Spinal cholinergic inhibition of the pressor response to skeletal muscle activation

Spinal cholinergic inhibition of the pressor response to muscle activation is mediated by muscarinic, but not nicotinic, receptors

This study examined the influence of spinal muscarinic and nicotinic receptors on the cardiovascular adjustments to skeletal muscle activation in anesthetized cats. Microdialyzing into the L(7) dorsal horn increasing doses of the muscarinic receptor agonist bethanechol, but not the nicotinic receptor antagonist mecamylamine, reduced increases in mean arterial pressure (MAP) and heart rate (HR) during hindlimb contraction or passive stretch. Atropine administration accentuated the cardiovascular responses during contraction, but not during passive stretch. These data indicate that muscarinic, but not nicotinic, receptors at the dorsal horn level blunt the pressor response to muscle activity. Further, the data suggest that the two neural pathways involved in muscle contraction or stretch are anatomically distinct.

Spinal modulation of the muscle pressor reflex by nitric oxide and acetylcholine

Static contraction of skeletal muscle activates the sympathetic nervous system, which in turn increases cardiovascular function. These changes are mediated, in part, by a reflex arising from the contracting muscle. This reflex is termed the exercise pressor reflex or, more simply, the muscle pressor reflex (MPR). Over the past few years, studies have been performed investigating the sensory processing that occurs in the dorsal horn of the spinal cord as it pertains to the MPR. Several putative neurotransmitters and receptors have been implicated in mediating the MPR at the level of the dorsal horn. In addition, several receptor systems have been shown to modulate the MPR at the dorsal horn. We have recently performed studies investigating the potential modulatory role of dorsal horn nitric oxide (NO) and acetylcholine (ACH) on the MPR. Along these lines, our experiments suggest that NO enhances the excitability of dorsal horn cells receiving input from muscle afferent neurons, while ACH decreases the MPR when its concentration in the dorsal horn is elevated. The purpose of this manuscript is to review recently published findings from our laboratory and apply this information in an effort to better understand the integration of sensory input that occurs in the dorsal horn as it pertains to cardiovascular regulation. This review is also designed to stimulate questions as to how these two neurochemicals exert their actions and whether or not they represent or can represent important physiological mechanisms involved in regulating the dorsal horn integration of the MPR.