We studied the distribution of the peripheral nerves innervating the distal forepaw by recording receptive fields from fascicles of the ulnar, radial, and median nerves and compared this result with the peripheral nerve representation in primary somatosensory (SI) cortex of cat. Our findings suggest that SI cortex receives input, in large part, from multiple peripheral nerves even when those nerves do not show a strong overlapping pattern in the periphery. This overlap pattern observed in SI cortex may be responsible, in part, for the immediate reorganization which is known to follow peripheral nerve deafferentation.
The ventroposterior region of the thalamus of mongrel cats was searched to locate zones activated by somatic stimuli. By using stimuli that selectively excited Pacinian corpuscles, areas activated by this class of afferent fibers were differentiated from regions activated by other classes of cutaneous mechanoreceptors. The results showed that Pacinian inputs excite neurons in the ventroposterior inferior nucleus (VPI) of the thalamus, whereas other more dorsal zones within the ventroposterior thalamus receive inputs from other mechanoreceptor classes. This definition of the VPI tended to be larger and to extend further lateral than some published descriptions. Horseradish peroxidase (HRP) was injected into ventroposterior zones shown by electrophysiological recordings to receive inputs from Pacinian afferents. Subsequently, labeled cell bodies were observed in the caudal poles of the dorsal column nuclei, a region previously shown to be activated by Pacinian afferents. Very few labeled cells were found in the central region of these nuclei, a region previously shown to be activated by other classes of cutaneous mechanoreceptors. Electrophysiological recordings were used to locate a small portion of the second somatosensory cortex driven by Pacinian stimuli. When HRP was injected into this region cell bodies in the VPI and the lateral part of the posterior group were labeled, but few or no labeled cells were found in ventroposterior lateral nucleus. We hypothesize that the VPI receives Pacinian information from a cytoarchitecturally distinct region in the caudal poles of the dorsal column nuclei. Further, we suggest that a major cortical target for the VPI is a subdivision of the second somatosensory cortex. These studies do not exclude the possibility that Pacinian inputs have other thalamic and cortical targets.
1. Two-hundred thirty-three single neurons were isolated and studied in somatosensory cortex of cats anesthetized with pentobarbital sodium or urethane. Two-hundred and three were studied during iontophoretic administration of acetylcholine (ACh), 173 during administration of glutamate, and 24 during administration of atropine. 2. Fifty-six percent of the 218 neurons tested responded to somatic stimuli. Another 21% did so during glutamate administration. In 11 cases ACh iontophoresis uncovered a receptive field in a previously unresponsive cell. 3. Forty-six percent of the 160 cells tested responded to thalamic stimulation. Another 17% did so in the presence of glutamate, but 19 cells responded to neither cutaneous nor thalamic stimuli. 4. Sixteen percent of the 203 cells tested were overtly excited by ACh and the responses to somatic stimulation of 29% were modulated by administration of ACh. Cells displaying overt excitation and/or modulation of responses were said to be cholinoceptive and made up 39% of the sample. These cells were located in all cortical layers. 5. Cholinoceptive neurons were more likely than noncholinoceptive cells to be driven by thalamic stimulation. 6. The changes observed during ACh administration tended to be facilitatory: an enhanced responsiveness to somatic stimuli, an increased firing rate, or an increased receptive-field size. However, in 10 of the 203 cases tested one or more of these variables decreased. 7. The enhanced responsiveness during ACh administration was a robust phenomenon; responses were often increased by as much as 200% and the discharge pattern was altered so that bursts of impulses following stimulation were more common. 8. ACh tended to enhance one attribute of a cell selectively rather than to act as a general excitant. 9. ACh is a powerful neuromodulatory agent in somatosensory cortex that, when released in specific behavioral states, should enhance the responsiveness of cortical neurons.
Abstract: The organization of the primary somatosensory cortex innervated by the ulnar nerve was studied before and immediately after ulnar nerve transection in 11 cats electrophysiologically mapped under Nembutal or Ketamine anesthesia. The cortex was reexamined a second time beginning 42 hr after nerve transection in four cats anesthetized with Nembutal. One additional sham-operated control was also mapped. The region of cortex formerly served by the ulnar nerve remained largely unresponsive to somatic stimulation independent of the type of anesthetic used during recording. Nonetheless, animals anesthetized with Ketamine had more new responsive sites in deafferented cortex following nerve cut than cats anesthetized with Nembutal. New responses, when observed, were evoked by stimulation of a region of skin adjacent to the region served by the ulnar nerve. These findings suggest that the immediate response to deafferentation of somatosensory cortex is a limited acquisition of novel responses restricted to a region immediately adjacent to cortex containing normal afferent input.
