Activation of peripheral cannabinoid CB1 receptors inhibits mechanically evoked responses of spinal neurons in noninflamed rats and rats with hindpaw inflammation

The presence of cannabinoid1 (CB1) receptors on primary afferent fibres may provide a novel target for cannabinoid analgesics. The present study investigated the ability of peripheral CB1 receptors to modulate innocuous and noxious transmission in noninflamed rats and rats with peripheral carrageenan inflammation. Effects of peripheral injection of arachidonyl-2-choroethylamide (ACEA; 10 and 30 micro g in 50 micro L), a selective CB1 receptor agonist, on mechanically evoked responses of dorsal horn neurons were studied in noninflamed rats and rats with peripheral carrageenan inflammation. Peripheral injection of ACEA (30 micro g in 50 micro L) significantly inhibited innocuous (12 g) mechanically evoked responses of spinal neurons in noninflamed (27 +/- 4% of control; P < 0.01) and inflamed (12 +/- 8% of control; P < 0.05) rats. Similarly, noxious (80 g) mechanically evoked responses of spinal neurons were inhibited by peripheral injection of ACEA (30 micro g in 50 micro L) in noninflamed rats (51 +/- 9% of control; P < 0.01) and rats with peripheral carrageenan inflammation (21 +/- 8% of control; P < 0.01). Inhibitory effects of ACEA were significantly greater in rats with peripheral carrageenan inflammation than in noninflamed rats (P < 0.05). Inhibitory effects of ACEA were significantly blocked by coadministration of the CB1 receptor antagonist SR141716A in both groups of rats. Peripheral injection of SR141716A alone did not alter mechanically evoked responses of spinal neurons in either group of rats. These data demonstrate that activation of peripheral CB1 receptors can inhibit innocuous and noxious somatosensory processing. Furthermore, following peripheral inflammation there is an enhanced inhibitory effect of a peripherally administered CB1 receptor agonist on both innocuous and noxious mechanically evoked responses of spinal neurons.     

Spinal anandamide inhibits nociceptive transmission via cannabinoid receptor activation in vivo

The endocannabinoid anandamide has affinity for cannabinoid and vanilloid receptors, which have opposing effects on nociceptive transmission. Effects of spinal administration of anandamide on innocuous and noxious evoked spinal neuronal responses in non-inflamed and carrageenin-inflamed rats were studied. Anandamide (0.1-50 microg/50 microl) had inconsistent effects in non-inflamed rats. Following carrageenin inflammation, anandamide (50 microg/50 microl) significantly reduced evoked neuronal responses, C-fibre mediated non-potentiated and post-discharge responses of neurones reduced to 65 +/- 5% and 57 +/- 10% of control, respectively. Effects of anandamide were blocked by SR141716A, a selective CB1 receptor antagonist. Spinal SR141716A (0.001-1 ng/50 microl) alone did not influence neuronal responses in inflamed rats. Spinal anandamide inhibited nociceptive transmission via CB1 receptors; following inflammation there is evidence for a loss of spinal endogenous cannabinoid tone.     

Effects of peripheral nerve injury on functional spinal VR1 receptors

VR1 receptors, present on Adelta- and C-fibres and post-synaptic sites within the spinal cord dorsal horn, is an integrator of noxious stimuli. Here, the contribution of spinal VR1 receptors to spinal nociceptive processing in nerve injured (selective spinal nerve ligated SNL) and sham anaesthetised rats was studied. Spinal capsazepine (0.5-30 microM), a competitive VR1 antagonist, reduced noxious evoked responses of spinal neurones to a greater extent in sham operated rats, compared to SNL rats. Significant differences between the effect of spinal capsazepine on the non-potentiated component of the C-fibre evoked response of SNL and sham operated rats are reported (p< 0.01, two-way ANOVA). Our data suggest there is a functional plasticity of the spinal VR1 receptor following nerve injury.     

