The effects of 4-aminopyridine on the cat spinal cord: rhythmic antidromic discharges recorded from the dorsal roots

Emergent epileptiform activity in spinal sensory circuits drives ectopic bursting in afferent axons and sensory dysfunction after cord injury

ABSTRACT

Spinal cord injury leads to hyperexcitability and dysfunction in spinal sensory processing. As hyperexcitable circuits can become epileptiform, we explored whether such activity emerges in a thoracic spinal cord injury (SCI) contusion model of neuropathic pain. Recordings from spinal sensory axons in multiple below-lesion segmental dorsal roots demonstrated that SCI facilitated the emergence of spontaneous ectopic burst spiking in afferent axons, which were correlated across multiple adjacent dorsal roots. Burst frequency correlated with behavioral mechanosensitivity. The same bursting events were recruited by afferent stimulation, and timing interactions with ongoing spontaneous bursts revealed that recruitment was limited by a prolonged post-burst refractory period. Ectopic bursting in afferent axons was driven by GABA A receptor activation, presumably by conversion of subthreshold GABAergic interneuronal presynaptic axoaxonic inhibitory actions to suprathreshold spiking. Collectively, the emergence of stereotyped bursting circuitry with hypersynchrony, sensory input activation, post-burst refractory period, and reorganization of connectivity represent defining features of an epileptiform network. Indeed, these same features were reproduced in naive animals with the convulsant 4-aminopyridine (fampridine). We conclude that spinal cord injury promotes the emergence of epileptiform activity in spinal sensory networks that promote profound corruption of sensory signaling. This includes hyperexcitability and bursting by ectopic spiking in afferent axons that propagate bidirectionally by reentrant central and peripheral projections as well as sensory circuit hypoexcitability during the burst refractory period. More broadly, the work links circuit hyperexcitability to epileptiform circuit emergence, further strengthening it as a conceptual basis to understand features of sensory dysfunction and neuropathic pain.

Emergent epileptiform activity drives spinal sensory circuits to generate ectopic bursting in intraspinal afferent axons after cord injury

Spinal cord injury ( SCI ) leads to hyperexcitability and dysfunction in spinal sensory processing. As hyperexcitable circuits can become epileptiform elsewhere, we explored whether such activity emerges in spinal sensory circuits in a thoracic SCI contusion model of neuropathic pain. Recordings from spinal sensory axons in multiple below-lesion segmental dorsal roots ( DRs ) demonstrated that SCI facilitated the emergence of spontaneous ectopic burst spiking in afferent axons, which synchronized across multiple adjacent DRs. Burst frequency correlated with behavioral mechanosensitivity. The same bursting events were recruited by afferent stimulation, and timing interactions with ongoing spontaneous bursts revealed that recruitment was limited by a prolonged post-burst refractory period. Ectopic bursting in afferent axons was driven by GABA A receptor activation, presumably via shifting subthreshold GABAergic interneuronal presynaptic axoaxonic inhibitory actions to suprathreshold spiking. Collectively, the emergence of stereotyped bursting circuitry with hypersynchrony, sensory input activation, post-burst refractory period, and reorganization of connectivity represent defining features of epileptiform networks. Indeed, these same features were reproduced in naïve animals with the convulsant 4-aminopyridine ( 4-AP ). We conclude that SCI promotes the emergence of epileptiform activity in spinal sensory networks that promotes profound corruption of sensory signaling. This corruption includes downstream actions driven by ectopic afferent bursts that propagate via reentrant central and peripheral projections and GABAergic presynaptic circuit hypoexcitability during the refractory period.

