The central consequences of the application of capsaicin to one peripheral nerve in adult rat

This paper reviews the central consequences of local application of capsaicin to one nerve in adult animals. 1) Marked chemical changes occur in the central terminals of C fibres. These include depletion of the enzyme FRAP and the peptides SP, CCK, somatostatin, CGRP and an increase of VIP. Maximal depletions occur if the nerve is soaked with capsaicin solutions with a concentration higher than 3 mM. The depletion begins by 7 days and is complete by 11. Recovery begins at about 110 days and is largely complete by 200. Our studies have concentrated on the effects of 40 mM capsaicin examined 14 days after the application. 2) Capsaicin treatment of a peripheral nerve decreased the ability of C fibres in that nerve to excite or to inhibit spinal cord cells. It produces a marked expansion of receptive fields of some cells in the dorsal horn which respond to A fibre stimulation. It is proposed that this change is not due to anatomical changes but to disinhibition. A further example of receptive field expansion is seen after treatment of the mouse infraorbital nerve which defocuses the normally precise projection of individual whiskers onto single cells in the barrel field of the somatosensory cortex. 3) Behavioural consequences follow the treatment of one adult nerve with capsaicin. In the area subserved by the treated nerve, there is a raised threshold to response to chemical and thermal stimuli, no change in the response to mechanical stimuli and an increase of autotomy following nerve section. 4) The aim of the experiments was to determine the role of C fibres in producing the changes seen in spinal cord following peripheral nerve section. Capsaicin treatment of nerve imitates the central effect of complete nerve section in certain important ways. Both result in a marked expansion of the receptive field of some cells. The effect is produced by a change of chemical transport. The results show that C fibres influence the connection of A fibres onto spinal cord cells.     

The depolarising action of capsaicin on rat isolated sciatic nerve

The effect of capsaicin on the isolated sciatic nerve of rat was studied by extracellular recording of membrane polarisation. Capsaicin depolarised the sciatic nerve, but desensitization occurred rapidly upon repeated administration. Several other neuroactive substances, including substance P, were inactive. The depolarisation was reduced in nerves depleted of unmyelinated fibres by neonatal capsaicin treatment, suggesting that it occurs mainly in C-fibres. This depolarising action of capsaicin could explain the irritant and acute antinociceptive properties of capsaicin.     

Immediate expansion of receptive fields of neurons in area 3b of macaque monkeys after digit denervation.

The short-term effect of total or partial single-digit denervation on receptive fields (RFs) of neurons in somatosensory cortex (area 3b) was examined in five macaque monkeys. In two animals, after denervation by amputation, it was found that electrode positions that initially recorded neurons with RFs on the amputated digit had new RFs extending from the wound. Often the new fields were on adjacent digits. Neurons with initial RFs that were partially amputated, or in some cases close to but not on the amputated digit, showed considerable expansion of the remaining RF. In three monkeys local anesthesia was used to provide a temporary denervation. In these experiments electrodes were placed in equivalent positions in both cortices. The effect on cortex contralateral to the denervation was similar to that seen with amputation. However, after anesthesia returned to the digit, the expanded RFs contracted. In cortex ipsilateral to the denervation, RFs were on the opposite unaffected hand. These also rapidly expanded and then contracted, with the same time course as their counterparts in cortex contralateral to the denervation. Because of the rapidity of the expansion and its temporary nature with short-term denervation, the basis of the effect is probably an unmasking of existing but normally unexpressed connections, which are normally inhibited by the intact output from the denervated area. The wide arborization fields of thalamocortical afferents provide a potential source for the unmasked sensitivity. A mechanism for the inhibition that normally suppresses the expression of large RFs is not readily apparent. However, work in other species suggests that peripheral C fibers provide the primary source of input to central inhibitory circuits.     

