Analysis of reflex activity in cardiac sympathetic nerve induced by myelinated phrenic nerve afferents

Electrical stimulation of the phrenic nerve afferents evoked excitatory responses in the right inferior cardiac sympathetic nerve in chloralose-anaesthetized cats. The reflex was recorded in intact and spinal cats. The latency and threshold of the volley recorded from the phrenic nerve as well as of the cord dorsum potentials evoked by electrical stimulation of the phrenic nerve indicated that group III afferents were responsible for this reflex. The phrenicocardiac sympathetic reflex recorded in intact cats was followed by a silent period. The maximum amplitude of the reflex discharges was 800 microV, the latency was 83 ms and the central transmission time 53 ms. Duration of the silent period lasted up to 0.83 s. In spinal cats the reflex was recorded 5.5-8 h after spinalization. The maximum amplitude of the spinal reflex discharges ranged from 22 to 91 microV and the latency from 36 to 66 ms.     

Effects of ipsilateral and contralateral cervical phrenic afferents stimulation on phrenic motor unit activity in the cat

The phrenic-to-phrenic inhibitory reflex has been analyzed using recordings of activity of single C₅-phrenic motor units (PMUs). After ipsilateral or contralateral stimulation of the C₆-phrenic root, early and late PMUs exhibit a similar inhibition. After contralateral stimulation, the duration of the inhibition is smaller and the threshold stimulus is higher than the corresponding values observed after ipsilateral stimulation. The latency of the inhibition is similar for both stimulations. Hemispinalization, contralateral to the recording site, affects weakly the phrenic-to-phrenic reflex. We conclude that early and late PMUs receive a similar inhibitory input from phrenic afferents and that the inhibition observed after cervical phrenic nerve stimulation may involve spinal cord circuits.     

Restorative respiratory pathways after partial cervical spinal cord injury: role of ipsilateral phrenic afferents

After disruption of the descending respiratory pathways induced by unilateral cervical spinal cord injury (SCI) in rats, the inactivated ipsilateral (ipsi) phrenic nerve (PN) discharge may partially recover following some specific experimental procedures [such as contralateral (contra) phrenicotomy (Phx)]. This phrenic reactivation involves normally silent contra pathways decussating at the level of the phrenic nucleus, but the mechanisms of this crossed phrenic activation are still poorly understood. The present study investigates the contribution of sensory phrenic afferents to this process by comparing the acute effects of ipsi and contra Phx. We show that the phrenic discharge (recorded on intact PNs) was almost completely suppressed 0 h and 3 h after a lateral cervical SCI, but was already spontaneously reactivated after 1 week. This ipsi phrenic activity was enhanced immediately after contra Phx and was completely suppressed by an acute contra cervical section, indicating that it is triggered by crossed phrenic pathways located laterally in the contra spinal cord. Ipsi phrenic activity was also abolished immediately after ipsi Phx that interrupts phrenic sensory afferents, an effect prevented by prior acute ablation of the cervical dorsal root ganglia, indicating that crossed phrenic activation depends on excitatory phrenic sensory afferents but also putatively on inhibitory non-phrenic afferents. On the basis of these data, we propose a new model for crossed phrenic activation after partial cervical injury, with an essential role played by ipsi-activating phrenic sensory afferents.     

Changes in the excitability of motor neurons and synaptic effects on them during formation of the generator of scratching movements in the cat

It is shown that the state of the segmental apparatus of the lumbal spinal cord of immobilized intercollicularly decerebrated cats during formation of a scratching generator is essentially different from that of a spinal animal. The excitability of "aiming" and "scratching" motoneurons increases, recurrent and reciprocal Ia inhibition of motoneurons becomes stronger and influence of Ib afferents weaker. The flexor reflex afferents exert inhibitory influences on "aiming" motoneurons. After spinalization these influences become excitatory, and the inhibitory influences on "scratching" motoneurons become weaker. The functional role of described changes is discussed.     

Spinal interneurones; how can studies in animals contribute to the understanding of spinal interneuronal systems in man?

