Pharmacological and neuroanatomical evidence for the involvement of the anterior pretectal nucleus in the antinociception induced by stimulation of the dorsal raphe nucleus in rats

The role of the anterior pretectal nucleus in pain modulation: A comprehensive review

Descending pain modulation involves multiple encephalic sites and pathways that range from the cerebral cortex to the spinal cord. Behavioral studies conducted in the 1980s revealed that electrical stimulation of the pretectal area causes antinociception dissociation from aversive responses. Anatomical and physiological studies identified the anterior pretectal nucleus and its descending projections to several midbrain, pontine, and medullary structures. The anterior pretectal nucleus is morphologically divided into a dorsal part that contains a dense neuron population (pars compacta) and a ventral part that contains a dense fiber band network (pars reticulata). Connections of the two anterior pretectal nucleus parts are broad and include prominent projections to and from major encephalic systems associated with somatosensory processes. Since the first observation that acute or chronic noxious stimuli activate the anterior pretectal nucleus, it has been established that numerous mediators participate in this response through distinct pathways. Recent studies have confirmed that at least two pain inhibitory pathways are activated from the anterior pretectal nucleus. This review focuses on rodent anatomical, behavioral, molecular, and neurochemical data that have helped to identify mediators of the anterior pretectal nucleus and pathways related to its role in pain modulation.

The ventral portion of the anterior pretectal nucleus controls descending mechanisms that initiate neuropathic pain in rats

Stimulating the dorsal anterior pretectal nucleus (dAPtN) in rats is more effective than stimulating the ventral APtN (vAPtN) at reducing tail-flick latency, whereas stimulation of the vAPtN is more effective at reducing postoperative pain behaviour. This study examines whether a cell lesion caused by injecting N-methyl-D-aspartate into the dAPtN or vAPtN changes the withdrawal threshold of a rat hind paw during different phases of the tactile hypersensitivity induced by a chronic constriction injury (CCI) of the contralateral sciatic nerve. The number of Fos immunoreactive cells in the APtN was also evaluated. The rats whose vAPtN was lesioned 2 days before CCI had more intense tactile hypersensitivity 2 days after CCI than that of the control group, but the groups were not different 7 days after the CCI. The rats whose vAPtN was lesioned 5 days after CCI had withdrawal thresholds that did not differ significantly 7 days after the CCI. The tactile hypersensitivity of the rats whose dAPtN was lesioned 2 days before or 5 days after CCI was not different from that of the control on the second and seventh days after the CCI. The number of Fos immunoreactive cells in the vAPtN and dAPtN increased 2 days after CCI, but did not differ from that in the control 7 days after CCI. We conclude that vAPtN and dAPtN cells are activated by nerve injury; the vAPtN exerts inhibitory control of the initial phase of neuropathic pain whereas the dAPtN does not appear to exert an inhibitory effect in neuropathic processing.

Serotonergic neural links from the dorsal raphe nucleus modulate defensive behaviours organised by the dorsomedial hypothalamus and the elaboration of fear-induced antinociception via locus coeruleus pathways

Decrease of γ-aminobutyric acid (GABA)-mediated neurotransmission in the dorsomedial hypothalamus (DMH) evokes instinctive fear-like responses. The aim of the present study was to investigate the involvement of the serotonin (5-HT)- and norepinephrine-mediated pathways of the endogenous pain inhibitory system, including the dorsal raphe nucleus (DRN) and the locus coeruleus (LC), in the defensive responses and antinociceptive processes triggered by the blockade of GABAergic receptors in the DMH. The intra-hypothalamic microinjection of the GABA(A) receptor antagonist bicuculline (40 ng/200 nL) elicited elaborate defensive behaviours interspersed with exploratory responses. This escape behaviour was followed by significantly increased pain thresholds, a phenomenon known as fear-induced antinociception. Furthermore, at 5 and 14 days after DRN serotonin-containing neurons were damaged using the selective neurotoxin 5,7-dihydroxytryptamine (5,7-DHT), the frequency and duration of alertness and escape behaviour evoked by the GABA(A) receptor blockade in the DMH decreased, as well as fear-induced antinociception. Pre-treatment with the non-selective 5-HT receptor antagonist methysergide, the 5-HT(2A/2C) receptor antagonist ketanserin and the 5-HT(2A) receptor selective antagonist R-96544 in the LC also decreased fear-induced antinociception, without significant changes in the expression of defensive behaviours. These data suggest that the serotonergic neurons of the DRN are directly involved in the organisation of defensive responses as well as in the elaboration of the innate fear-induced antinociception. However, serotonin-mediated inputs from the NDR to the LC modulate only fear-induced antinociception and not the defensive behaviours evoked by GABA(A) receptor blockade in the DMH.