ω-Agatoxin IVA, a P-Type Calcium Channel Antagonist, Reduces Nociceptive Processing in Spinal Cord Neurons with Input From the Inflamed But Not From the Normal Knee Joint — An Electrophysiological Study in the Rat In Vivo

High threshold voltage-dependent P- and Q-type calcium channels are involved in neurotransmitter release. In order to investigate the role of P- and Q-type calcium channels in the mechanosensory (nociceptive) processing in the spinal cord, their participation in the responses of spinal wide-dynamic-range neurons to innocuous and noxious mechanical stimulation of the knee and ankle joints was studied in 30 anaesthetized rats. The knee was either normal or acutely inflamed by kaolin/carrageenan. During the topical application of ω-agatoxin IVA (P-type channel antagonist, 0.1 μM) onto the dorsal surface of the spinal cord, the responses to innocuous and noxious pressure applied to the normal knee were increased to respectively 124 ± 42% and 114 ± 23% of predrug values (mean ± SD, P < 0.05, 14 neurons). By contrast, in rats with an inflamed knee, the responses to innocuous and noxious pressure applied to the knee were reduced to respectively 72 ± 19 and 73 ± 22% of baseline (mean ± SD, P < 0.01, 13 neurons). In the same neurons, ω-agatoxin IVA slightly increased the responses to pressure on the non-inflamed ankle whether the knee was normal or inflamed. Thus P-type calcium channels seem to acquire a predominant importance in the excitation of spinal cord neurons by mechanosensory input from inflamed tissue and hence in the generation of inflammatory pain. By contrast, the Q-type channel antagonist, ω-conotoxin MVllC (1 or 100 μM), had no significant effect upon responses to innocuous or noxious pressure applied to either normal or inflamed knees (25 neurons).     

Spinal GABA(B)-receptor antagonism increases nociceptive transmission in vivo.

GABA(B) receptors modulate primary afferent fibre evoked responses of spinal neurones. Here effects of the selective GABA(B) receptor antagonist, CGP-35348, on electrically-evoked responses of spinal neurones in control and carrageenan-inflamed rats were studied. Spinal CGP-35348 (0.1-10 microg/50 microl) did not alter Abeta- or Adelta-fibre evoked neuronal responses in control rats, although C-fibre evoked responses and post discharge responses of spinal neurones were significantly facilitated by 3.0 and 10.0 microg/50 microl CGP-35348 (p < 0.05). In carrageenan-treated animals, spinal CGP-35348 did not alter electrically evoked responses of spinal neurones at any dose. Our data suggest that following acute peripheral inflammation there is loss of endogenous GABA(B) receptor mediated inhibition of C-fibre transmission at the level of the spinal cord.     

Inhibition of peripheral vanilloid TRPV1 receptors reduces noxious heat-evoked responses of dorsal horn neurons in naïve, carrageenan-inflamed and neuropathic rats

The vanilloid TRPV1 receptor, present on primary afferent fibres, is activated by noxious heat, low pH and endogenous vanilloids. Changes in the function or distribution of TRPV1 receptors may play an important role in pain induced by inflammation or neuropathy. The aim of the present study was to evaluate the role of peripheral TRPV1 receptors in thermal nociception in rat models of inflammatory and neuropathic pain. Here, we have determined the effects of peripheral administration of the potent TRPV1 receptor antagonist iodoresiniferatoxin (IRTX) on noxious heat (45 °C)‐evoked responses of spinal wide dynamic range (WDR) neurons in naïve, carrageenan‐inflamed, sham‐operated and L5/6 spinal nerve‐ligated (SNL) anaesthetized rats in vivo. In addition, effects of peripheral administration of IRTX on mechanically evoked responses of WDR neurons were determined in sham‐operated and SNL rats. Carrageenan inflammation significantly (P < 0.05) increased the 45 °C‐evoked responses of WDR neurons. Intraplantar injection of the lower dose of IRTX (0.004 µg) inhibited (P < 0.05) 45 °C‐evoked responses of WDR neurons in carrageenan‐inflamed, but not in naïve, rats. The higher dose of IRTX (0.4 µg) significantly (P < 0.05) inhibited 45 °C‐evoked responses in both inflamed and naïve rats. In sham‐operated and SNL rats, IRTX (0.004 and 0.4 µg) significantly (P < 0.05) inhibited 45 °C‐evoked, but had no effect on mechanically evoked responses of WDR neurons. These data support the role of peripheral TRPV1 receptors in noxious thermal transmission in naïve, inflamed and neuropathic rats, and suggest that there is an increased functional contribution of peripheral TRPV1 receptors following acute inflammation.     