The first part of this review deals with arguments that the essential properties and organization of spinal interneuronal systems in the cat and in man are similar. The second part is concerned with the possibility that some interneuronal systems may be responsible for motor disturbances caused by spinal cord injuries and that these interneurones may be defined. This possibility is discussed with respect to the hyperexcitability of -motoneurones and the exaggeration of stretch reflexes in spastic patients. To this end, what is known about cat spinal interneurones and about the neuronal basis and pharmacological treatment of spasticity, is put together. Interneurones in di- and trisynaptic reflex pathways from group II muscle afferents are singled out, since they are depressed by the ₂ noradrenaline receptor agonists clonidine and tizanidine, which is a critical feature of interneurones expected to contribute to exaggerated stretch reflexes which are reduced by ₂ noradrenaline receptor agonists. Recent observations that reflex excitation of extensor motoneurones from group II afferents is enhanced in spastic patients and that the pathologically strong reflex actions of group II afferents are reduced by clonidine and tizanidine support this proposal. On the other hand, a lack of effect of clonidine and tizanidine upon other types of excitatory or inhibitory interneurones argues against any major contribution of such interneurones to the abnormally strong responses of -motoneurones to muscle stretch.     

Functional organization of the spinal reflex pathways from forelimb afferents to hindlimb motoneurons in the cat. II. Conditions of the interneuronal connections

The interneuronal conditionsof the descending pathways from forelimb afferents to hindlimb motoneurones were investigated by testing spatial interactions in these pathways and between these pathways and segmental lumbar reflex pathways. In high spinal unanaesthetized cats hindlimb motoneuroneswere intracellularly recorded and spatial interactions were tested between effects evoked by stimulation of pairs of ipsi- and contralateral forelimb nerves or pairs of a forelimb and an ipsilateral hindlimb nerve. The excitatory and late inhibitory pathways from forelimb afferents projecting to most of the hindlimb motoneurone pools, showed an interactive pattern which was distinctly different to the fast inhibitory pathway projecting specifically for ipsilateral forelimb afferents to flexor digitorum and hallucis longus (FDHL) motoneurones. Stimulation of homonymous or heteronymous pairs of two forelimb nerves of both sides evoked generally a distinct spatial facilitation of the excitatory and late inhibitory effects, while the specific early IPSPs to FDHL motoneurones were not facilitated. Paired stimulation of two forelimb nerves of one side only produced spatial facilitation of EPSPs or late IPSPs if low strength stimuli were used, using higher strength which induced larger effects, generally caused occlusion instead. In case of large IPSPs this may be due to the vicinity to the equilibrium potential. Except for an inhibition of cutaneous reflex pathways, the spatial interaction of the excitatory and late inhibitory pathways onto segmental lumbar reflex pathways was weak and variable. The fast inhibitory pathway to FDHL motoneurone showed a partial spatial facilitatory interaction with lumbar reflex pathways from cutaneous and group II muscle afferents. The second IPSP wave evoked by this pathway was inhibited by antidromic stimulation of the ventral root L7S1 and of the α-efferents of the antagonistic peroneal nerve. From the results conclusions are drawn on the interneuronal organization of the descending pathways from forelimb afferents to hindlimb motoneurones.     

Activity in sympathetic neurons supplying skin and skeletal muscle in spinal cats

In anesthetized cats with intact neuraxis, vasoconstrictor neurons supplying skeletal muscle (MVC) and hairy and hairless skin (CVC), and sudomotor neurons innervating sweat glands (SM), exhibit distinct reflex patterns. MVC and SM are largely under excitatory, CVC under inhibitory control of various afferent input systems from the body surface and from the viscera. In chronic spinal animals all 3 types of sympathetic neurons exhibit some resting activity without cardiac and respiratory modulation. Sixty to 150 days after isolation of the neural circuits within the sympathetic systems within the spinal cord from their descending control systems by spinalization, these reflex patterns are very similar to those in animals with intact neuraxis. Important changes which do occur after spinalization are the following: CVC neurons are excited by stimulation of visceral afferents in spinal animals but inhibited in animals with intact neuraxis; noxious stimulation of skin leads to long-lasting after-effects in CVC and SM neurons in spinal animals. Comparison of reflexes among spinal animals and animals with intact neuraxis indicates that spinal circuits are probably important for the functioning of the sympathetic systems. It is possible that these circuits determine the typical reaction patterns seen in the sympathetic systems by integrating multisensory information from primary afferents and information from spinal descending fiber tracts.     