Paradoxical effect of noradrenaline-mediated neurotransmission in the antinociceptive phenomenon that accompanies tonic-clonic seizures: role of locus coeruleus neurons and α(2)- and β-noradrenergic receptors

The postictal state is generally followed by antinociception. It is known that connections between the dorsal raphe nucleus, the periaqueductal gray matter, and the locus coeruleus, an important noradrenergic brainstem nucleus, are involved in the descending control of ascending nociceptive pathways. The aim of the present study was to determine whether noradrenergic mechanisms in the locus coeruleus are involved in postictal antinociception. Yohimbine (an α(2)-receptor antagonist) or propranolol (a β-receptor antagonist) was microinjected unilaterally into the locus coeruleus, followed by intraperitoneal administration of pentylenetetrazole (PTZ), a noncompetitive antagonist that blocks GABA-mediated Cl(-) influx. Although the administration of both yohimbine and propranolol to the locus coeruleus/subcoeruleus area resulted in a significant decrease in tonic or tonic-clonic seizure-induced antinociception, the effect of yohimbine restricted to the locus coeruleus was more distinct compared with that of propranolol, possibly because of the presynaptic localization of α(2)-noradrenergic receptors in locus coeruleus neurons. These effects were related to the modulation of noradrenergic activity in the locus coeruleus. Interestingly, microinjections of noradrenaline into the locus coeruleus also decrease the postictal antinociception. The present results suggest that the mechanism underlying postictal antinociception involves both α(2)- and β-noradrenergic receptors in the locus coeruleus, although the action of noradrenaline on these receptors causes a paradoxical effect, depending on the nature of the local neurotransmission.

Abnormal anterior pretectal nucleus activity contributes to central pain syndrome

Central pain syndrome (CPS) is a debilitating condition that affects a large number of patients with a primary lesion or dysfunction in the CNS, most commonly due to spinal cord injury, stroke, and multiple sclerosis lesions. The pathophysiological processes underlying the development and maintenance of CPS are poorly understood. We have recently shown, in an animal model of CPS, that neurons in the posterior thalamic nucleus (PO) have increased spontaneous and evoked activity. We also demonstrated that these changes are due to suppressed inhibitory inputs from the zona incerta (ZI). The anterior pretectal nucleus (APT) is a diencephalic nucleus that projects on both the PO and ZI, suggesting that it might be involved in the pathophysiology of CPS. Here we test the hypothesis that CPS is associated with abnormal APT activity by recording single units from APT in anesthetized rats with CPS resulting from spinal cord lesions. The firing rate of APT neurons was increased in spinal-lesioned animals, compared with sham-operated controls. This increase was due to a selective increase in firing of tonic neurons that project to and inhibit ZI and an increase in bursts in fast bursting and slow rhythmic neurons. We also show that, in normal animals, suppressing APT results in increased PO spontaneous activity and evoked responses in a subpopulation of PO neurons. Taken together, these findings suggest that APT regulates ZI inputs to PO and that enhanced APT activity during CPS contributes to the abnormally high activity of PO neurons in CPS.

