Hz with a progressive decline at higher frequencies. Above 400 Hz, impulse activity occurred almost randomly throughout the vibratory stimulus cycle and therefore carried little further signal of vibratory frequency. The decline, with increasing frequency, in the ability of cuneate neurones to signal information about vibratory frequency parallels the known subjective capacities for frequency discrimination.5. A switch-over occurred at approximately 80 Hz in the population of cuneate neurones able to provide the more reliable signal of vibratory frequency; above 80 Hz, the Pacinian neurones; below 80 Hz, the neurones receiving intradermal, rapidly adapting receptor input from the pads. P. R. DOUGLAS, D. G. FERRINGTON AND M. ROWE 6. The observed properties of cuneate neurones are compatible with a role in signalling information which could contribute to subjective tactile abilities.
1. Localized cortical cooling was employed in anesthetized cats for the rapid reversible inactivation of the distal forelimb region within the primary somatosensory cortex (SI). The aim was to examine the responsiveness of individual neurons in the second somatosensory area (SII) in association with SI inactivation to evaluate the relative importance for tactile processing of the direct thalamocortical projection to SII and the indirect projection from the thalamus to SII via an intracortical path through SI. 2. Response features were examined quantitatively before, during, and after SI inactivation for 29 SII neurons, the tactile receptive fields of which were on the glabrous or hairy skin of the distal forelimb. Controlled mechanical stimuli that consisted of l-s trains of either sinusoidal vibration or rectangular pulses were delivered to the skin by means of small circular probes (4- to 8-mm diam). 3. Twenty-three of the 29 SII neurons (80%) showed no change in response level (in impulses per second) as a result of SI inactivation. These included seven neurons activated exclusively or predominantly by Pacinian corpuscle (PC) receptors, six that received hair follicle input, four activated by convergent input from hairy and glabrous skin, and six driven by dynamically sensitive but non-PC inputs from the glabrous skin. 4. Six SII neurons (20%), also made up of different functional classes, displayed a reduction in response to cutaneous stimuli when SI was inactivated. 5. Stimulus-response relations, constructed by plotting response level in impulses per second against the amplitude of the mechanical stimulus, showed that the effect of SI inactivation on individual neurons was consistent over the whole response range. 6. The reduced response level seen in 20% of SII neurons in association with SI inactivation cannot be attributed to direct spread of cooling from SI to the forelimb area of SII, as there was no evidence for a cooling-induced prolongation in SII spike waveforms, an effect that is known to precede any cooling-induced reduction in responsiveness. 7. As SI inactivation produced a fall in spontaneous activity in the affected SII neurons, we suggest that the inactivation removes a source of background facilitatory influence that arises in SI and affects a small proportion of SII neurons. 8. Phase-locking and therefore the precision of impulse patterning were unchanged in the responses of SII neurons to vibration during SI inactivation. This was the case whether response levels of neurons were reduced or unchanged by SI inactivation.(ABSTRACT TRUNCATED AT 400 WORDS)
SUMMARY1. Responses were recorded from individual tactile afferent fibres isolated by microdissection from the median nerve of pentobarbitone-anaesthetized neonatal kittens (1-5 days post-natal age). Experiments were also conducted on adult cats to permit precise comparisons between neonatal and adult fibres.2. Neonatal fibres with receptive fields on the glabrous skin of the foot pads were classified into two broad groups, a slowly adapting class (40 %) which responded throughout a 1 see period of steady indentation and a rapidly adapting or dynamically sensitive class comprising 60 % of units. Fibres in these two groups had overlapping conduction velocities in the range 4-3 to 7-5 m/sec and were believed to be the developing Group II afferents of the adult. 3. Neonatal slowly adapting fibres qualitatively resembled their adult counterparts. They displayed graded stimulus-response relations which, over the steepest segment of the curves, had mean slopes of 15-7 impulses/100um of indentation. Plateau levels of response were often reached at amplitudes of skin indentation of < 0 5-0 7 mm.4. Dynamically sensitive fibres with receptive fields on the glabrous skin were studied using sinusoidal cutaneous vibration which in the adult enables them to be divided into two distinct classes. However, in the neonate, they formed a continuum whether criteria of sensitivity or responsiveness were used.5. In response to vibration neonatal fibres differed from adult ones according to the following quantitative indices: (i) sensitivity as measured by both absolute thresholds and thresholds for a 1:1 pattern of response, both of which were higher in the neonate than in the adult at all frequencies > 50 Hz and differed by an order of magnitude at frequencies > 200 Hz; (ii) responsiveness based on the mean impulse rate evoked at a fixed amplitude of cutaneous vibration; (iii) band width of vibratory sensitivity which in the neonate was confined to approximately 5-300 Hz whereas in the two classes of adult units it covered the range 5-800 Hz; (iv) capacity for coding information about vibration frequency. Impulse activity of neonatal fibres was less tightly phase-locked to the vibratory stimulus and showed a poorer reflection of the periodic nature of the vibratory stimulus than impulse patterns of adult units.6. The results reveal that tactile receptors and afferent fibres in the neonate are functionally immature. Their restricted coding capacities suggest that peripheral tactile sensory mechanisms impose limits on the ability of the new-born animal to derive information about its tactile environment.
3. An alternative classification of the cells was based on a k means cluster analysis of the responses to a series of mechanical stimuli. The response profiles for a given cell were normalized, and those of the s.t.t. cells in or near lamina I were analysed along with the responses of a population of s.t.t. cells, largely in laminae IV-VI, that had been described previously. S.t.t. cells in or near lamina I were distributed amongst three of the four groups of cells determined by the cluster analysis (types 2-4).4. Vibratory stimuli excited most of the w.d.r. but none of the h.t. cells tested. Best frequencies were 5-10 Hz (at 100 and 500 ,um indentations). 6. After a series of noxious heat stimuli, the thresholds for noxious heat were lowered and responses to lower-intensity noxious heat stimuli were enhanced (sensitization). However, responses to more intense stimuli were reduced (inactivation). Similar changes were seen in the responses to graded mechanical stimuli.7. It is concluded that s.t.t. cells in or near lamina I can signal noxious cutaneous stimuli but have poor coding abilities for innocuous mechanical stimuli. Some of these cells respond to innocuous thermal stimuli, but their role in thermoreception is unclear. The small receptive fields suggest that these cells could contribute to stimulus localization.
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