Neuronal organization of coeruleo-spinal connections in the cat

Electrical stimulation of locus coeruleus in anesthetized cats was accompanied by a decrease in the inhibitory action of flexor reflex afferents (FRA) on extensor motoneurons. No changes in excitatory reactions of spinal motoneurons were observed. Microinjections of aspartic acid or chlorpromazine depressed FRA inhibitory action; injection of procaine and noradrenaline potentiated this action. The responses of differente spinal interneurons during activation of locus coeruleus were also studied. A conclusion is made that the inhibitory action of FRA is depressed by coeruleo-spinal influences on the level of the last-order inhibitory interneuron of the FRA system.     

Functional organization of the spinal reflex pathways from forelimb afferents to hindlimb motoneurones in the cat. II. Conditions of the interneuronal connections

The interneuronal conditions of the descending pathways from forelimb afferents to hindlimb motoneurones were investigated by testing spatial interactions in these pathways and between these pathways and segmental lumbar reflex pathways. In high spinal unanaesthetized cats hindlimb motoneurones were intracellularly recorded and spatial interactions were tested between effects evoked by stimulation of pairs of ipsi- and contralateral forelimb nerves or pairs of a forelimb and an ipsilateral hindlimb nerve. The excitatory and late inhibitory pathways from forelimb afferents projecting to most of the hindlimb motoneurone pools, showed an interactive pattern which was distinctly different to the fast inhibitory pathway projecting specifically from ipsilateral forelimb afferents to flexor digitorum and hallucis longus (FDHL) motoneurones. Stimulation of homonymous or heteronymous pairs of two forelimb nerves of both sides evoked generally a distinct spatial facilitation of the excitatory and late inhibitory effects, while the specific early IPSPs to FDHL motoneurones were not facilitated. Paired stimulation of two forelimb nerves of one side only produced spatial facilitation of EPSPs or late IPSPs if low strength stimuli were used, using higher strength which induced larger effects, generally caused occlusion instead. In case of large IPSPs this may be due to the vicinity to the equilibrium potential. Except for an inhibition of cutaneous reflex pathways, the spatial interaction of the excitatory and late inhibitory pathways onto segmental lumbar reflex pathways was weak and variable. The fast inhibitory pathway to FDHL motoneurones showed a partial spatial facilitatory interaction with lumbar reflex pathways from cutaneous and group II muscle afferents. The second IPSP wave evoked by this pathway was inhibited by antidromic stimulation of the ventral root L7S1 and of the alpha-efferents of the antagonistic peroneal nerve. From the results conclusions are drawn on the interneuronal organization of the descending pathways from forelimb afferents to hindlimb motoneurones.     

Activity of Ia inhibitory interneurons during fictitious scratch reflex in the cat

1. (1) The fictitious scratch reflex was observed in decerebrate cats immobilized with Flaxedil. The activity of interneurons in the inhibitory pathways from Ia afferents to motoneurons of antagonistic muscles was recorded during scratching. The selected interneurons were supplied by Ia afferents from m. vastus, posterior biceps-semitendinosus and sartorius.

2. (2) Almost all recorded interneurons showed periodic modulation of activity. Their maximal activity in the scratch cycle usually coincided with the maximal activity of motoneurons of those muscles from which the interneurons receive Ia afferents. Excitation of Ia afferents by passive stretch of the muscle or by electrical stimulation of the muscle nerve resulted in the increase of the interneuron activity, without changing its timing in the scratch cycle.

Facilitatory interaction between cutaneous afferents from low threshold mechanoreceptors and nociceptors in segmental reflex pathways to α-motoneurons

In spinal cats weak stroking of the fur of the foot facilitated PSPs from group II muscle afferents in α-motoneurons. This spatial facilitation indicates that afferents from low threshold cutaneous mechanoreceptors and group II muscle afferents may converge onto common interneurons in segmental reflex pathways. The results confirm the contribution of group II muscle afferents to a multisensorial spinal reflex system for movement control.     