5-HT1A/1B, 5-HT6, and 5-HT7 serotonergic receptors recruitment in tonic-clonic seizure-induced antinociception: role of dorsal raphe nucleus

Pharmacological studies have been focused on the involvement of different neural pathways in the organization of antinociception that follows tonic-clonic seizures, including 5-hydroxytryptamine (5-HT)-, norepinephrine-, acetylcholine- and endogenous opioid peptide-mediated mechanisms, giving rise to more in-depth comprehension of this interesting post-ictal antinociceptive phenomenon. The present work investigated the involvement of 5-HT(1A/1B), 5-HT(6), and 5-HT(7) serotonergic receptors through peripheral pretreatment with methiothepin at doses of 0.5, 1.0, 2.0 and 3.0 mg/kg in the organization of the post-ictal antinociception elicited by pharmacologically (with pentylenetetrazole at 64 mg/kg)-induced tonic-clonic seizures. Methiothepin at 1.0 mg/kg blocked the post-ictal antinociception recorded after the end of seizures, whereas doses of 2.0 and 3.0 mg/kg potentiated the post-ictal antinociception. The nociceptive thresholds were kept higher than those of the control group. However, when the same 5-hydroxytryptamine receptors antagonist was microinjected (at 1.0, 3.0 and 5.0 microg/0.2 microL) in the dorsal raphe nucleus, a mesencephalic structure rich in serotonergic neurons and 5-HT receptors, the post-ictal hypo-analgesia was consistently antagonized. The present findings suggest a dual effect of methiothepin, characterized by a disinhibitory effect on the post-ictal antinociception when peripherally administered (possibly due to an antagonism of pre-synaptic 5-HT(1A) serotonergic autoreceptors in the pain endogenous inhibitory system) and an inhibitory effect (possibly due to a DRN post-synaptic 5-HT(1B), 5-HT(6), and 5-HT(7) serotonergic receptors blockade) when centrally administered. The present data also suggest that serotonin-mediated mechanisms of the dorsal raphe nucleus exert a key-role in the modulation of the post-ictal antinociception.

Small animal, whole brain fMRI: innocuous and nociceptive forepaw stimulation

Supra-spinal pain processing involves a number of extensive networks. An examination of these networks using small animal functional magnetic resonance imaging (fMRI) is difficult. While prior studies have successfully delineated regions consistent with known pain processing pathways, they have been restricted to acquisitions of limited spatial extent with coarse in-plane resolution to achieve a high temporal resolution. An isotropic, whole brain fMRI protocol has been developed for the examination of the supra-spinal consequences of innocuous and nociceptive electrical stimulation of the rat forepaw. Innocuous electrical stimulation of the rat forepaw delineated BOLD contrast responses consistent with known somatosensory processing pathways (contralateral primary somatosensory cortex (S1), a region consistent with secondary somatosensory cortex, the ventral posterolateral thalamic nucleus and ipsilateral cuneate nucleus), providing face validity for the technique. The putative noxious stimulus delineated additional regions consistent with the classical lateral and medial pain systems as well as secondarily associated areas: the aversion and descending inhibition systems. These included the ipsilateral inferior colliculus, anterior pretectal nucleus, mediodorsal thalamic nucleus, with regions in the pre-frontal, cingulated, ventral orbital and infra-limbic cortices, nucleus accumbens all exhibiting negative BOLD changes. Such regions are in agreement with, and extend, those previously reported. Acquisition, post-processing and analysis methodologies undertaken in this study constitute a marked extension of previous fMRI in the rat, enabling whole brain coverage at a spatial resolution sufficient to delineate regional changes in BOLD contrast consistent with somatosensory and nociceptive networks.