Neonatal Mice Spinal Cord Interneurons Send Axons through the Dorsal Roots

Spontaneous interneuron activity plays a critical role in developing neuronal networks. Discharges conducted antidromically along the dorsal root (DR) precede those from the ventral root’s (VR) motoneurons. This work studied whether spinal interneurons project axons into the neonate’s dorsal roots. Experiments were carried out in postnatal Swiss-Webster mice. We utilized a staining technique and found that interneurons in the spinal cord’s dorsal horn send axons through the dorsal roots. In vitro electrophysiological recordings showed antidromic action potentials (dorsal root reflex; DRR) produced by depolarizing the primary afferent terminals. These reflexes appeared by stimulating the adjacent dorsal roots. We found that bicuculline reduced the DRR evoked by L5 dorsal root stimulation when recording from the L4 dorsal root. Simultaneously, the monosynaptic reflex (MR) in the L5 ventral root was not affected; nevertheless, a long-lasting after-discharge appeared. The addition of 2-amino-5 phosphonovaleric acid (AP5), an NMDA receptor antagonist, abolished the MR without changing the after-discharge. The absence of DRR and MR facilitated single action potentials in the dorsal and ventral roots that persisted even in low Ca2+ concentrations. The results suggest that firing interneurons could send their axons through the dorsal roots. These interneurons could activate motoneurons producing individual spikes recorded in the ventral roots. Identifying these interneurons and the persistence of their neuronal connectivity in adulthood remains to be established.

Extrasynaptic α5GABAA receptors on proprioceptive afferents produce a tonic depolarization that modulates sodium channel function in the rat spinal cord

Activation of GABA_A receptors on sensory axons produces a primary afferent depolarization (PAD) that modulates sensory transmission in the spinal cord. While axoaxonic synaptic contacts of GABAergic interneurons onto afferent terminals have been extensively studied, less is known about the function of extrasynaptic GABA receptors on afferents. Thus, we examined extrasynaptic α₅GABA_A receptors on low-threshold proprioceptive (group Ia) and cutaneous afferents. Afferents were impaled with intracellular electrodes and filled with neurobiotin in the sacrocaudal spinal cord of rats. Confocal microscopy was used to reconstruct the afferents and locate immunolabelled α₅GABA_A receptors. In all afferents α₅GABA_A receptors were found throughout the extensive central axon arbors. They were most densely located at branch points near sodium channel nodes, including in the dorsal horn. Unexpectedly, proprioceptive afferent terminals on motoneurons had a relative lack of α₅GABA_A receptors. When recording intracellularly from these afferents, blocking α₅GABA_A receptors (with L655708, gabazine, or bicuculline) hyperpolarized the afferents, as did blocking neuronal activity with tetrodotoxin, indicating a tonic GABA tone and tonic PAD. This tonic PAD was increased by repeatedly stimulating the dorsal root at low rates and remained elevated for many seconds after the stimulation. It is puzzling that tonic PAD arises from α₅GABA_A receptors located far from the afferent terminal where they can have relatively little effect on terminal presynaptic inhibition. However, consistent with the nodal location of α₅GABA_A receptors, we find tonic PAD helps produce sodium spikes that propagate antidromically out the dorsal roots, and we suggest that it may well be involved in assisting spike transmission in general. NEW & NOTEWORTHY GABAergic neurons are well known to form synaptic contacts on proprioceptive afferent terminals innervating motoneurons and to cause presynaptic inhibition. However, the particular GABA receptors involved are unknown. Here, we examined the distribution of extrasynaptic α₅GABA_A receptors on proprioceptive Ia afferents. Unexpectedly, these receptors were found preferentially near nodal sodium channels throughout the afferent and were largely absent from afferent terminals. These receptors produced a tonic afferent depolarization that modulated sodium spikes, consistent with their location.

Network-based activity induced by 4-aminopyridine in rat dorsal horn in vitro is mediated by both chemical and electrical synapses

This study investigated the role of electrical and chemical synapses in sustaining 4-aminopyridine (4-AP)-evoked network activity recorded extracellularly from substantia gelatinosa (SG) of young rat spinal cord in vitro. Superfusion of 4-AP (50 microM) induced two types of activity, the first was observed as large amplitude field population spiking activity and the second manifested within the inter-spike interval as low amplitude rhythmic oscillations in the 4-12 Hz frequency range (mean peak of 8.0 +/- 0.1 Hz). The AMPA/kainate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM) abolished field population spiking and disrupted 4-12 Hz rhythmic oscillatory activity whereas the NMDA receptor antagonist D-AP5 (50 microM) had no significant effect on either activity component. The glycine receptor antagonist strychnine (4 microM) and the GABA(A) receptor antagonist bicuculline (10 microM) diminished and abolished, respectively, field population spiking and both antagonists reduced the power of 4-12 Hz oscillations. The non-specific gap junction blockers carbenoxolone (100 microM) and octanol (1 mM) attenuated both types of 4-AP-induced activity. By comparison, the neuronal-specific gap junction uncouplers quinine (250 microM) and mefloquine (500 nM) both disrupted 4-12 Hz oscillations but only quinine reduced the frequency of field population spiking. These data demonstrate the existence of 4-AP-sensitive neuronal networks within SG that can generate rhythmic activity, are differentially modulated by excitatory and inhibitory ionotropic neurotransmission and are at least partly reliant on neuronal and/or glial-mediated electrical connectivity. The physiological significance of these putative intrinsic SG networks and the implications in the context of processing of nociceptive inputs are discussed.