Acute Effects of Total or Partial Digit Denervation on Raccoon Somatosensory Cortex

The immediate effects of total or partial denervation of single digits (0-16 hr after nerve transection) on primary somatosensory cortex were studied electrophysiologically. Comparisons of response properties and cortical somatotopy were made between intact raccoons and four groups of raccoons with transection of some or all of the nerves innervating the fourth or fifth digit. Animals with all four digital nerves cut (amputation of the digit) were most different from normal. Approximately half of the penetrations in the affected cortical region showed inhibitory responses to stimulation of adjacent skin regions. These consisted of a strong response to stimulus offset and/or a suppression of spontaneous activity during indentation. Since these responses were substantially different from those recorded several months after digit amputation, additional changes in connectivity and synaptic strength must occur with chronic denervation. These inhibitory responses were not seen in animals with one, two, or three nerves cut per digit.

In the animals with partial denervation of a digit, the greatest disruption occurred when both ventral nerves to the glabrous skin were transected. This yielded cell clusters with abnormally large receptive fields, disruptions in somatotopic organization, and a decreased occurrence of low-threshold responses. If only one nerve to glabrous skin was transected, there was less change, even if it was combined with transection of both nerves to hairy skin. These results suggest that the release of inhibitory responses in a cortical digital region by amputation is prevented by the retention of even one ventral nerve. None of the denervation conditions produced large nonresponsive areas of cortex, which would have indicated a loss of all inputs.     

Acute effects of total or partial digit denervation on raccoon somatosensory cortex

The immediate effects of total or partial denervation of single digits (0-16 hr after nerve transection) on primary somatosensory cortex were studied electrophysiologically. Comparisons of response properties and cortical somatotopy were made between intact raccoons and four groups of raccoons with transection of some or all of the nerves innervating the fourth or fifth digit. Animals with all four digital nerves cut (amputation of the digit) were most different from normal. Approximately half of the penetrations in the affected cortical region showed inhibitory responses to stimulation of adjacent skin regions. These consisted of a strong response to stimulus offset and/or a suppression of spontaneous activity during indentation. Since these responses were substantially different from those recorded several months after digit amputation, additional changes in connectivity and synaptic strength must occur with chronic denervation. These inhibitory responses were not seen in animals with one, two, or three nerves cut per digit. In the animals with partial denervation of a digit, the greatest disruption occurred when both ventral nerves to the glabrous skin were transected. This yielded cell clusters with abnormally large receptive fields, disruptions in somatotopic organization, and a decreased occurrence of low-threshold responses. If only one nerve to glabrous skin was transected, there was less change, even if it was combined with transection of both nerves to hairy skin. These results suggest that the release of inhibitory responses in a cortical digital region by amputation is prevented by the retention of even one ventral nerve. None of the denervation conditions produced large nonresponsive areas of cortex, which would have indicated a loss of all inputs.     

Bilateral receptive field neurons and callosal connections in the somatosensory cortex

Earlier studies recording single neuronal activity with bilateral receptive fields in the primary somatosensory cortex of monkeys and cats agreed that the bilateral receptive fields were related exclusively to the body midline and that the ipsilateral information reaches the cortex via callosal connections since they are dense in the cortical region representing the midline structures of the body while practically absent in the regions representing the distal extremities. We recently found a substantial number of neurons with bilateral receptive fields on hand digits, shoulders-arms or legs-feet in the caudalmost part (areas 2 and 5) of the postcentral gyrus in awake Japanese monkeys (Macaca fuscata). I review these results, discuss the functional implications of this bilateral representation in the postcentral somatosensory cortex from a behavioural standpoint and give a new interpretation to the midline fusion theory.     

Receptive fields of auditory cortical neurons in the cat

Receptive fields of auditory cortical neurons were studied by electrical stimulation of nerve fibers in different parts of the cochlea in cats anesthetized with pentobarbital. The dimensions of the receptive fields were shown to depend on the topographic arrangement of the neuron in the auditory cortex. The more caudad the neuron on the cortical projection of the cochlea in the primary auditory cortex, the more extensive its receptive field. The receptive fields were narrowest in the basal turn of the cochlea and were symmetrical with respect to their center. It is suggested that the region of finest discrimination of acoustic stimuli in cats is located in the basal region of the cochlea, i.e., in that part of its receptor system which has the narrowest receptive field and is represented by significantly more (than the middle and apical regions of the cochlea) nerve cells in the primary auditory cortex [1].A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 467–473, September–October, 1981.     