Involvement of 5-HT(2) serotonergic receptors of the nucleus raphe magnus and nucleus reticularis gigantocellularis/paragigantocellularis complex neural networks in the antinociceptive phenomenon that follows the post-ictal immobility syndrome

The post-ictal immobility syndrome is followed by a significant increase in the nociceptive thresholds in animals and men. In this interesting post-ictal behavioral response, endogenous opioid peptides-mediated mechanisms, as well as cholinergic-mediated antinociceptive processes, have been suggested. However, considering that many serotonergic descending pathways have been implicated in antinociceptive reactions, the aim of the present work is to investigate the involvement of 5-HT(2)-serotonergic receptor subfamily in the post-ictal antinociception. The analgesia was measured by the tail-flick test in seven or eight Wistar rats per group. Convulsions were followed by statistically significant increase in the tail-flick latencies (TFL), at least for 120 min of the post-ictal period. Male Wistar rats were submitted to stereotaxic surgery for introduction of a guide-cannula in the rhombencephalon, aiming either the nucleus raphe magnus (NRM) or the gigantocellularis complex. In independent groups of animals, these nuclei were neurochemically lesioned with a unilateral microinjection of ibotenic acid (1.0 microg/0.2 microL). The neuronal damage of either the NRM or nucleus reticularis gigantocellularis/paragigantocellularis complex decreased the post-ictal analgesia. Also, in other independent groups, central administration of ritanserin (5.0 microg/0.2 microL) or physiological saline into each of the reticular formation nuclei studied caused a statistically significant decrease in the TFL of seizing animals, as compared to controls, in all post-ictal periods studied. These results indicate that serotonin input-connected neurons of the pontine and medullarly reticular nuclei may be involved in the post-ictal analgesia.

Descriptive and functional neuroanatomy of locus coeruleus-noradrenaline-containing neurons involvement in bradykinin-induced antinociception on principal sensory trigeminal nucleus

The present study was carried out in Wistar rats, using the jaw-opening reflex and dental pulp stimulation, to investigate noradrenaline- and serotonin-mediated antinociceptive circuits. The effects of microinjections of bradykinin into the principal sensory trigeminal nucleus (PSTN) before and after neurochemical lesions of the locus coeruleus noradrenergic neurons were studied. Neuroanatomical experiments showed evidence for reciprocal neuronal pathways connecting the locus coeruleus (LC) to trigeminal sensory nuclei and linking monoaminergic nuclei of the pain inhibitory system to spinal trigeminal nucleus (STN). Fast blue (FB) injections in the locus coeruleus/subcoeruleus region retrogradely labeled neurons in the contralateral PSTN and LC. Microinjections of FB into the STN showed neurons labeled in both ipsilateral and contralateral LC, as well as in the ipsilateral Barrington's nucleus and subcoeruleus area. Retrograde tract-tracing with FB also showed that the mesencephalic trigeminal nucleus sends neural pathways towards the ipsilateral PSTN, with outputs from cranial and caudal aspects of the brainstem. In addition, neurons from the lateral and dorsolateral columns of periaqueductal gray matter also send outputs to the ipsilateral PSTN. Microinjections of FB in the interpolar and caudal divisions of the STN labeled neurons in the caudal subdivision of STN. Microinjections in the STN interpolar and caudal divisions also retrogradely labeled serotonin- and noradrenaline-containing nucleus of the brainstem pain inhibitory system. Finally, the gigantocellularis complex (nucleus reticularis gigantocellularis/paragigantocellularis), nucleus raphe magnus and nucleus raphe pallidus also projected to the caudal divisions of the STN. Microinjections of bradykinin in the PSTN caused a statistically significant long-lasting antinociception, antagonized by the damage of locus coeruleus-noradrenergic neuronal fibres with (N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine) (DSP4), a neurotoxin that specifically depleted noradrenaline from locus coeruleus terminal fields. These data suggest that serotonin- and noradrenaline-containing nuclei of the endogenous pain inhibitory system exert a key-role in the antinociceptive mechanisms of bradykinin and the locus coeruleus is crucially involved in this effect.

