ABSTRACT
An increase in the instantaneous pulmonary flow and a decrease in the respiratory frequency has been found in man as a consequence of isometric contraction of either flexor or extensor muscles of the elbow. The delay of 200 to 900msec between the onset of the muscle contraction and the beginning of the flow increment suggests that the respiratory system increases its activity due to the proprioreceptor activation. As there is no significant difference in the results obtained during flexor or extensor contraction, the contribution of the two different receptor groups appears to be the same.
Subject(s)
Isometric Contraction , Muscle Contraction , Physical Exertion , Respiration , Adult , Arm , Humans , Male , Respiratory Function TestsABSTRACT
Cyclic passive movements of the right arm at 1Hz induce an increase in pulmonary ventilation in man. This results from an increase in frequency of the respiratory cycles, mainly due to a shortening of the expiratory phase, and from an increase of the instantaneous flow. The delay between the beginning of the arm movements and the onset of the increase in flow is about 450msec.
Subject(s)
Respiration , Adult , Arm , Humans , Movement , Muscles/physiology , Posture , Respiratory Function Tests , RestABSTRACT
Passive leg movements induced in man at a frequency of 1 Hz by an electric cycle increase pulmonary ventilation after a delay of 200-400 msec. No chemical stimuli can account for this effect since a longer delay of 1 to 5 respiratory acts (7) is required for them to drive the respiratory system. Consequently the hypothesis is made that a neural mechanism, put into action by the moving legs, provides the adequate stimuli.
Subject(s)
Leg/physiology , Movement , Oxygen Consumption , Adult , Electric Stimulation , Humans , Respiratory Function TestsABSTRACT
Experiments were carried out on cats to re-examine the respiratory effects of the stimulation of the large afferent fibers originating in the receptors of the hindlimb muscles. During the contraction of the triceps surae induced by stimulating the ventral roots, pulmonary ventilation increased due to an increase in tidal volume and, usually, in respiratory frequency. An increase in ventilation occurred also during stimulation at group I strength of the central end of the previously cut nerves to the triceps surae (LGS + MG) and to the posterior biceps plus the semitendinosus (PBST) muscles. Appreciable increase in ventilation was seen for stimuli near threshold for group I (Ia + Ib) afferent fibers of the LGS + MG nerves, while stimuli at group Ib strength were needed to produce the same effects when using the PBST nerves. It is concluded that group Ib fibers afferent from muscle receptors play a role in the reflex control of respiration.
Subject(s)
Muscles/innervation , Respiration , Afferent Pathways/physiology , Animals , Cats , Electric Stimulation , Hindlimb , Isometric Contraction , Mechanoreceptors/physiology , Muscle Spindles/physiology , Muscles/physiology , Nerve Fibers/physiologyABSTRACT
Brief contraction of arm muscles affects respiratory ventilation either by increasing respiratory frequency or by increasing the instantaneous flow. Both these changes occur at a time subsequent to muscle contraction and can be attributed to a reflex mechanism originating from the muscles.
Subject(s)
Muscle Contraction , Muscles/physiology , Respiration , Adult , Arm , Humans , Physical Exertion , Respiratory Function TestsABSTRACT
Increments in pulmonary ventilation were shown to occur in anaesthetized cats during long-lasting stimulation of a peripherally cut extensor muscle nerve at maximal intensity for group I afferent fibers. However, these increments tended to gradually adapt to a lower value when stimuli were delivered at high frequency and constant rate whereas a tendency to potentiation, up to a steady state, occurred when stimulation was intermittent. End-tidal PCO2 initially decreased with a tendency to adaptation in the case of continuous stimulation, and decreased progressively in the case of intermittent stimulation. It is concluded that the nervous mechanisms producing hyperpnoea exhibit fatigue during their constant excitation while their effects sum up during intermittent stimulation.