The immediate and long-term effects of applying capsaicin to cutaneous nerves

Capsaicin has now been shown to have a neurotoxic action on C-fibres in adult rodents and several other mammalian species. In the adult the effect is preferentially on nociceptive C-fibres. The hypoalgesia and loss of neurogenic inflammation that follow capsaicin treatment are likely to be a direct consequence of the C-fibre loss. In addition to its long-term toxic action, capsaicin also has an immediate effect on conduction in nociceptive C-fibres. This action probably produces the short-term hypoalgesia and loss of antidromic plasma extravasation that follow application of capsaicin to peripheral nerves.     

Stimulation of bitterness by capsaicin and menthol: differences between lingual areas innervated by the glossopharyngeal and chorda tympani nerves

Capsaicin is viewed as a purely chemesthetic stimulus that selectively stimulates the somatosensory system. Here we show that when applied to small areas of the tongue, capsaicin can produce a bitter taste as well as sensory irritation. In experiment 1, individuals were screened for the ability to perceive bitterness from capsaicin on the circumvallate papillae. Fifteen of 25 subjects who reported at least weak bitterness rated the intensity of taste, irritation and coolness produced by 100-320 microM capsaicin and 100-320 mM menthol applied via cotton swabs to the tip (fungiform region), the posterior edge (foliate region), and the dorsal posterior surface (circumvallate region) of the tongue. Sucrose, citric acid, sodium chloride and quinine hydrochloride were applied to the same areas to assess tastes responsiveness. On average, capsaicin and menthol produced "moderate" bitterness (and no other significant taste qualities) in the circumvallate region, and weaker bitterness on the side and tip of the tongue. Sensory irritation from capsaicin was rated significantly higher at the tongue tip, whereas menthol coolness was rated higher in the circumvallate region. In experiment 2 we applied sucrose and quinine hydrochloride together with capsaicin to investigate the effects other taste stimuli might have on capsaicin's reported bitterness. As expected, adding quinine produced stronger bitterness in the circumvallate and fungiform regions, and adding sucrose significantly reduced the bitterness of capsaicin in the circumvallate region. Overall, the results suggest that capsaicin and menthol are capable of stimulating a subset of taste neurons that respond to bitter substances, perhaps via receptor-gated ion channels like those recently found in capsaicin- and menthol-sensitive trigeminal ganglion neurons, and that the glossopharyngeal nerve may contain more such neurons than the chorda tympani nerve. That some people fail to perceive bitterness from capsaicin further implies that the incidence of capsaicin-sensitive taste neurons varies across people as well as between gustatory nerves.     

Chronic effects of total or partial digit denervation on raccoon somatosensory cortex.

Electrophysiological recordings were made in the primary somatosensory cortex of anesthetized raccoons 14 to 169 days following digit amputation or 60 to 129 days after transection of the two nerves innervating the ventral surface of the fourth digit. The incidence of inhibitory responses decreased from 50% of the penetrations immediately after amputation to 35% over the first 3 weeks and to almost zero after 2 months. The number of sites with low-threshold excitatory responses increased from 4% to 14% to 50% during these same intervals. Initially, the excitatory fields were small and located over the nerve stumps, and were therefore probably due to direct stimulation of the damaged nerves. At 2 months after amputation, the excitatory receptive fields were large and diffuse. Although the size of receptive fields decreased during the later period (when the thresholds were also decreasing), there was no recovery of any precise somatotopic organization in the deafferented cortex. The reorganization process in the raccoon thus consists of at least two stages: The early stage is dominated by inhibitory connections, whereas the second involves a recovery and restructuring of excitatory inputs. From 2 to 4 months after partial digit denervation, there were only minor changes in response properties or somatotopic organization in the deafferented cortex as compared to immediately after nerve transection. Thus, few of the characteristics of reorganization induced by digit amputation were elicited by this treatment, which leaves some of the digit innervation intact. There was, however, an unexpected increase in the portion of the ventral digit that was able to activate the cortex, suggesting complexities in the peripheral innervation of the digit that need to be resolved.     