Neuroanatomical approaches of the tectum-reticular pathways and immunohistochemical evidence for serotonin-positive perikarya on neuronal substrates of the superior colliculus and periaqueductal gray matter involved in the elaboration of the defensive behavior and fear-induced analgesia

Deep layers of the superior colliculus, the dorsal periaqueductal gray matter and the inferior colliculus are midbrain structures involved in the generation of defensive behavior and fear-induced anti-nociception. Local injections of the GABA(A) antagonist bicuculline into these structures have been used to produce this defense reaction. Serotonin is thought to be the main neurotransmitter to modulate such defense reaction in mammals. This study is the first attempt to employ immunohistochemical techniques to locate serotonergic cells in the same midbrain sites from where defense reaction is evoked by chemical stimulation with bicuculline. The blockade of GABA(A) receptors in the neural substrates of the dorsal mesencephalon was followed by vigorous defensive reactions and increased nociceptive thresholds. Light microscopy immunocytochemistry with streptavidin method was used for the localization of the putative cells of defensive behavior with antibodies to serotonin in the rat's midbrain. Neurons positive to serotonin were found in the midbrain sites where defensive reactions were evoked by microinjection of bicuculline. Serotonin was localized to somata and projections of the neural networks of the mesencephalic tectum. Immunohistochemical studies showed that the sites in which neuronal perikarya positive to serotonin were identified in intermediate and deep layers of the superior colliculus, and in the dorsal and ventral columns of the periaqueductal gray matter are the same which were activated during the generation of defense behaviors, such as alertness, freezing, and escape reactions, induced by bicuculline. These findings support the contention that serotonin and GABAergic neurons may act in concert in the modulation of defense reaction in the midbrain tectum. Our neuroanatomical findings indicate a direct neural pathway connecting the dorsal midbrain and monoaminergic nuclei of the descending pain inhibitory system, with profuse synaptic terminals mainly in the pontine reticular formation, gigantocellularis nucleus, and nucleus raphe magnus. The midbrain tectum-gigantocellularis complex and midbrain tectum-nucleus raphe magnus neural pathways may provide an alternative output allowing the organization of the fear-induced anti-nociception by mesencephalic networks.

State-dependent effects of orexins on the serotonergic dorsal raphe neurons in the rat

The serotonergic dorsal raphe (DR) neurons play an important role in sleep-wakefulness regulation. Orexinergic neurons in the lateral hypothalamus densely project to the brainstem sites including the DR. To test the effects of orexins on the serotonergic DR neurons, we applied orexin A (0.1 mM) by pressure to these neurons in unanesthetized and urethane anesthetized rats. Orexin A caused excitation in 10 of 15 neurons under unanesthetized condition. The excitation was characterized by slow onset (0-18 s), long lasting duration (15-150 s) and state-dependency. Orexin A applied during REM sleep or slow wave sleep induced significant excitation while during wakefulness, the similar amount of orexin A did not increase the firing rate any more. In the anesthetized animals, orexin A induced excitation in four of eight neurons. The excitation had slow onset and was long lasting. These results suggest that orexinergic neurons exert excitatory influence on the serotonergic DR neurons to maintain tonic activity of them, thereby participating in regulation of sleep-wakefulness cycles and other functions.

Role of muscarinic and nicotinic cholinergic receptors in an experimental model of epilepsy-induced analgesia

