Why Does Exercise Terminate At The Maximal Lactate Steady State Intensity?

Bertrand Baron ^1*, Timothy D Noakes ², Jeanne Dekerle ³, Farouck Moullan ¹, Sophie Robin ⁴, Régis Matran ⁴ and Patrick Pelayo ³

¹ Centre Universitaire de Recherches en Activités Physiques et Sportives, Reunion
² MRC/UCT Research Unit for Exercise Science and Sports Medicine, South Africa
³ Laboratoire d'Etudes de la Moticité Humaine, France
⁴ Service des Explorations Fonctionnelles Respiratoires, France

^* To whom correspondence should be addressed. E-mail: bertrand.baron{at}univ-reunion.fr.

Accepted 20 November 2007

Abstract

Objective: The purpose of this study was to measure physiological responses during exercise performed until exhaustion at the exercise intensity corresponding to the maximal lactate steady state (MLSS) in order to determine why subjects stopped. Methods: Eleven male trained subjects performed a test at MLSS until exhaustion on a cycle ergometer. Results: Time to exhaustion was 55.0 ± 8.5 min. No variation was observed between the 10th and the last min for arterial pyruvate, bicarbonate, and haemoglobin concentrations, redox state, arterial oxygen pressure, arterial oxygen saturation, osmolality, hematocrit, oxygen uptake, carbon dioxide output, and gas exchange ratio (p>0.05). Arterial lactate concentration and arterial carbon dioxide pressure decreased significantly whereas pH, base excess and the Ratings of Perceived Exertion (RPE) increased significantly (p<0.05). Although respiratory rate, minute ventilation and heart rate increased significantly until exhaustion (p<0.05), values at termination of the MLSS test were significantly lower than values measured during a maximal exercise test (p<0.05). Blood ammonia concentrations rose progressively during the MLSS test. However there is no known mechanism by which this change could cause peripheral fatigue. Conclusions: Exercise termination was not associated with evidence of failure in any physiological system during prolonged exercise performed at MLSS. Thus the biological mechanisms of exercise termination at MLSS were compatible with an integrative homoeostatic control of peripheral physiological systems during exercise. Key Words: Physiological responses, Homeostatic control, Fatigue.

Key Words: FATIGUE, HOMOEOSTATIC CONTROL, PHYSIOLOGICAL RESPONSES

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