematic review

BioMedical Engineering OnLine ◽

10.1186/s12938-020-00840-w ◽

2021 ◽

Vol 20 (1) ◽

Author(s):

Raphael Uwamahoro ◽

Kenneth Sundaraj ◽

Indra Devi Subramaniam

Keyword(s):

Electrical Stimulation ◽

Processing Speed ◽

Muscle Activity ◽

Neuromuscular Electrical Stimulation ◽

Voluntary Contraction ◽

Electrical Signal ◽

Muscle Performance ◽

Inclusion Criteria ◽

Activity Assessment ◽

Experimental Protocols

AbstractThis research has proved that mechanomyographic (MMG) signals can be used for evaluating muscle performance. Stimulation of the lost physiological functions of a muscle using an electrical signal has been determined crucial in clinical and experimental settings in which voluntary contraction fails in stimulating specific muscles. Previous studies have already indicated that characterizing contractile properties of muscles using MMG through neuromuscular electrical stimulation (NMES) showed excellent reliability. Thus, this review highlights the use of MMG signals on evaluating skeletal muscles under electrical stimulation. In total, 336 original articles were identified from the Scopus and SpringerLink electronic databases using search keywords for studies published between 2000 and 2020, and their eligibility for inclusion in this review has been screened using various inclusion criteria. After screening, 62 studies remained for analysis, with two additional articles from the bibliography, were categorized into the following: (1) fatigue, (2) torque, (3) force, (4) stiffness, (5) electrode development, (6) reliability of MMG and NMES approaches, and (7) validation of these techniques in clinical monitoring. This review has found that MMG through NMES provides feature factors for muscle activity assessment, highlighting standardized electromyostimulation and MMG parameters from different experimental protocols. Despite the evidence of mathematical computations in quantifying MMG along with NMES, the requirement of the processing speed, and fluctuation of MMG signals influence the technique to be prone to errors. Interestingly, although this review does not focus on machine learning, there are only few studies that have adopted it as an alternative to statistical analysis in the assessment of muscle fatigue, torque, and force. The results confirm the need for further investigation on the use of sophisticated computations of features of MMG signals from electrically stimulated muscles in muscle function assessment and assistive technology such as prosthetics control.

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