Characteristics of the electrical oscillations evoked by 4-aminopyridine on dorsal root fibers and their relation to fictive locomotor patterns in the rat spinal cord in vitro

4-Aminopyridine (4-AP) is suggested to improve symptomatology of spinal injury patients because it may facilitate neuromuscular transmission, spinal impulse flow and the operation of the locomotor central pattern generator (CPG). Since 4-AP can also induce repetitive discharges from dorsal root afferents, this phenomenon might interfere with sensory signals necessary to modulate CPG activity. Using electrophysiological recording from dorsal and ventral roots of the rat isolated spinal cord, we investigated 4-AP-evoked discharges and their relation with fictive locomotor patterns. On dorsal roots 4-AP (5-10 microM) induced sustained synchronous oscillations (3.3+/-0.8 s period) smaller than electrically evoked synaptic potentials, persistent after sectioning off the ventral region and preserved in an isolated dorsal quadrant, indicating their dorsal horn origin. 4-AP oscillations were blocked by tetrodotoxin, or 6-cyano-7-nitroquinoxaline-2,3-dione and d-amino-phosphonovalerate, or strychnine and bicuculline, suggesting they were network mediated via glutamatergic, glycinergic and GABAergic transmission. Isolated ventral horn areas could not generated 4-AP oscillations, although their intrinsic disinhibited bursting was accelerated by 4-AP. Thus, ventral horn areas contained 4-AP sensitive sites, yet lacked the network for 4-AP induced oscillations. Activation of fictive locomotion by either application of N-methyl-D-aspartate and serotonin or stimulus trains to a single dorsal root reversibly suppressed dorsal root oscillations induced by 4-AP. This suppression was due to depression of dorsal network activity rather than simple block of root discharges. Since dorsal root oscillations evoked by 4-AP were turned off when the fictive locomotor program was initiated, these discharges are unlikely to interfere with proprioceptive signals during locomotor training in spinal patients.

Epileptiform activity in rat spinal dorsal horn in vitro has common features with neuropathic pain

Neuropathic pain and epileptic seizures bear several similarities, among them is the response to anticonvulsant drugs. It has therefore been hypothesized that epileptiform activity of nociceptive spinal dorsal horn neurons may contribute to paroxysmal forms of neuropathic pain. We used patch-clamp and field potential recordings from young rat spinal cord slices to test if nociceptive dorsal horn structures are indeed able to sustain epileptiform activity. Application of the convulsant 4-aminopyridine (100 microM) evoked epileptiform activity that was most pronounced in superficial dorsal horn and involved nociceptive lamina I neurons with a projection to the brain. The epileptiform activity was dependent on fast excitatory and inhibitory synaptic transmission through ionotropic glutamate receptors and GABA(A) receptors. During epileptiform activity, previously silent polysynaptic pathways from primary afferent C-fibers to superficial dorsal horn neurons were opened. Stimulation of primary afferents at Adelta- and C-fiber intensity interfered with the epileptiform rhythm, suggesting that both affect the same dorsal horn structures. Similar to neuropathic pain, spinal dorsal horn epileptiform activity was much less reduced by classical analgesics than by anticonvulsant agents.

