Your search keyword '"Vergès, Samuel"' showing total 2 results

1. Biometric approximation of diaphragmatic contractility during sustained hyperpnea.

Author

Kabitz HJ, Walker DJ, Schwoerer A, Schlager D, Walterspacher S, Storre JH, Roecker K, Windisch W, Vergès S, and Spengler CM

Subjects

Adult, Humans, Male, Muscle Fatigue physiology, Oxygen Consumption physiology, Respiratory Mechanics physiology, Time Factors, Young Adult, Biometry methods, Diaphragm physiology, Hyperventilation physiopathology, Muscle Contraction physiology

Abstract

Imposing load on respiratory muscles results in a loss of diaphragmatic contractility that develops early, is independent of task failure, and levels off following the initial decrease. This study assessed the progression of diaphragmatic contractility during sustained normocapnic hyperpnea and applied a biometric approximation (hypothesis: non-linear decay). Ten healthy subjects performed three consecutive hyperpnea bouts (I:6 min warm up/II:9 min/III:task failure 28.6 ± 11.5 min; mean ± SD) at maximal voluntary ventilation fractions (I:30-60%/II:70%/III:70%), followed by recovery periods (I:18 min/II:6 min/III:30 min). Twitch transdiaphragmatic pressure (TwPdi) was assessed throughout the protocol. Bouts II and III induced diaphragmatic fatigue (TwPdi baseline vs. Recovery -19 ± 17% and -30 ± 16%, both p < 0.05 RM-ANOVA) while bout I did not. During sustained hyperpnea (II/III), TwPdi followed an exponential decay (r(2) = 0.91). The reduction in diaphragmatic contractility closely follows a non-linear function with an early loss in diaphragmatic contractility during sustained hyperpnea, levels off thereafter, and is independent of task failure. Thus, reasons other than diaphragmatic fatigue are likely to be responsible for task failure during sustained hyperpnea., (Copyright © 2011 Elsevier B.V. All rights reserved.)

Published

2011

2. Electrical stimulation for testing neuromuscular function: from sport to pathology.

Author

Millet, Guillaume, Martin, Vincent, Martin, Alain, Vergès, Samuel, Millet, Guillaume Y, and Vergès, Samuel

Subjects

NEUROMUSCULAR system physiology, PATHOLOGY, ELECTRIC stimulation, MUSCLE contraction, EVOKED potentials (Electrophysiology), SARCOLEMMA, EXCITATION (Physiology), RESPIRATORY muscles, MOTOR neurons, MYONEURAL junction, NEUROMUSCULAR disease diagnosis, BIOLOGICAL models, ELECTROMYOGRAPHY, NEUROLOGIC examination, NEUROMUSCULAR diseases, SPORTS, PHYSIOLOGY

Abstract

The use of electrical stimulation (ES) can contribute to our knowledge of how our neuromuscular system can adapt to physical stress or unloading. Although it has been recently challenged, the standard technique used to explore central modifications is the twitch interpolated method which consists in superimposing single twitches or high-frequency doublets on a maximal voluntary contraction (MVC) and to compare the superimposed response to the potentiated response obtained from the relaxed muscle. Alternative methods consist in (1) superimposing a train of stimuli (central activation ratio), (2) comparing the MVC response to the force evoked by a high-frequency tetanus or (3) examining the change in maximal EMG response during voluntary contractions, if this variable is normalized to the maximal M wave, i.e. EMG response to a single stimulus. ES is less used to examine supraspinal factors but it is useful for investigating changes at the spinal level, either by using H reflexes, F waves or cervicomedullary motor-evoked potentials. Peripheral changes can be examined with ES, usually by stimulating the muscle in the relaxed state. Neuromuscular propagation of action potentials on the sarcolemma (M wave, high-frequency fatigue), excitation-contraction coupling (e.g. low-frequency fatigue) and intrinsic force (high-frequency stimulation at supramaximal intensity) can all be used to non-invasively explore muscular function with ES. As for all indirect methods, there are limitations and these are discussed in this review. Finally, (1) ES as a method to measure respiratory muscle function and (2) the comparison between electrical and magnetic stimulation will also be considered. [ABSTRACT FROM AUTHOR]

Published

2011