Spinal cord sensory systems after neonatal capsaicin

Animals with a severe reduction in the number of afferent C-fibres as a consequence of neonatal administration of capsaicin, exhibit a number of neurological and behavioral deficits including increased nociceptive thresholds, altered somato-visceral and viscero-visceral reflexes, depressed cardiovascular and respiratory reflexes and changes in the organisation of spinal cord sensory systems. The reduction in the number of C-fibres produced by neonatal capsaicin does not cause a decrease of similar magnitude in the number of dorsal horn cells driven by the surviving C-fibres. Twenty-two per cent of dorsal horn neurones in capsaicin treated animals respond to electrical stimulation of the surviving afferent C-fibres: a reduction of only 50% from control values. Inhibitory controls on afferent C-fibre evoked responses of dorsal horn neurones are weaker in capsaicin treated rate than in control animals. The cutaneous receptive fields of some dorsal horn neurones can increase in size following stimulation of afferent C-fibres. Tonic descending inhibition on C-fibre evoked responses of dorsal horn neurones is reduced in capsaicin treated rats: fewer neurones show tonic descending inhibition in these animals and those that do are subjected to less powerful inhibitions than similar neurones from control animals. However, some central inhibitory mechanism are unchanged after neonatal capsaicin treatment, specially those that do not involve afferent C-fibres. We suggest that the nervous system develops central inhibition in response to and directed towards the excitations mediated by its afferent drives. Therefore reduced central inhibition in response to a decreased number of afferent C-fibres can compensate for the lost capacity in the signalling of peripheral noxious events.     

Capsaicin application to central or peripheral vagal fibers attenuates CCK satiety

Capsaicin treatment destroys small primary sensory neurons including a subpopulation of vagal afferents. Intraperitoneal, fourth ventricular or perivagal application of capsaicin attenuated or abolished cholecystokinin (CCK)-induced suppression of food intake. Capsaicin applied to the thoracolumbar spinal cord or to the pyloric region of the stomach did not alter CCK-induced reductions of food intake. Intraperitoneal capsaicin treatment reduced substance P-like immunoreactivity (SPLI) in the spinal dorsal horn and parts of the dorsal hindbrain. SPLI depletion, therefore, served as a histochemical indicator of the spread of capsaicin from its site of application. Capsaicin applied directly to the vagal trunks did not reduce SPLI in the spinal cord or hindbrain. Intraventricular capsaicin reduced SPLI in the hindbrain but not in the spinal cord. These data indicate that localized capsaicin application attenuates CCK-induced suppression of food intake by impairing the function of either central or peripheral portions of vagal afferent neurons. The data also support the conclusion that intraperitoneal capsaicin attenuates CCK-induced suppression of feeding by impairing vagal sensory function.     

Low temperature painful stimulus alters brain wave pattern of transcutaneous electrical stimulus

The somatosensory evoked response recorded from the scalp over the somatosensory cortex was used to examine the interaction between painful cold and transcutaneous electrical stimuli delivered concomitantly. When a painful cold stimulus was applied to the palmar receptive field of the median nerve while that nerve was being stimulated with electrical pulses at the wrist, there was an augmentation of an early component of the somatosensory evoked response manifested by an increase in the amplitude of a wave segment in comparison with room temperature controls. This augmentation depended on there being normal conduction of nerve impulses in both the population of small and large peripheral nerve fibers as compared to a state in which conduction was blocked selectively by a local anesthetic or a pressure cuff in those small and large fibers, respectively. The augmentation was not found to be characteristic of an arousal phenomenon, but was localized to the somatosensory cortex. This might represent the effects of a non-specific thalamortical projection system on a specific one.     