The blockade of GABA-mediated Cl(-) influx with pentylenetetrazol (PTZ) was used in the present work to induce seizures in animals. The neurotransmission in the postictal period has been the focus of many studies, and there is evidence suggesting antinociceptive mechanisms following tonic-clonic seizures in both animals and men. The aim of this work was to study the involvement of acetylcholine in the antinociception induced by convulsions elicited by peripheral administration of PTZ (64 mg/kg). Analgesia was measured by the tail-flick test in eight albino Wistar rats per group. Convulsions were followed by significant increases in tail-flick latencies (TFLs) at least for 120 min of the postictal period. Peripheral administration of atropine (0.25, 1 and 4 mg/kg) caused a significant dose-dependent decrease in the TFL in seizing animals, as compared to controls. These data were corroborated by peripheral administration of mecamylamine, a nicotinic cholinergic receptor blocker, at the same doses (0.25, 1 and 4 mg/kg) used for the muscarinic cholinergic receptor antagonist. The recruitment of the muscarinic receptor was made 10 min postconvulsions and in subsequent periods of postictal analgesia, whereas the involvement of the nicotinic cholinergic receptor was implicated only after 30 min postseizures. The cholinergic antagonists caused a minimal reduction in body temperature, but did not impair baseline TFL, spontaneous exploration or motor coordination in the rotarod test at the maximal dose of 4 mg/kg. These results indicate that acetylcholine may be involved as a neurotransmitter in postictal analgesia.

Antinociception induced by stimulating the anterior pretectal nucleus in two models of pain in rats

1. This study examined whether different parts of the rat anterior pretectal nucleus (APtN) may be involved in the spinal control of brief (tail flick test) or persistent (surgical incision of the plantar aspect of a hind paw) noxious inputs via activation of descending pathways. 2. We have confirmed that stimulation of the dorsal APtN produces a strong antinociceptive effect in the tail flick test, as opposed to a very weak effect obtained from the ventral APtN. Stimulation at the ventral APtN was the most effective part of the nucleus against a persistent incisional pain. 3. The incisional pain was significantly increased following injection of 1 or 2% lignocaine (0.25 microL) into the nucleus, but the effect was more intense after neural block of the ventral rather than the dorsal APtN. Injection of 2% lignocaine (0.10 microL) into the ventral, but not dorsal, APtN significantly increased the perception of the incisional pain. 4. We conclude that the effect of stimulating the APtN depends on the site of stimulation and model of pain used. Sustained noxious stimuli activate pathways from the ventral APtN to reduce further noxious spinal inputs. The noxious stimulation produced during the tail flick test may be not enough to activate the same circuitry, but electrical stimulation at the dorsal APtN is very effective in inhibiting brief thermal noxious inputs at the spinal level.

Expression of c-Fos and NADPH-d after peripheral noxious stimulation in the pedunculopontine tegmental nucleus

The participation of pedunculopontine tegmental nucleus in descending pain control mechanisms has been proposed. The aim of this study was to investigate NADPH-d and c-Fos reactivity in the pedunculopontine tegmental nucleus following noxious peripheral stimulation. Formalin induced hind paw inflammation in the rat resulted in bilateral increase of Fos and NADPH-d expression in the pedunculopontine tegmental nucleus. Approximately 30% of labelled cells were double-labelled. Close proximity to NADPH-d labelled neuronal processes with Fos-labelled nuclei were observed. This anatomical relationship supports the hypothesis that pedunculopontine tegmental nucleus is involved in pain modulation and proposes a new explanation for the presence of nitric oxide in this nucleus.

Involvement of the anterior pretectal nucleus in the control of persistent pain: a behavioral and c-Fos expression study in the rat