Ventricular reflex interactions during transmural myocardial ischemia

The role of left ventricular receptors with sympathetic afferent fibers in the reflex response to myocardial ischemia is controversial, particularly in the canine model. Previous experiments have shown that reflex excitatory responses mediated by left ventricular sympathetic afferents can be detected in sinoaortic denervated and vagotomized dogs during transmural myocardial ischemia. The purpose of these experiments was to determine if reflex excitatory responses occur in dogs with intact left ventricular vagal afferents. Experiments were performed in 27 chloralose-anesthetized dogs with sinoaortic denervation. Responses of efferent renal sympathetic nerve activity, arterial, and left atrial pressures to transmural and non-transmural inferoposterior myocardial ischemia were measured before and after interruption of left ventricular sympathetic afferents by stellectomy. The adequacy of sympathetic deafferentation was assessed by measurement of renal nerve responses to epicardial bradykinin. Prior to stellectomy, excitatory responses were observed in 10 animals and inhibitory responses in 9 animals. The remaining animals had no responses and were excluded from analysis. In the excitatory group, reflex increases in renal nerve activity during both transmural and non-transmural inferoposterior ischemia were abolished by stellectomy and not replaced by inhibitory responses. In the inhibitory group, non-transmural inferoposterior ischemia elicited greater reflex decreases in renal nerve activity when left ventricular sympathetic afferents were intact. After stellectomy, transmural ischemia elicited greater reflex inhibition of renal nerve activity. Renal nerve responses to epicardial bradykinin were abolished by stellectomy. These results indicate that reflex excitatory responses mediated by left ventricular receptors with sympathetic afferent fibers can be elicited in dogs with intact vagal afferents. These excitatory responses are most apparent during transmural myocardial ischemia. In dogs with inhibitory responses to coronary occlusion, activation of sympathetic afferents during transmural ischemia appears to attenuate reflex inhibitory responses mediated by left ventricular vagal afferents.     

Late prolonged discharges in the motor nerves of the hindlimbs and their relationship to locomotor rhythmicity in thalamically immobilized cats]

Effects of flexor reflex afferents stimulation were investigated on high decerebrated curarized cats. Stimulation of ipsilateral flexor reflex afferents evoked late long-lasting discharges in flexor nerves. Contralateral flexor reflex afferents stimulation evoked late discharges both in extensor and flexor nerves. Transition from late discharges to rhythmic discharges was observed. Early segmental reflexes were tonically depressed in thalamic in comparison with acute spinal cats. A similar tonic depression of segmental reflexes took place in acute spinal cats after DOPA injection. Segmental reflexes were distinctly modulated during late and rhythmic discharges. On the basis of the data available possible central mechanisms of the observed changes of segmental reflexes are discussed.     

Inhibitory influences of reticulospinal fibers of the lateral funiculus on neurons of the reflex arc of the thoracic region of the spinal cord

Experiments on anesthetized cats with partial lesions of the spinal cord show that reticulospinal pathways in the ventral part of the lateral funiculus take part in the polysynaptic reflex inhibition caused by stimulation of ipsi- and contralateral reticular formation. The reticulofugal volley in the ventrolateral funiculus produced relatively short (up to 7 ms) inhibitory PSP in some motoneurons of the internal intercostal nerve and at the same time long-lasting depression of EPSPs evoked by high-threshold segmentary afferents. This volley also caused inhibitory PSP in segmental interneurons (in 14 out of 91, i.e. 15.5%). The IPSPs lasted no longer than 100 ms, while the segmentary excitatory responses of 21 out of 43 interneurons were depressed for 120-500 ms. The described inhibitory action of the lateral reticulospinal system on segmentary reflex pathways is suggested to be caused by several synaptic mechanisms which do not necessarily include hyperpolarization of spinal neurons. Possible mechanisms of such inhibition are discussed.     

Bradykinin modulation of a spinal nociceptive reflex in the rat.

Bradykinin (BK) is a potent algesic compound. Therefore, we hypothesized that BK, acting as a peripheral noxious stimulus, would attenuate or inhibit responses to another noxious stimulus. When administered intravenously (i.v.) to rats lightly anesthesized with pentobarbital, BK produced a dose-dependent (12-144 micrograms/kg) inhibition of the nociceptive tail-flick (TF) reflex. BK also produced a dose-dependent decrease in mean arterial blood pressure, a subsequent increase in heart rate and an increase in the rate of respiration. The latency to the maximal effect of BK on the TF reflex was 10 s and was occasionally preceded by pseudoaffective responses at doses greater than 48 micrograms/kg BK. Neonatal treatment with capsaicin (50 mg/kg, subcutaneous) significantly attenuated BK-produced inhibition of the TF reflex indicating that BK was acting via peripheral afferents to inhibit the TF reflex. Reversible cold block or complete spinal transection at a low thoracic level (T9-12), but not reversible cold block at a high cervical level (C1-2), significantly attenuated BK-produced inhibition of the TF reflex, suggesting that BK activates afferents which enter the spinal cord between C2 and T9. Pretreatment with intrathecally administered phentolamine (30 micrograms), an alpha-adrenoceptor antagonist, or methysergide (30 micrograms), a non-selective serotonin receptor antagonist, did not alter BK-produced inhibition of the TF reflex, further supporting the absence of activation of descending systems from the brainstem by i.v. BK. While coadministration of PGE2 and BK significantly potentiated BK-produced inhibition of the TF reflex, neither bilateral removal of the stellate ganglion nor bilateral cervical vagotomy significantly affected the inhibitory action of i.v. BK on the TF reflex. These results suggest that i.v. BK inhibits the nociceptive TF reflex by activation of capsaicin-sensitive visceral afferents entering the spinal cord between C2 and T9.     