Cannabinoid CB2 receptor activation inhibits mechanically evoked responses of wide dynamic range dorsal horn neurons in naïve rats and in rat models of inflammatory and neuropathic pain

Peripheral cannabinoid 2 receptors (CB2 receptors) modulate immune responses and attenuate nociceptive behaviour in models of acute and persistent pain. The aim of the present study was to investigate whether peripheral CB2 receptors modulate spinal processing of innocuous and noxious responses and to determine whether there are altered roles of CB2 receptors in models of persistent pain. Effects of local administration of the CB2 receptor agonist JWH-133 (5 and 15 microg/50 microL) on mechanically evoked responses of spinal wide dynamic range (WDR) neurons in noninflamed rats, rats with carrageenan-induced hindpaw inflammation, sham operated rats and spinal nerve-ligated (SNL) rats were determined in anaesthetized rats in vivo. Mechanical stimulation (von Frey filaments, 6-80 g) of the peripheral receptive field evoked firing of WDR neurons. Mechanically evoked responses of WDR neurons were similar in noninflamed, carrageenan-inflamed, sham-operated and SNL rats. Intraplantar injection of JWH-133 (15 microg), but not vehicle, significantly (P < 0.05) inhibited innocuous and noxious mechanically evoked responses of WDR neurons in all four groups of rats. In many cases the selective CB2 receptor antagonist, SR144528 (10 microg/50 microL), attenuated the inhibitory effects of JWH-133 (15 microg) on mechanically evoked WDR neuronal responses. The CB1 receptor antagonist, SR141716A, did not attenuate the inhibitory effects of JWH-133 on these responses. Intraplantar preadministration of JWH-133 also inhibited (P < 0.05) carrageenan-induced expansion of peripheral receptive fields of WDR dorsal horn neurons. This study demonstrates that activation of peripheral CB2 receptors attenuates both innocuous- and noxious-evoked responses of WDR neurons in models of acute, inflammatory and neuropathic pain.     

Effects of spinal administration of muscimol on C- and A-fibre evoked neuronal responses of spinal dorsal horn neurones in control and nerve injured rats

Neuropathic pain is a common clinical problem with complex aetiology, mechanisms and symptoms. Alterations in spinal gamma-aminobutyric acid (GABA) receptors may contribute to persistent pain states. The aim of the present study is to investigate potential changes of spinal GABA(A)-receptor function following peripheral nerve injury. Effects of spinal administration of the GABA(A)-receptor agonist muscimol (0.1-30 microg/50 microl) on electrically-evoked responses of spinal neurones in control, spinal nerve ligated and sham operated halothane-anaesthetised rats were studied. Spinal muscimol significantly (10 microg/50 microl) reduced evoked Abeta-, Adelta- and C-fibre responses of spinal neurones in control rats (58+/-22% of control, P<0.05; 3+/-2% of control, P<0.001; and 8+/-7% of control, P<0.001; respectively). Muscimol produced significantly greater inhibition of Adelta- and C-fibre evoked neuronal responses compared to Abeta-fibre evoked neuronal responses in control rats (P<0.001). C-fibre mediated post-discharge responses and the non-potentiated C-fibre evoked responses were significantly inhibited by muscimol in control rats. Inhibitory effects of muscimol (10 microg/50 microl) were blocked by pre-application of spinal bicuculline (10 microg/50 microl). Following either sham surgery, or spinal nerve ligation, spinal muscimol inhibited Abeta-, Adelta- and C-fibre evoked responses of spinal neurones to a similar extent, however significant inhibitory effects on the post-discharge response were not observed in nerve injured rats. Our data demonstrate that GABA(A)-receptor control of Abeta- and Adelta-fibre evoked responses are not altered in nerve injured or sham operated rats, compared to control. However, following nerve injury we report a reduction in GABA(A)-receptor control of C-fibre responses, in particular in relation to post-discharge responses.     

