The role of the prefrontal cortex in the development of muscle fatigue in Charcot-Marie-Tooth 1A patients.

This study aimed at comparing both peripheral and central mechanisms of muscle fatigue between Charcot-Marie-Tooth 1A patients and healthy individuals during a fatiguing voluntary task by simultaneous electromyographic and electroencephalographic recordings. Six Charcot-Marie-Tooth 1A patients (3 females, 40±11 years) and 6-matched healthy individuals performed four blocks of sub-maximal isometric knee extensions. At the beginning of the session and after each block, electrically-evoked maximal single-twitch, maximal voluntary contraction and surface-electromyography of the vastus lateralis muscle were measured. The movement-related-cortical potentials were averaged in early (block 1-2) and late (block 3-4) stages of fatigue. The effect of fatigue was demonstrated at peripheral level by the decline of maximal voluntary contraction, maximal twitch and surface electromyography amplitude and at central level by the larger amplitude of movement-related-cortical-potentials during late than early stage of fatiguing sub-maximal contractions. Charcot-Marie-Tooth 1A patients showed lower motor cortex activity during motor planning, with earlier onset and larger prefrontal cortex activity during the late stage of the fatiguing task than healthy controls. These data demonstrate the key role of the prefrontal cortex in the development of fatigue in Charcot-Marie-Tooth 1A patients, which may be activated as a compensatory mechanism for the low motor cortex activation, thus reflecting high awareness of movement complexity.

Hemodynamic responses to metaboreflex activation: insights from spinal cord-injured humans.

This investigation was conducted to study the hemodynamic consequences of spinal cord injury (SCI) during post-exercise muscle metaboreflex activation in SCI subjects. The hemodynamic response to metaboreflex recruitment was assessed in ten SCI patients and nine healthy controls (CTL) by means of impedance cardiography. The main results were (1) the metaboreflex-induced blood pressure rise was blunted in SCI subjects compared with normals, (2) the CTL group achieved the blood pressure response via cardiac output increase, while the SCI subjects could not use this mechanism, (3) the CTL group was able to enhance stroke volume and ventricular filling rate in response to the metaboreflex, whereas the SCI group could not. It was concluded that in healthy individuals, the hemodynamic response to the metaboreflex is an integrated phenomenon that depends mainly on a flow-mediated mechanism, whereas in SCI individuals the reduced venous return impairs this mechanism.

Physiological responses and energy cost during a simulation of a Muay Thai boxing match.

Muay Thai is a martial art that requires complex skills and tactical excellence for success. However, the energy demand during a Muay Thai competition has never been studied. This study was devised to obtain an understanding of the physiological capacities underlying Muay Thai performance. To that end, the aerobic energy expenditure and the recruitment of anaerobic metabolism were assessed in 10 male athletes during a simulation match of Muay Thai. Subjects were studied while wearing a portable gas analyzer, which was able to provide data on oxygen uptake, carbon dioxide production, and heart rate (HR). The excess of CO2 production (CO2 excess) was also measured to obtain an index of anaerobic glycolysis. During the match, group energy expenditure was, on average (mean +/- standard error of the mean), 10.75 +/- 1.58 kcal.min-1, corresponding to 9.39 +/- 1.38 metabolic equivalents. Oxygen uptake and HRs were always above the level of the anaerobic threshold assessed in a preliminary incremental test. CO2 excess showed an abrupt increase in the first round, and reached a value of 636 +/- 66.5 mL.min-1. This parameter then gradually decreased throughout the simulation match. These data suggest that Muay Thai is a physically demanding activity with great involvement of both the aerobic metabolism and anaerobic glycolysis. In particular, it appears that, after an initial burst of anaerobic glycolysis, there was a progressive increase in the aerobic energy supply. Thus, training protocols should include exercises that train both aerobic and anaerobic energetic pathways.

Estimating stroke volume from oxygen pulse during exercise.

This investigation aimed at verifying whether it was possible to reliably assess stroke volume (SV) during exercise from oxygen pulse (OP) and from a model of arterio-venous oxygen difference (a-vO(2)D) estimation. The model was tested in 15 amateur male cyclists performing an exercise test on a cycle-ergometer consisting of a linear increase of workload up to exhaustion. Starting from the analysis of previous published data, we constructed a model of a-vO(2)D estimation (a-vO(2)D(est)) which predicted that the a-vO(2)D at rest was 30% of the total arterial O(2) content (CaO(2)) and that it increased linearly during exercise reaching a value of 80% of CaO(2) at the peak workload (W(max)) of cycle exercise. Then, the SV was calculated by applying the following equation, SV = OP/a-vO(2)D(est), where the OP was assessed as the oxygen uptake/heart rate. Data calculated by our model were compared with those obtained by impedance cardiography. The main result was that the limits of agreement between the SV assessed by impedance cardiography and the SV estimated were between 22.4 and -27.9 ml (+18.8 and -24% in terms of per cent difference between the two SV measures). It was concluded that our model for estimating SV during effort may be reasonably applicable, at least in a healthy population.