A survey of spinal collateral actions of feline ventral spinocerebellar tract neurons

The aim of this study was to identify spinal target cells of spinocerebellar neurons, in particular the ventral spinocerebellar tract (VSCT) neurons, giving off axon collaterals terminating within the lumbosacral enlargement. Axons of spinocerebellar neurons were stimulated within the cerebellum while searching for most direct synaptic actions on intracellularly recorded hindlimb motoneurons and interneurons. In motoneurons the dominating effects were inhibitory [inhibitory postsynaptic potentials (IPSPs) in 67% and excitatory postsynaptic potentials (EPSPs) in 17% of motoneurons]. Latencies of most IPSPs indicated that they were evoked disynaptically and mutual facilitation between these IPSPs and disynaptic IPSPs evoked by group Ia afferents from antagonist muscles and group Ib and II afferents from synergists indicated that they were relayed by premotor interneurons in reflex pathways from muscle afferents. Monosynaptic EPSPs from the cerebellum were accordingly found in Ia inhibitory interneurons and intermediate zone interneurons with input from group I and II afferents but only oligosynaptic EPSPs in motoneurons. Monosynaptic EPSPs following cerebellar stimulation were also found in some VSCT neurons, indicating coupling between various spinocerebellar neurons. The results are in keeping with the previously demonstrated projections of VSCT neurons to the contralateral ventral horn, showing that VSCT neurons might contribute to motor control at a spinal level. They might thus play a role in modulating spinal activity in advance of any control exerted via the cerebellar loop.     

Effect of capsaicin on micturition and associated reflexes in chronic spinal rats

The role of capsaicin-sensitive bladder afferents in micturition was studied in unanesthetized chronic spinal rats. Reflex voiding in response to tactile stimulation of the perigenital region appeared 5–9 days after spinal cord injury (SCI) whereas voiding induced by bladder distension occurred 2–3 weeks after SCI. The frequency and amplitude of reflex bladder contractions recorded under isovolumetric conditions were similar in chronic spinal and urethane-anesthetized CNS-intact rats. However, cystometrograms (CMGs) performed 6–8 weeks after SCI revealed that the chronic spinal rats had larger bladder capacities (1.86 ml) than CNS-intact rats (0.48 ml) and also exhibited multiple, small-amplitude, nonvoiding bladder contractions that were not detected in CNS-intact rats. Administration of capsaicin (50 mg/kg s.c.) acutely (onset 14–40 min) suppressed reflex bladder activity induced by bladder distension or by perigenital stimulation in chronic spinal animals. However, pretreatment of chronic spinal rats with capsaicin (125 mg/kg s.c.) 4 days before the experiment did not depress voiding reflexes or change bladder capacity but did eliminate the nonvoiding contractions. Inhibition of reflex bladder contractions by mechanical stimulation of rectoanal canal or the uterine cervix-vagina was not altered by pretreatment with capsaicin. These data indicate that capsaicin-sensitive bladder afferents are not essential for the initiation of reflex micturition in chronic spinal rats. However, these afferents do contribute to hyperactivity of the bladder during the filling phase of the CMG. Thus, capsaicin-sensitive bladder afferents should be evaluated as possible targets for the pharmacological treatment of bladder hyperreflexia in patients with SCI.     