Increased spinal cord phosphorylation of extracellular signal-regulated kinases mediates micturition overactivity in rats with chronic bladder inflammation

Spinal processing of somatosensory and viscerosensory information is greatly facilitated in some persistent pain states. Growing evidence suggests that the so-called central sensitization depends in part on intracellular activation and signalling via specific MAP kinases. Here we studied the expression of phosphorylated extracellular signal-regulated kinases 1 and 2 (phosphoERK), the active form of these kinases, in spinal neurons following innocuous and noxious distension of non-inflamed and cyclophosphamide (CYP)-inflamed rat urinary bladders. Additionally, we investigated the nature of bladder primary afferents responsible for spinal ERK activation. Finally, we used a specific inhibitor of ERK phosphorylation to study the influence of these kinases on the bladder reflex activity of normal and inflamed bladders. Results indicated that, in non-inflamed rats, noxious but not innocuous bladder distension significantly increased spinal phosphoERK immunoreactivity from its normal very low level. However, in CYP-inflamed rats, innocuous and noxious bladder distension significantly increased the number of spinal neurons immunoreactive to phosphoERK. ERK activation was rapid (within minutes) and transient. Desensitization of vanilloid-sensitive afferents by intravesical resiniferatoxin, a capsaicin analogue, did not decrease phosphoERK immunoreactivity in normal or CYP-inflamed rats. ERK inhibition by intrathecal PD 98059 had no effect on bladder reflex contractions of non-inflamed bladders but significantly decreased its frequency in inflamed animals. Our results suggest that spinal ERK intervene in acute and chronic inflammatory pain perception and mediate bladder reflex overactivity accompanying chronic bladder inflammation. In addition, bladder noxious input conveyed in vanilloid-resistant primary afferents is important to spinal ERK phosphorylation in both noninflamed and CYP-inflamed animals.     

Spinal modulation of the induction of central sensitization

Peripheral tissue injury results in a change in the excitability of spinal dorsal horn neurons, central sensitization, and the behavioral correlate, hyperalgesia. It is proposed here that a dynamic balance exists between excitatory and inhibitory synaptic input to the spinal dorsal horn that functions to prevent central sensitization following brief, mild, noxious stimulation. Following more severe stimulation and injury, there is a loss of these inhibitory mechanisms that allow central sensitization to proceed. Single-unit recordings were made from L4–L5 deep dorsal horn neurons (wide dynamic range and nociceptive specific) from barbiturate-anesthetized rats that were non-inflamed or had a carrageenan-inflamed hindpaw. Baseline test responses to mechanical stimuli were obtained and normalized to 100%. An electrical conditioning stimulus (1 Hz, 20 s, C-fiber strength) was applied to the tibial nerve or the neuronal receptive field. Five seconds later the test stimulus was repeated and the magnitude of response compared to baseline. During the conditioning stimulus, 46% of the neurons from non-inflamed and inflamed rats showed wind-up although the magnitude of wind-up was significantly greater for inflamed rats. The remaining neurons showed no change (36–46%) or wind-down (8–18%). Five seconds following the end of the conditioning stimulus 67% of the neurons from non-inflamed rats had attenuated responses to mechanical stimuli (36% of baseline). The remaining neurons were either unaffected (30%) or facilitated (3%). Following inflammation significantly fewer neurons (28%) had attenuated responses and the magnitude of attenuation was significantly less than in non-inflamed rats (54% of baseline). The responses of the remaining neurons were unaffected (54%) or facilitated (18%). During subsequent test stimuli, the responses of 30% of the neurons from non-inflamed rats were facilitated to 140% of baseline. The responses of 46% of neurons from inflamed rats were facilitated to 160% of baseline. In these neurons there was significantly less initial attenuation following inflammation compared to non-inflamed rats. The response of the neuron during the electrical conditioning had no effect upon the response following conditioning. The conditioning stimulus given transcutaneously within the receptive field produced qualitatively similar results to tibial nerve stimulation. In non-inflamed rats, when the conditioning/test-stimulus interval was increased from 5 s to 10–30 s, the responses of 20% of the neurons were attenuated (compared to 67%) and the mean magnitude of attenuation was 52% of baseline (compared to 36% of baseline). However, the responses of only 33% of the neurons were ultimately facilitated (compared to 30%). The present study documents a short period following a low-frequency C-fiber input in which the response to natural stimuli is suppressed. It is suggested that this attenuation, whether or not expressed, prevents a significant portion of deep dorsal horn neurons from becoming sensitized to C-fiber input. This functions to prevent central sensitization when the noxious stimulus does not produce inflammation and it is not beneficial to the animal to become hyperalgesic (i.e., to alter its behavior in order to protect an injured limb and reduce painful sensations). Following injury-producing tissue damage and inflammation the mechanisms that produce the attenuation are reduced, with a concomitant increase in excitation to electrical and natural stimuli, suggesting that the attenuation is inhibitory modulation of nociceptive input and injury results in a disinhibition producing an increase in excitability and central sensitization.     