GABA-dependent generation of ectopic action potentials in the rat hippocampus

Intracellular recordings from CA3 pyramidal cells of rat hippocampus in a slice preparation revealed the occurrence of interictal epileptiform discharges and synchronous GABA-mediated potentials during application of 4-aminopyridine (4AP, 50 micrometer). The synchronous GABA-mediated potential consisted of a sequence of early hyperpolarization, long-lasting depolarization (LLD), and late hyperpolarization. Action potentials of variable amplitude occurred at the peak of the early hyperpolarization and during the LLD rising phase (48 of 64 cells); they were not prevented by membrane hyperpolarization and displayed inflections that were reminiscent of the initial segment-somatodendritic (IS-SD) fractionation. Interictal discharges were blocked by excitatory amino acid receptor antagonists, while both GABA-mediated potentials and action potentials of variable amplitude continued to occur (n = 10). The latter events were still recorded in the presence of the GABAB receptor antagonist CGP-35348 (0.5-1 mm, n = 4), but were abolished by the GABAA receptor antagonist bicuculline methiodide (BMI, 10 micrometer, n = 5). Localized application of BMI (20 micrometer, n = 6) or tetrodotoxin (TTX, 5 micrometer, n = 3) to the CA1 stratum radiatum blocked the variable amplitude action potentials; these effects were not seen when BMI (n = 4) or TTX (n = 4) were applied to the CA3 stratum radiatum, although both procedures made LLDs disappear. Our findings indicate that action potentials of variable amplitude recorded from CA3 pyramidal cells in the 4AP model are generated at or near the terminal region of the Schaffer collaterals and that they represent TTX-sensitive ectopic events. These action potentials are generated at this site by a BMI-sensitive (and thus GABAA-mediated) mechanism. We propose that the ectopic action potentials reflect an increased excitability of axon terminals that is presumably caused by [K+]o elevations associated with the 4AP-induced synchronous GABA-mediated potential.

Excitation of central and peripheral terminals of primary afferent neurons by capsaicin in vivo

In three groups of rats discharge activity was recorded (i) from the peripheral stump of the cut saphenous nerve (saphenous-receptor preparation); (ii) from the central stump of the cut L4 or L5 dorsal root (dorsal root preparation); or (iii) from the peripheral stump of the saphenous nerve segment cut at both ends (axon preparation) during slow intraarterial infusion of capsaicin (30-300 micrograms/kg/min for 5 min) into the carotid artery. Capsaicin produced excitation, i.e. an increase in frequency of action potentials in the same dose range (100-300 micrograms/kg/min) in both the saphenous-receptor and dorsal root preparations, while the axon preparations remained unresponsive. In the cat, close arterial injection of capsaicin (up to 20 micrograms) into a collateral branch of the saphenous artery failed to evoke discharges in the saphenous axon preparation, although similar injection of 4-aminopyridine (60 micrograms), a K+ channel blocking agent was readily effective. These results indicate that after systemic application of capsaicin the peripheral and central endings of primary afferent neurons are equally important sites for activation and are much more sensitive to capsaicin than the axons of the nerve trunk.

Toxin I, but not 4-aminopyridine, blocks the late inhibitory component of the dorsal root reflex in an isolated preparation of rat spinal cord

Bursts of spontaneous antidromic dorsal root action potentials, and evoked dorsal root reflexes (DRR), have been recorded from lumbar roots of isolated spinal cord preparations of rats weighing 70-90 g. The pattern of dorsal root activity was similar to that reported for isolated cord preparations from hamsters, but the frequency of spontaneous dorsal root activity was approximately 10 times slower in the rat. Toxin I and 4-aminopyridine (4-AP) both increased the frequency of spontaneous dorsal root activity. The threshold concentration of 4-AP was 1 microM, with EC50 at 20 microM. Insufficient Toxin I was available to reach a maximal response, but the threshold concentration for producing an increase in spontaneous activity was 0.1 microM, and the curve appeared to be parallel to that of 4-AP. The patterns of spontaneous dorsal root activity in the presence of 4-AP and Toxin I differed. In 4-AP bursts of large amplitude action potentials were followed by periods of depressed activity lasting up to 500 ms, whereas in Toxin I bursts of large amplitude action potentials caused no change in the continuously firing small amplitude action potentials. DRR evoked by stimulation of adjacent dorsal roots also showed differences in the presence of 4-AP and Toxin I. In 4-AP the excitatory phase of the reflex was followed by a period of depressed activity lasting up to 500 ms. This was was reduced or absent in the presence of Toxin I. Paired pulse stimulation confirmed the presence of inhibition in 4-AP, and its reduction in Toxin I. Examination of the pattern of spontaneous dorsal root activity following dorsal root stimulation showed strong oscillatory activity in the presence of 4-AP, but little such activity in the presence of Toxin I. It was concluded that the actions of 4-AP and Toxin I on the isolated preparation of rat spinal cord are similar in that both cause an increase in the spontaneous dorsal root firing rate, but that Toxin I also blocks the period of inhibition which follows bursts of large amplitude action potentials.