The anterior pretectal nucleus (APtN) participates in nociceptive processing and in the activation of central descending mechanisms of pain control. In this study we used behavioral tests (incisional pain and carrageenan-induced inflammatory pain) and c-Fos expression changes to examine the involvement of the APtN in the control of persistent pain in rats. A 1cm longitudinal incision through the skin and fascia of the plantar region (large incision), or a 0.5cm longitudinal incision through the skin only (small incision) was used, and the postoperative incisional allodynia was evaluated with von Frey filaments. The hyperalgesia produced by the intraplantar administration of carrageenan (25 or 50 microg/100 microl) into a hind paw was evaluated by a modified paw pressure test. The electrolytic lesion of the contralateral, but not ipsilateral, APtN significantly intensified the allodynia produced by a large incision of the hind paw. The incisional allodynia and the carrageenan-induced hyperalgesia were intensified by the microinjection of 2% lidocaine into the contralateral, but not ipsilateral APtN, the effect being significantly stronger when a large incision or a higher carrageenan concentration was utilized. A significant increase in the number of c-Fos positive cells was found in the ipsilateral, and mainly in the contralateral APtN of rats submitted to a large incision. The number of positive cells in the superficial or deep laminae of the contralateral spinal cord of control and incised rats was not significantly different. Positive cells in the superficial or deep laminae of the ipsilateral spinal cord were significantly more numerous than in control, the effect being significantly more intense in rats with large incision. The microinjection of 0.5% bupivacaine into the APtN contralateral to the incised hind paw reduced the number of positive cells bilaterally in the APtN, but the effect was significant in the contralateral nucleus only. The number of positive cells in the superficial and deep laminae of the contralateral spinal cord of incised and non-incised animals was not significantly changed by the neural block of the contralateral APtN. In the ipsilateral spinal cord, the incision-induced increase in the number of positive cells was significantly reduced in the superficial lamina and significantly increased in the deep lamina of animals previously treated with bupivacaine in the contralateral APtN. In conclusion, the integrity of the APtN is necessary to reduce the severity of the responses to persistent injury. The results also are in agreement with the current notion that persistent noxious inputs to the APtN tonically activate a descending mechanism that excites superficial cells and inhibits deep cells in the spinal dorsal horn.

Inflammatory pain reduces correlated activity in the dorsal column nuclei

Persistent pain can result in sensitization of neurons in the spinal cord dorsal horn and produce physiological changes in sites such as the thalamus, that receive projections from the dorsal horn. Although the dorsal column nuclei receive both primary afferent input and projections from the dorsal horn, their participation in persistent pain states is relatively unexplored, perhaps because they play a limited role in acute, cutaneous nociception. We have used a model of inflammatory pain to examine the physiological properties of dorsal column nucleus neurons during persistent pain. We used this model in order to minimize direct damage to large myelinated primary afferents that project directly to the dorsal column nuclei. Inflammation was produced by injection of complete Freund's adjuvant into one hindpaw in rats, and neurons in the gracile nucleus were recorded 2-8 days later. Inflammation resulted in increased responsiveness to nociceptive (pinch) stimulation and increased incidence of afterdischarge firing 2-3 days after injection. Spontaneous activity was increased 6-8 days after injection. Inflammation decreased the strength of correlated firing in neuron pairs that shared common inputs, but did not affect the strength of monosynaptic interactions between neurons. These results suggest that the dorsal column nuclei can participate in persistent pain processes. Based on their anatomical connections, the dorsal column nuclei may contribute to thalamic changes during persistent pain as well as to supraspinal centers that modulate pain transmission in the spinal cord.

Post-ictal analgesia: involvement of opioid, serotoninergic and cholinergic mechanisms

The neural mechanisms involved in post-ictal analgesia remain to be elucidated. Pentylenetetrazol (PTZ) is used experimentally to induce seizure in animal subjects. This non-competitive antagonist blocks GABA-mediated Cl(-) flux. The aim of this work is to study the neurochemical basis of the antinociception induced by convulsions elicited by peripheral administration of PTZ (64 mg/kg). The analgesia was measured by the tail-flick test, in eight rats per group. Convulsions were followed by significant increase in the tail-flick latencies (TFL), at least for 30 min of the post-ictal period. Peripheral administration of naloxone (5 mg/kg and 10 mg/kg), atropine (1 mg/kg and 5 mg/kg), methysergide (1 mg/kg and 5 mg/kg) and ketanserine (1 mg/kg and 2 mg/kg) caused a significant decrease in the TFL in seizing animals, as compared to controls. However, while naloxone antagonized analgesia 15 and 25 min post convulsions, the other drugs caused a blockade of the post-ictal analgesia in a relatively greater period of time. These results indicate that endogenous opioids, serotonin and acetylcholine may be involved in post-ictal analgesia.