Sensory and behavioral properties of neurons in posterior parietal cortex of the awake, trained monkey.

Neurons in posterior parietal cortex of the awake, trained monkey respond to passive visual and/or somatosensory stimuli. In general, the receptive fields of these cells are large and nonspecific. When these neurons are studied during visually guided hand movements and eye movements, most of their activity can be accounted for by passive sensory stimulation. However, for some visual cells, the response to a stimulus is enhanced when it is to be the target for a saccadic eye movement. This enhancement is selective for eye movements into the visual receptive field since it does not occur with eye movements to other parts of the visual field. Cells that discharge in association with a visual fixation task have foveal receptive fields and respond to the spots of light used as fixation targets. Cells discharging selectively in association with different directions of tracking eye movements have directionally selective responses to moving visual stimuli. Every cell in our sample discharging in association with movement could be driven by passive sensory stimuli. We conclude that the activity of neurons in posterior parietal cortex is dependent on and indicative of external stimuli but not predictive of movement.     

Responses of neurons in cat primary somatosensory cortex to repetitive stimulation of vibrissae

Extra- and intracellular responses of neurons in the primary somatosensory cortex to repetitive mechanical stimulation of the vibrissae at different frequencies were studied in unanesthetized curarized adult cats. Unlike responses to electrical stimulation of the combined afferent input (the infraorbital nerve) spike discharges of neurons in response to vibrissal stimulation can reproduce rather higher frequencies of stimulation and their initial character changes more often in the course of the repetitive series. Most cortical neurons were characterized by limitation of the area of their peripheral receptive fields with an increase in the frequency of adequate repetitive stimulation. A group of cortical neurons was distinguished by its ability to respond to high-frequency stimulation and to generate burst discharges. Comparison of the frequency characteristics of spike responses of these cells and of inhibitory synaptic action in other cortical neurons led to the conclusion that this group of cells thus distinguished may be inhibitory cortical neurons. The role of interaction between excitatory and inhibitory processes arising in cortical neurons during repetitive stimulation of different areas of their receptive fields is discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 14, No. 2, pp. 164–171, March–April, 1982.     

Dissociation of μ- and δ-opioid inhibition of glutamatergic synaptic transmission in superficial dorsal horn

Background

Although it has been widely accepted that the primary somatosensory (SI) cortex plays an important role in pain perception, it still remains unclear how the nociceptive mechanisms of synaptic transmission occur at the single neuron level. The aim of the present study was to examine whether noxious stimulation applied to the orofacial area evokes the synaptic response of SI neurons in urethane-anesthetized rats using an in vivo patch-clamp technique.

Results

In vivo whole-cell current-clamp recordings were performed in rat SI neurons (layers III-IV). Twenty-seven out of 63 neurons were identified in the mechanical receptive field of the orofacial area (36 neurons showed no receptive field) and they were classified as non-nociceptive (low-threshold mechanoreceptive; 6/27, 22%) and nociceptive neurons. Nociceptive neurons were further divided into wide-dynamic range neurons (3/27, 11%) and nociceptive-specific neurons (18/27, 67%). In the majority of these neurons, a proportion of the excitatory postsynaptic potentials (EPSPs) reached the threshold, and then generated random discharges of action potentials. Noxious mechanical stimuli applied to the receptive field elicited a discharge of action potentials on the barrage of EPSPs. In the case of noxious chemical stimulation applied as mustard oil to the orofacial area, the membrane potential shifted depolarization and the rate of spontaneous discharges gradually increased as did the noxious pinch-evoked discharge rates, which were usually associated with potentiated EPSP amplitudes.

Conclusions

The present study provides evidence that SI neurons in deep layers III-V respond to the temporal summation of EPSPs due to noxious mechanical and chemical stimulation applied to the orofacial area and that these neurons may contribute to the processing of nociceptive information, including hyperalgesia.     

