Neuromuscular electrical stimulation: implications of the electrically evoked sensory volley

Bergquist, Austin J.; Clair, J. M.; Lagerquist, Olle; Mang, Cameron S.; Okuma, Yoshino; Collins, David F.

doi:10.1007/s00421-011-2087-9

Cited by 195 publications

(200 citation statements)

References 106 publications

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“…In order to maximize the spatial recruitment during NMES, thus minimizing the extent of muscle fatigue, it has been recommended to implement different expedients during a treatment session such as progressive increase in current intensity, alteration in muscle length, and displacement of active electrodes (Maffiuletti 2010). In this cluster of articles, further approaches have been proposed to alleviate, at least in part, discomfort and other possible complications associated to the electrically evoked contractions (Botter et al 2011;Bergquist et al 2011;Gobbo et al 2011). Fig.…”

Section: Nmes Physiologymentioning

confidence: 99%

“…These two logical steps should necessarily precede all evidence-based applications of NMES directed toward the improvement of neuromuscular function in vivo. Within each column, studies are grouped by topic area, with the name of the first author presented in square brackets Bergquist et al (2011) provided an overview of how peripheral (direct activation of motor axon branches) and central (reflexive recruitment of spinal motor neurons by the electrically evoked afferent volley) pathways contribute to electrically evoked contractions and suggested that some of the limitations of NMES (particularly discomfort and random recruitment) could be minimized by increasing the contribution through central pathways. In fact, motor unit recruitment through central pathways may be more orderly, less synchronous and more spatially diffuse throughout the muscle, than recruitment through purely peripheral pathways.…”

Section: Nmes Physiologymentioning

confidence: 99%

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Electrical stimulation for neuromuscular testing and training: state-of-the art and unresolved issues

et al. 2011

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Section: Nmes Physiologymentioning

confidence: 99%

Section: Nmes Physiologymentioning

confidence: 99%

Electrical stimulation for neuromuscular testing and training: state-of-the art and unresolved issues

et al. 2011

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“…The qualitative critique of various metric methods demonstrated for example, that although individual peak plots are indeed quite meaningful, their computation time is poor in relation to the other plots. Further, the extrema plots, with an average computational time, yield at best average meaningful data.In terms of experimental design, there were several avenues for optimisation, such as quantification of the exact site to provide optimal stimulation through use of a motor pen [27] and assessing whether to stimulate the femoral nerve or quadriceps directly as they differ in terms of aspects such as comfort [28]. Moreover, the lower limb and torso could be held still during the contraction process [29] to minimise the input of residual torques from other movements of the body.…”

Section: Discussionmentioning

confidence: 99%

“All talk no torque”– A novel set of metrics to quantify muscle fatigue through isometric dynamometry in Functional Electrical Stimulation (FES) muscle studies

Taylor

Fornusek

Chazal

et al. 2017

IOP Conf. Ser.: Mater. Sci. Eng.

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Abstract. Functional Electrical Stimulation (FES) activates nerves and muscles that have been ravished and rendered paralysed by disease. As such, it is advantageous to study joint torques that arise due to electrical stimulation of muscle, to measure fatigue in an indirect, minimallyinvasive way. Dynamometry is one way in which this can be achieved. In this paper, torque data is presented from an FES experiment on quadriceps, using isometric dynamometry to measure torque. A library of fatigue metrics to quantify these data are put forward. These metrics include; start and end torque peaks, percentage changes in torque over time, and maximum and minimum torque period algorithms (MTPA 1 and 2), and associated torque-time plots. It is illustrated, by example, how this novel library of metrics can model fatigue over time. Furthermore, these methods are critiqued by a qualitative assessment and compared against one another for their utility in modelling fatigue. Linear trendlines with coefficients of correlation (R 2 ) and qualitative descriptions of data are used to achieve this. We find that although arduous, individual peak plots yield the most relevant values upon which fatigue can be assessed. Methods to calculate peaks in data have less of a utility, offset by an order of magnitude of ~10 1 in comparison with theoretically expected peak numbers. In light of this, we suggest that future methods would be well-inclined to investigate optimized form of peak analysis.

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“…Neuromuscular electrical stimulation (NMES) involves the repetitive application of pulses of stimulation over a muscle belly or nerve trunk and can restore movement and reduce muscle atrophy for people who have had a spinal cord injury or stroke (Sheffler and Chae 2007;Bergquist et al 2011). NMES activates both efferent and afferent axons, resulting in muscle contractions and the transmission of an afferent volley to the central nervous system, respectively.…”

Section: Introductionmentioning

confidence: 99%

The pulse duration of electrical stimulation influences H-reflexes but not corticospinal excitability for tibialis anterior

Hindle

Lou

Collins

2014

Can. J. Physiol. Pharmacol.

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The afferent volley generated by neuromuscular electrical stimulation (NMES) influences corticospinal (CS) excitability and frequent NMES sessions can strengthen CS pathways, resulting in long-term improvements in function. This afferent volley can be altered by manipulating NMES parameters. Presently, we manipulated one such parameter, pulse duration, during NMES over the common peroneal nerve and assessed the influence on H-reflexes and CS excitability. We hypothesized that compared with shorter pulse durations, longer pulses would (i) shift the H-reflex recruitment curve to the left, relative to the M-wave curve; and (ii) increase CS excitability more. Using 3 pulse durations (50, 200, 1000 μs), M-wave and H-reflex recruitment curves were collected and, in separate experiments, CS excitability was assessed by comparing motor evoked potentials elicited before and after 30 min of NMES. Despite finding a leftward shift in the H-reflex recruitment curve when using the 1000 μs pulse duration, consistent with a larger afferent volley for a given efferent volley, the increases in CS excitability were not influenced by pulse duration. Hence, although manipulating pulse duration can alter the relative recruitment of afferents and efferents in the common peroneal nerve, under the present experimental conditions it is ineffective for maximizing CS excitability for rehabilitation.

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Neuromuscular electrical stimulation: implications of the electrically evoked sensory volley

Cited by 195 publications

References 106 publications

Electrical stimulation for neuromuscular testing and training: state-of-the art and unresolved issues

Electrical stimulation for neuromuscular testing and training: state-of-the art and unresolved issues

“All talk no torque”– A novel set of metrics to quantify muscle fatigue through isometric dynamometry in Functional Electrical Stimulation (FES) muscle studies

The pulse duration of electrical stimulation influences H-reflexes but not corticospinal excitability for tibialis anterior

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