Identification of the axon pathways which mediate functional recovery of a paralyzed hemidiaphragm following spinal cord hemisection in the adult rat

Despite extensive neurophysiological work carried out to characterize the crossed phrenic phenomenon, relatively little is known about the morphological substrate of this reflex which restores function to a hemidiaphragm paralyzed by spinal cord injury. In the present study WGA-HRP was injected into normal and functionally recovered hemidiaphragm muscle in rats during the crossed phrenic phenomenon. The retrograde transynaptic transport characteristics of WGA-HRP was utilized to delineate the source of the neurons which mediate the crossed phrenic phenomenon. The results indicated that the neurons which drive phrenic motoneurons in spinal hemisected rats during the crossed phrenic phenomenon are located bilaterally in the rostral ventral respiratory group (rVRG) of the medulla. No transneuronal labeling of propriospinal neurons was noted in either normal or spinal-hemisected rats. Thus, propriospinal neurons do not relay respiratory drive to phrenic motoneurons. The neurons of the rVRG project monosynaptically to phrenic motoneurons. The present results suggest that both crossed and uncrossed bulbospinal pathways from the rVRG collateralize to both the left and right phrenic nucleic and functional recovery of a hemidiaphragm paralyzed by ipsilateral spinal cord hemisection is mediated by supraspinal neurons from both sides of the brain stem. These results are important to our complete understanding of the mechanisms which govern motor recovery in mammals following spinal cord injury.     

Conduction velocity in spinal descending pathways of baro- and chemoreceptor reflex

Activity in the white rami T3 and L2 or 3 has been recorded and averaged with respect to excitation of the carotid sinus baroreceptor afferents produced by the pulsatile blood pressure (baroreceptor reflex) and with respect to brief trains of electrical stimuli exciting low threshold chemoreceptor afferents in the left carotid sinus nerve (chemoreceptor reflex). Experiments were performed on chloralose anaesthetized cats with both vago-depressor nerves cut. From the latency difference between the onset of the responses at the thoracic and their arrival at the lumbar level the spinal conduction velocity for the pathway of each reflex has been calculated. The baroreceptor reflex pathway has slower spinal conduction velocity 3.3 +/- 0.7 m/sec than the chemoreceptor pathway 5.5 +/- 0.9 m/sec. These results indicate that there are separate descending spinal pathways for the two types of reflexes.     

On the Role of Galanin,Substance P and Other Neuropeptides in Primary Sensory Neurons of the Rat: Studies on Spinal Reflex Excitability and Peripheral Axotomy

The interaction of intrathecally (i.t.) applied galanin (GAL) with substance P (SP), calcitonin gene-related peptide (CGRP), vasoactive intestinal polypeptide (VIP), somatostatin (SOM) and C-fibre conditioning stimulation (CS) with regard to their effects on the spinal nociceptive flexor reflex was studied in decerebrate, spinalized, unanaesthetized rats with intact or sectioned sciatic nerves. SP, CGRP, VIP and SOM applied onto the surface of lumbar spinal cord or a brief CS train (1 Hz, 20 s) to the sural nerve facilitated the flexor reflex for several minutes in animals with intact or sectioned nerves. Pretreatment with GAL, which by itself had a biphasic effect on the flexor reflex in a dose-dependent manner, antagonized the reflex facilitation induced by sural CS before and after sciatic nerve section. SP-induced facilitation of the flexor reflex was antagonized by GAL in rats with intact sciatic nerves, but not after nerve section. In contrast, VIP-induced reflex facilitation was antagonized by GAL only after sectioning of the sciatic nerve. GAL was effective in antagonizing the facilitatory effect of CGRP under both situations, but had no effect on SOM-induced facilitation. A parallel immunohistochemical study revealed that after sciatic nerve section GAL-like immunoreactivity (LI) and VIP-LI are increased in the dorsal root ganglia and that these two peptides coexist in many cells. The present results indicate that GAL antagonizes the excitatory effect of some neuropeptides which exist in the spinal cord. This antagonism could explain the inhibitory effect of GAL on C-fibre CS-induced facilitation of the flexor reflex, which is presumably due to the release of some of these neuropeptides from the terminals of primary afferents. Furthermore, the interaction between GAL and other neuropeptides is altered by sciatic nerve section, paralleling changes in the levels of these neuropeptides in primary afferents and their pattern of coexistence after nerve section. It is proposed that SP and CGRP are important mediators of the spinal flexor reflex in intact rats. However, after axotomy VIP may replace SP in this capacity, paralleling the decrease in SP and marked increase in VIP levels. In general the study provides further support for involvement of peptides in sensory function.