Somatosensory cortical unit responses to stimulation of the vibrissae in cats

Characteristics of extra- and intracellular responses of 57 neurons in the vibrissal projection zone of the first somatosensory area of the cat cortex were investigated. The intensity of both excitatory and inhibitory unit responses was found to diminish during successive stimulation of different parts of the receptive fields in the direction from center toward periphery. Usually, when central parts of receptive fields were stimulated, inhibition in the unit responses was postexcitatory, whereas when peripheral parts were stimulated inhibition could precede excitation. The possibility of an increase in the role of interaction between excitatory and inhibitory processes arising in neurons in response to vibrissal stimulation with an increase in the distance from center to periphery of receptive fields of single cortical cells is discussed. Neurons found during one insertion of the microelectrode were seen to have common center for their receptive fields, but the diameters of the receptive fields of individual neurons could differ significantly. Moreover, during such vertical insertions responses of neurons with primary inhibition to the stimuli presented were recorded.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 2, pp. 124–130, March–April, 1980.     

Mechanism of inhibitory action of capsaicin on particulate axoplasmic transport in sensory neurons in culture

The inhibitory effect of capsaicin on axoplasmic transport in cultured dorsal root ganglion cells was analyzed by video-enhanced contrast microscopy. Capsaicin inhibited particle transports in a dose-dependent manner, irrespective of the diameter of axons. The effect of capsaicin was reversible at low concentrations. Capsaicin affected both the anterograde and retrograde transport. Large organelles were more sensitive to capsaicin than small ones in the retrograde transport. An experiment using calcium-sensitive dye, Fura 2, indicated that capsaicin raised the intraneuronal free calcium concentration preceding the inhibition of the transport. Electron microscopy revealed that microtubules and neurofilaments are disorganized and disoriented by capsaicin. We reached a conclusion that capsaicin inhibits fast axoplasmic transport of both anterograde and retrograde directions in all types of somatosensory neurons in culture by disorganizing intraaxonal cytoskeletal structures, through the elevated intracellular Ca²⁺ concentration. © 1993 John Wiley & Sons, Inc.     

Integrating information from different senses in the auditory cortex

Multisensory integration was once thought to be the domain of brain areas high in the cortical hierarchy, with early sensory cortical fields devoted to unisensory processing of inputs from their given set of sensory receptors. More recently, a wealth of evidence documenting visual and somatosensory responses in auditory cortex, even as early as the primary fields, has changed this view of cortical processing. These multisensory inputs may serve to enhance responses to sounds that are accompanied by other sensory cues, effectively making them easier to hear, but may also act more selectively to shape the receptive field properties of auditory cortical neurons to the location or identity of these events. We discuss the new, converging evidence that multiplexing of neural signals may play a key role in informatively encoding and integrating signals in auditory cortex across multiple sensory modalities. We highlight some of the many open research questions that exist about the neural mechanisms that give rise to multisensory integration in auditory cortex, which should be addressed in future experimental and theoretical studies.     

Rabbit visual cortical neurons with simple and complex receptive fields

Receptive fields of neurons of the rabbit visual cortex selective for stimulus orientation were investigated. These receptive fields were less well differentiated than those of the analogous neurons of the cat visual cortex (large in size and circular in shape). Two mechanisms of selectivity for stimulus orientation were observed: inhibition between on and off zones of the receptive field (sample type) and oriented lateral inhibition within the same zone of the receptive field (complex type). Lateral inhibition within the same zone of the receptive field also took place in unselective neurons; "complex" selective neurons differed from them in the orientation of this inhibition. A combination of both mechanisms was possible in the receptive field of the same neuron. It is suggested that both simple and complex receptive fields are derivatives of unselective receptive fields and that "complex" neurons are not the basis for a higher level of analysis of visual information than in "simple" neurons.A. N. Severtsov Institute of Evolutionary Morphology and Ecology of Animals, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 10, No. 1, pp. 13–21, January–February, 1978.