RESUMEN
This technical note is presenting and discussing a severe limitation of the breath-by-breath (BBB) determination of pulmonary gas exchange routinely used as a surrogate for the metabolic gas exchange rate at rest and during exercise. We are presenting the view that continuous airway gas sampling at the mouth used for the determination of O2 and CO2 content is inaccurate in the range of a low-to-medium expiratory flows, due to the discrepancy between the cross section surfaces of the sampling line and the expiratory tube (mask or mouth piece). This difference results in the sampling of a mixed exhaled gas at low expiratory flow, for which any temporal relationship between the instantaneous expired CO2 and O2 signals and instantaneous expiratory flow is lost. Further analysis of this mechanism points to the difference between the exhalation (ve) and sampling (vs) gas velocities, where the ratio of ve/vs must be equal or higher than 1 to enable proper analysis of the respiratory gas concentrations during exhalation. Moreover, the above requirement is particularly crucial in monitoring the tidal concentration of the respiratory gases in experiments with small animals.
Asunto(s)
Pruebas Respiratorias , Espiración/fisiología , Intercambio Gaseoso Pulmonar/fisiología , Animales , Ejercicio Físico , Humanos , DescansoRESUMEN
This review examines the evidence that skeletal muscles can sense the status of the peripheral vascular network through group III and IV muscle afferent fibers. The anatomic and neurophysiological basis for such a mechanism is the following: 1) a significant portion of group III and IV afferent fibers have been found in the vicinity and the adventitia of the arterioles and the venules; 2) both of these groups of afferent fibers can respond to mechanical stimuli; 3) a population of group III and IV fibers stimulated during muscle contraction has been found to be inhibited to various degrees by arterial occlusion; and 4) more recently, direct evidence has been obtained showing that a part of the group IV muscle afferent fibers is stimulated by venous occlusion and by injection of vasodilatory agents. The physiological relevance of sensing local distension of the vascular network at venular level in the muscles is clearly different from that of the large veins, since the former can directly monitor the degree of tissue perfusion. The possible involvement of this sensing mechanism in respiratory control is discussed mainly in the light of the ventilatory effects of peripheral vascular occlusions during and after muscular exercise. It is proposed that this regulatory system anticipates the chemical changes that would occur in the arterial blood during increased metabolic load and attempts to minimize them by adjusting the level of ventilation to the level of muscle perfusion, thus matching the magnitudes of the peripheral and pulmonary gas exchange.