Effects of stimulating the reticular formation during fictive locomotion in lampreys

The effects of stimulating the reticular formation were studied during fictive locomotion in lampreys (Ichthyomyzon unicuspis). The in vitro isolated preparation of the brainstem and spinal cord was used and fictive locomotion was induced by bath application of N-methyl-D-aspartate (NMDA; 50-100 microM). During different phases of the locomotor cycle, short trains of stimuli (10 pulses at 80-100 Hz; 10 microA) were delivered through glass-coated tungsten microelectrodes positioned within the middle rhombencephalic reticular nucleus (MRRN) and their effects were studied on ipsi- and contralateral ventral root locomotor discharges. Irrespective of the locomotor phase during which the stimulation train was delivered, a resetting effect occurred. It was characterized by a re-synchronization of the locomotor discharges with a constant latency for each ventral root on the ipsilateral side. The latency increased as the recorded root was located further caudally. This increase in latency was in the range of the phase lag observed between roots during control bouts of locomotion. These results suggest that reticulospinal neurones exert strong resetting effects on spinal locomotor networks. These effects may play a significant role with respect to changes of direction during swimming.

Effects of 4-aminopyridine on motor evoked potentials in patients with spinal cord injury

The potassium (K+) channel-blocking agent 4-aminopyridine (4-AP) is currently being investigated for its potential therapeutic value in patients with spinal cord injury (SCI). The present study was designed to test the hypothesis that 4-AP ameliorates central motor conduction deficits in individuals with SCI. Oral 4-AP (10 mg) was administered to 19 (n = 19) SCI subjects with stable neurological deficits. Their response to the drug was monitored using motor evoked potentials (MEPs) following transcranial magnetic stimulation of motor cortex and various measures of segmental or peripheral reflex activity (F-waves, H-reflex, and M-response) recorded from lower limb muscles. The mean MEP amplitude in the extensor digitorum brevis muscle (left) was significantly (p < .05) increased from x = .25 +/- .42 mV to x = .59 +/- 1.04 mV at 2 h after drug administration, and the cortical stimulation threshold was reduced (p < .05) by 5.8%. Similar results were obtained in all subjects exhibiting MEPs (n = 13) and in all muscles (n = 6) studied. These changes were maintained at 4 h postdrug. MEP latencies were reduced in all subjects who initially exhibited abnormally prolonged MEP latencies relative to control group (n = 13) values. F-wave, H-reflex, and M-response values (latency and amplitude) were not systematically altered by 4-AP, leading to the conclusion that it was central motor conduction that was enhanced. This interpretation was supported by observed reductions in central motor conduction time (CMCT) in the majority of SCI subjects from whom CMCT measurements were obtained, two of whom anecdotally reported improved motor control after 4-AP, and by increased MEP:M-wave amplitude ratios. The MEP:M-wave ratios indicated that the magnitude of the effect of 4-AP on motoneuron recruitment was not large, in absolute terms (<4% motoneuron pool), but was appreciable relative to the initial level of motoneuron recruitment. These results provide the first statistically significant, objective evidence of improved functioning of the neuromuscular system in chronically injured SCI subjects receiving 4-AP and suggest that the improvements are mediated through enhanced central conduction. The results further support the emerging view that pharmaceutical management of central conduction deficits may prove to be a useful therapeutic strategy for some patients with long-standing SCI.

