Differential vulnerability of 3 rapidly conducting somatosensory pathways in the dog with vitamin B6 neuropathy

Abstract

In anesthetized dogs with chronically implanted cortical electrodes somatic sensory-evoked potentials (SEPs) were produced by electrical stimulation at neural, muscular or cutaneous sites of the contralateral hind leg. Stimulation of the tibial nerve at the calcaneus or of the short flexor muscles of the hind paw caused SEPs having characteristics following activation of rapidly conducting afferents from muscle spindles. Stimulation of the glabrous skin of the central pad resulted in SEPs arriving after a more protracted latency evidently related to activation of afferents from Merkel cells, Krause and Pacinian corpuscles known to be located at these sites. Stimulation of the hairy skin from the dorsal surface of the hindpaw produced a further type of SEP presumably resulting from activation of afferents from receptors of tylotrich hair follicles. Vitamin B6-induced neuropathy involves the selective degeneration of the largest neurons in the spinal ganglia and of associated long peripheral and central neurites performing rapid impulse transmission. In the course of vitamin B6 neuropathy the relatively slow impulse transmission following stimulation of the central pad was more severely impaired than the faster one after activation of afferents from muscle spindles or receptors from hair follicles. This allows us to conclude that in the dog afferents from the glabrous skin of the central pad conduct centrally via the dorsal columns, susceptible to vitamin B6 intoxication, while muscle and hair receptor afferents ascend in the dorsal spinocerebellar and spinocervical tract, respectively, which are vitamin B6 resistant.