The anterior pretectal nucleus participates as a relay station in the glutamate-, but not morphine-induced antinociception from the dorsal raphe nucleus in rats

The anterior pretectal nucleus (APtN) and the dorsal raphe nucleus (DRN) are involved in descending pathways that control noxious inputs to the spinal cord and participate in the normal physiological response to noxious stimulation. Evidence has also been provided for the involvement of the APtN acting as a relay station through which the DRN partly modulates spinal nociceptive messages. In the present study, the effects of microinjecting glutamate or morphine into the DRN on the latency for the tail withdrawal reflex after noxious heating of the skin were examined in rats in which hyperbaric lidocaine (5%), naloxone (a non-selective opioid antagonist) or methiothepin (a non-selective 5-HT(1) antagonist) was previously microinjected into the APtN. Microinjection of glutamate (38 nmol/0.25 microl) into the DRN evoked strong but short-lasting antinociception that was fully inhibited by the previous administration of lidocaine (0.25 microl), naloxone (2.7 nmol/0.25 microl), or methiothepin (1 nmol/0.25 microl). A smaller dose of methiothepin (0.5 nmol/0.25 microl) significantly reduced the effect of glutamate. Microinjection of morphine (7.5 nmol/0.25 microl) into the DRN evoked strong and long-lasting antinociception that was not significantly changed by previous microinjection of lidocaine into the APtN. These results confirm that APtN integrity is at least in part necessary for the antinociceptive effects of stimulating the DRN, and that at least opioid and 5-HT1 mechanisms in the APtN participate as neuromodulators in the DRN-APtN connection. The results demonstrate that the antinociceptive effects of stimulating the DRN-APtN path depend on the activation of cell bodies in the DRN that can be excited by the local administration of glutamate, but not morphine. The study also further supports the notion that the DRN is involved in both descending and ascending pain inhibitory systems.

Synaptic contacts between serotonergic and cholinergic neurons in the rat dorsal raphe nucleus and laterodorsal tegmental nucleus

We examined synaptic connectivity between cholinergic and serotonergic neurons in the dorsal raphe nucleus and the laterodorsal tegmental nucleus of the rat. To this purpose we employed two variations (the combination of pre-embedding immunogold-silver intensification with avidin-biotin-peroxidase complex technique and the combination of avidin-biotin-peroxidase/3, 3'-diaminobenzidine/silver-gold intensification with avidin-biotin-peroxidase/3,3'-diaminobenzidine reaction) of a double pre-embedding immunoelectron procedure, using primary antibodies against vesicular acetylcholine transporter and serotonin. At the light-microscopic level, serotonin-like immunoreactive neurons in the dorsal raphe nucleus appeared as reddish black and vesicular acetylcholine transporter-like immunoreactive axon terminals were brown colored using a combination of pre-embedding immunogold-silver technique and avidin-biotin-peroxidase complex technique. Serotonin-like immunoreactive fibers projected to the laterodorsal tegmental nucleus. At the electron microscopy level, with both methods we observed in the dorsal raphe nucleus vesicular acetylcholine transporter-immunopositive axon terminals in synaptic contact with serotonin-like immunoreactive dendrites and, to a lesser degree, with serotonin-like immunoreactive cell bodies. These synapses usually were of the symmetrical type. Occasionally we noted, next to vesicular acetylcholine transporter-immunopositive axon terminals, also immunonegative terminals synapsing with the serotonin-like immunoreactive dendrites. In the laterodorsal tegmental nucleus we found serotonin-like immunoreactive axon terminals and immunonegative terminals forming synapses with vesicular acetylcholine transporter-immunoreactive dendrites. Most synapses formed by the serotonin-like immunopositive terminals were of the asymmetrical type. Our results suggest that serotonergic neurons in the dorsal raphe nucleus and cholinergic neurons in the laterodorsal tegmental nucleus may reciprocally influence each other by means of synaptic connectivity. Such connectivity may serve to regulate pain sensation, or be involved in the regulation of the sleeping-waking cycle.