Effects of selective and non-selective -opioid receptor agonists on cutaneous C-fibre-evoked responses of rat dorsal horn neurones

We have studied the effects of 3 putative kappa-opioid receptor agonists, U50488H, ethylketocyclazocine (EKC) and dynorphin A1-13 (DYN) on the processing of nociceptive information in the dorsal horn of the rat under halothane anaesthesia. Extracellular single unit recordings were made from convergent or multireceptive lumbar dorsal horn neurones, which could be excited by impulses in A beta and C fibre afferents following transcutaneous electrical stimulation of their ipsilateral hind paw receptive fields and also by noxious and innocuous natural stimuli. Agonists were applied directly onto the surface of the spinal cord. DYN and U50488H consistently produced both a facilitation and inhibition of the C-fibre evoked nociceptive responses of individual cells, these dual effects being relatively insensitive to naloxone antagonism and cancelled each other for the whole population of cells. A beta fibre-evoked responses were little altered. In contrast, EKC consistently depressed C-fibre transmission in a dose-dependent, naloxone reversible manner, analogous to, but considerably less potent than intrathecal morphine under identical experimental conditions. Agonist-induced effects on neuronal responses to natural stimulation (noxious pinch and innocuous prod) were consistent with the changes observed with the electrically evoked responses. The present results therefore indicate that EKC probably exerts its spinal antinociceptive activity in the rat spinal cord in a manner akin to mu-receptor activation. Results with U50488H and DYN indicate that -opioids can excite and inhibit individual neurones but produce no overall change on the whole population, so differing from effects mediated by the other opiate receptors.     

Inhibitory effects evoked from both the lateral and ventrolateral periaqueductal grey are selective for the nociceptive responses of rat dorsal horn neurones

In rats anaesthetized with alphaxalone/alphadolone a comparative study was made of the inhibitory effects on dorsal horn neurones evoked by chemical stimulation at identified pressor and depressor sites in the lateral and ventrolateral periaqueductal grey (PAG). Stimulating micropipettes were inserted stereotaxically into the lateral or ventrolateral PAG at sites where microinjection of -homocysteic acid (DLH) evoked increases or decreases respectively in mean arterial blood pressure. The effects of DLH microinjection at these sites were tested against the responses of dorsal horn neurones to noxious and innocuous stimuli applied to their cutaneous receptive fields. Single unit extracellular recordings were made from 15 Class 1 (low-threshold) and 37 Class 2 (wide dynamic range) dorsal horn neurones in laminae II–VI of the lower lumbar spinal cord. The responses of Class 1 neurones to innocuous prodding of their receptive fields were unaffected by neuronal activation in either the lateral or ventrolateral PAG. The nociceptive (noxious pinch/heat) responses of most Class 2 neurones were strongly inhibited by chemical stimulation in either sector of the PAG. The low threshold (prod) responses of the same neurones were generally unaffected or only weakly inhibited by identical stimulation, regardless of stimulation site. No significant differences were found between the effects of lateral vs. ventrolateral PAG stimulation on the responses of dorsal horn neurones. These results do not support the view that dorsal horn neurones may be inhibited with different selectivities by hyper- and hypotensive regions of the PAG.     