Spontaneous synchronized neural activity in decerebrate gallamine-paralysed cats

In decerebrate cats paralysed with gallamine, over a period of several days there develops a remarkable synchronization of discharge in widely different motor nerves throughout the body, including intercostal nerves and limb nerves. These discharges are also in synchrony with slow waves approximately 100 ms in duration in the inferior olive. The slow waves and discharges are at first irregular and only weakly synchronized, but become increasingly strongly synchronized and by about the fourth day exhibit a strong 6-8 Hz rhythm. The degree of synchronization is greater the lower the end-tidal CO2 concentration. Transection of the spinal cord at a high cervical level breaks the synchrony and may abolish the discharge in the nerves, but the slow waves in the inferior olive continue rhythmically. It was shown, however, that gallamine injected subdurally at cervical vertebra 7 or lumbar vertebra 7 has a direct excitatory action on the spinal cord. Slow waves in the inferior olive are elicited by gallamine in the decerebrate, spinalized and decerebellectomized cat, and therefore must originate in the brainstem. Gallamine is known to act directly on olivary neurons and the slow waves may originate in the inferior olive, but further experiments are needed to determine what other structures it affects. The condition of the cat a few days after decerebration and paralysis resembles the clinical condition of reticular reflex myoclonus and it is suggested that the genesis of the myoclonus may be similar in the two conditions.

Backpropagation of action potentials generated at ectopic axonal loci: hypothesis that axon terminals integrate local environmental signals

This review deals with the fascinating complexity of presynaptic axon terminals that are characterized by a high degree of functional distinctiveness. In vertebrate and invertebrate neurons, all-or-none APs can take off not only from the axon hillock, but also from ectopic axonal loci including terminals. Invertebrate neurons display EAPs, for instance alternating with somatic APs, during survival functions. In vertebrate, EAPs have been recorded in the peripheral and central nervous systems in time relationship with physiological or pathological neuronal activities. In motor or sensory axon, EAP generation may be the cause of motor dysfunctioning or sensory perceptions and pain respectively. Locomotion is associated with rhythmic depolarizations of the presynaptic axonal membrane of primary afferents, which are ridden by robust EAP bursts. In central axons lying within an epileptic tissue EAP discharges, coinciding with paroxysmal ECoG waves, get longer as somatic discharges get shorter during seizure progression. Once invaded by an orthodromic burst, an ectopic axonal locus can display an EAP after discharge. Such loci can also fire during hyperpolarization or the postinhibitory excitatory period of the parent somata, but not during their tonic excitation. Neurons are thus endowed with electrophysiological intrinsic properties making possible the alternate discharges of somatic APs and EAPs. In invertebrate and vertebrate neurons, ectopic axonal loci fire while the parent somata stop firing, further suggesting that axon terminal networks are unique and individual functional entities. The functional importance of EAPs in the nervous systems is, however, not yet well understood. Ectopically generated axonal APs propagate backwards and forwards along the axon, thus acting as a retrograde and anterograde signal. In invertebrate neurons, somatically and ectopically generated APs cannot have the same effect on the postsynaptic membrane. As suggested by studies related to the dorsal root reflex, EAPs may not only be implied in the presynaptic modulation of transmitter release but also contribute significantly during their backpropagation to a powerful control (collision process) of incoming volleys. From experimental data related to epileptiform activities it is proposed that EAPs, once orthodromically conducted, might potentiate synapses, initiate, spread or maintain epileptic cellular processes. For instance, paroxysmal discharges of EAPs would exert, like a booster-driver, a powerful synchronizing synaptic drive upon a large number of excitatory and inhibitory postsynaptic neurons. We have proposed that, once backpropagated, EAPs are likewise capable of initiating (and anticipating) threshold and low-threshold somatodendritic depolarizations. Interestingly, an antidromic EAP can modulate the excitability of the parent soma.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification and characterization of rhythmic nociceptive and non-nociceptive spinal dorsal horn neurons in the rat

