Tony G. Waldrop

Unanesthetized decorticate cats walked or ran normally on a treadmill either spontaneously or during electrical stimulation of the subthalamic "locomotor" region. The respiratory response usually preceded the locomotor response and increased in proportion to locomotor activity despite control or ablation of respiratory feedback mechanisms. Respiration increased similarly in paralyzed animals during fictive locomotion despite the absence of muscular contraction or movement. Hypothalamic command signals are thus primarily responsible for the proportional driving of locomotion and respiration during exercise.

Static contraction of the hindlimb muscles of cats reflexly increases cardiovascular function, an effect that is potentiated by occlusion of the arterial supply to the working muscles. Although group III and IV afferents are known to be stimulated by and to cause the reflex cardiovascular responses to static muscular contraction, little is known about the responses of these afferents to static contraction when the arterial supply to a working muscle is occluded. We therefore recorded the impulse activity of 24 group III afferents and 30 group IV afferents with endings in the triceps surae while we statically contracted this muscle group, both when the abdominal aorta was occluded and when it was patent. A chi 2 analysis revealed that ischemia increased the responses to static contractions of a significantly higher percentage of group IV afferents than group III afferents (46.7% vs. 12.5%, respectively; P less than 0.02). In addition, two patterns of responses to ischemic contraction were observed. The first pattern was displayed by afferents (n = 10) that were stimulated by nonischemic contraction but were stimulated more by ischemic contraction. The second pattern was displayed by afferents (n = 7) that were not stimulated by nonischemic contraction but were stimulated by ischemic contraction. We conclude that afferents displaying both patterns are likely to contribute to the reflex cardiovascular responses to ischemic contraction.

Abstract The sections in this article are: Respiration Circulation Central Command Mechanisms Central Drive of Locomotion Locomotor Pattern Generator Supraspinal Locomotor Sites Central Command Control of Respiration and Circulation in Animals Cerebral Cortex Hypothalamic Locomotor Region Mesencephalic Locomotor Region Amygdala Awake, Exercising Animal Studies Short‐Term Potentiation Respiration Central Command Control of Respiration and Circulation in Humans Respiration Circulation Interactions Between Central Command and Peripheral Feedback Interaction of Central Command with Cardiorespiratory Reflexes Baroreceptor Reflex Hering‐Breuer Reflex Chemoreceptor Reflexes Conclusions