The properties of rhythmic low-threshold and multireceptive spinal dorsal horn neurons were determined. Multiple neuron recordings were made via a single electrode in the lumbar spinal cord of pentobarbital-anesthetized or decerebrate, unanesthetized, spinalized rats. The background activity of a total of 223 neurons was analysed: 21.0% of 176 fully characterized neurons were low threshold, 73.3% multireceptive and 5.7% nociceptive-specific neurons. Twenty of 100 neurons tested were driven by antidromic stimulation at the upper cervical cord. To identify and evaluate rhythmic harmonic oscillations in the discharges of spinal dorsal horn neurons during background activity and steady-state noxious heat-evoked responses, interspike interval, autocorrelation and autospectral analysis were performed. The background activity of 99 of the 223 neurons (44.4%) of our sample was rhythmic. The distribution of the fundamental spectral frequencies has a bimodal shape, the first band between 0.5 and 2 Hz and the second between 6 and 13 Hz. Low-threshold and multireceptive neurons had a similar incidence of rhythmicity (54.1 and 43.4%, respectively). Only one of 20 neurons with long ascending projections presented rhythmic background activity. Activation of heat-sensitive nociceptors within the cutaneous receptive fields of the neurons had a strong anti-rhythmic effect in nine of 15 (60%) neurons. No change was observed in the pattern of autospectra of non-rhythmic neurons or low-threshold neurons during noxious stimulation. Twenty-four of 37 (66.6%) rhythmic neurons retained their rhythmic background discharges during reversible cold-block spinalization at the upper thoracic cord. The incidence of neurons with burst-like discharges was highest among multireceptive neurons (98/129, 75.9%) and non-rhythmic neurons (89/124, 71.8%). Thus, rhythmicity exists in sensory neurons of the spinal dorsal horn probably generated within its local neuronal network and partially modulated by supraspinal descending systems. Rhythmicity is depressed by activity in primary afferent nociceptors. The role of rhythmicity for information transfer and neuronal plasticity is discussed.

Pattern of irregular dorsal root discharge in the spinal cat

Pattern of irregular type of dorsal root discharge (DRD) in non-anaesthetized spinal cats was inferred from the distribution of its interspike intervals. Interspike interval histograms were compiled from antidromic spike potentials of irregular DRD which were recorded in the central ends of 33 single dorsal root fibres of L7 dorsal root. The majority of histograms was unimodal. The mean preferred interval of irregular DRD which indicated the most frequently occurring interspike interval was 6.1 +/- 0.5 ms. The shortest and longest intervals were 3.7 +/- 0.3 ms and 45.9 +/- 4.4 ms, respectively. The coefficient of symmetry of the histogram was 0.06, indicating highly unsymmetrical distribution of intervals of irregular DRD. Conduction velocity of dorsal root fibres carrying irregular antidromic discharge amounted to 52.3 +/- 5.3 m/s (n = 23). There were no significant correlations between three analysed interspike intervals and conduction velocity. The results are discussed in view of the hypothesis of the modulating effect of antidromic discharge on the afferent inflow. Comparison of preferred interspike interval of irregular DRD with the existing data on the rate of orthodromic activity in afferent nerve fibres suggests that irregular antidromic discharge on many occasions is able to block othodromic impulses by collision.

Unitary discharges in dorsal and ventral roots after the administration of 4-aminopyridine in the cat

The administration of 4-aminopyridine (4-AP) in decerebrate paralyzed cats induces centrifugal rhythmic discharges in both ventral and dorsal roots. This study describes the mode of discharge of individual primary afferents as well as some ventral root fibers. Several patterns of antidromic discharge have been observed in primary afferents after the administration of 4-AP. A large proportion of the units (n = 96; 53%) showed rhythmic bursts of discharge related (n = 41) or not (n = 55) to the ongoing rhythmic activity in the peripheral nerves. Other units (n = 86; 47%) discharged either tonically, sporadically or had no antidromic activity at all. The conduction velocity of the non-bursting units was significantly higher (89.7 +/- 18.4 m/s) than that of the bursting units (70.6 +/- 15.4 m/s; P less than 0.01). Ventral roots showed rhythmic activity although less intense than that of the dorsal roots. As in dorsal roots, some fibers showed a rhythmical pattern of discharge related to the mass activity recorded from whole dorsal roots or peripheral nerves, while other units were not related. It is concluded that bursting activity which occurs in peripheral nerves after the administration of 4-AP is mainly the result of the antidromic activation of medium to small size primary afferent fibers.