Neurophysiological, pharmacological and behavioral evidence for medial thalamic mediation of cocaine-induced dopaminergic analgesia.

These studies examined the effects of cocaine on thalamic neurons that respond maximally either to noxious or to innocuous somatic stimulation. Cocaine attenuated high intensity electrically-evoked nociceptive responses of all 25 units studied in the parafascicular and central lateral nuclei of the medial thalamus. A dose of 1 mg/kg intravenously (i.v.) suppressed medial thalamic unit discharge evoked by both noxious somatic stimulation (49.4 +/- 8.7% of control response) and spinal cord stimulation (76.2 +/- 6.6% of control response). The effect of cocaine on unit responses to noxious somatic stimulation was dose-related in the range of 0.3-3.5 mg/kg i.v. and was attenuated by eticlopride, a D-2 selective dopamine receptor antagonist. Morphine also suppressed noxious somatic evoked responses of medial thalamic units in a dose-dependent manner. Units in the lateral (ventrobasal) thalamus (n = 4) that responded only to innocuous stimuli were not affected by cocaine at doses up to 3.5 mg/kg i.v. Ibotenic acid lesions in the parafascicular nucleus of the medial thalamus attenuated the analgesic effect of cocaine in the formalin test. These results suggest that both cocaine and the parafascicular nucleus interact with dopaminergic mechanisms that attenuate nociceptive spinal projections to the medial thalamus.     

Responses of spinal neurones to cutaneous and dorsal root stimuli in rats with mechanical allodynia after contusive spinal cord injury

The firing of neurones in spinal segments adjacent to a contusive T13 spinal cord injury was characterised in anaesthetised rats. Three groups of rats were examined: (1) allodynic spinally injured, (2) non-allodynic spinally injured and (3) normal, uninjured. Spinal cord field potentials evoked by electrical dorsal root stimulation and the responses of 207 dorsal horn neurones to mechanical stimuli applied to the skin were studied. Within the lesioned spinal segment few active neurones were encountered and field potentials were absent. Depolarising field potentials recorded rostral to the lesion were reduced in both allodynic and non-allodynic animals compared to uninjured controls, while those recorded in caudal segments were enhanced in allodynic animals. Neuronal recordings revealed that allodynia was associated with exaggerated responses, including afterdischarges, to innocuous and noxious mechanical stimuli in a proportion of wide dynamic range, but not low threshold, neurones. These changes were observed both rostral and caudal to the site of injury. The results suggest that an increased responsiveness of some dorsal horn neurones in segments neighbouring a contusive spinal cord injury may contribute to the expression of mechanical allodynia. It is proposed that a relative lack of inhibition underlies altered cell responses.     

Evidence for biological effects of exogenous LPA on rat primary afferent and spinal cord neurons

There is growing behavioural evidence that the phospholipid growth factor lysophosphatidic acid (LPA) modulates nociceptive responses in vivo. The present study investigated further the effects of LPA on peripheral nociceptive processing. Effects of intraplantar injection of LPA on ongoing and peripheral mechanically evoked responses of spinal neurons were studied in vivo. In addition, LPA-evoked responses of adult rat dorsal root ganglion (DRG) neurons were studied with calcium imaging. To determine whether LPA may also act at the level of the spinal cord, LPA receptor G-protein coupling in lumbar spinal cord sections was studied with in vitro autoradiography of guanylyl 5'-[g-[(35)S]thio]triphosphate ([(35)S]GTPgammaS) binding. Intraplantar injection of LPA (5 microg/5 microl) significantly increased the duration (P<0.001) and frequency of spinal neuronal firing (P<0.01), compared to vehicle. Intraplantar injection of LPA (1 microg/5 microl) did not significantly alter innocuous and noxious mechanically evoked responses of spinal neurons, but a higher dose of LPA (5 microg) significantly (P<0.05) attenuated mechanically evoked responses of spinal neurons. Calcium imaging studies demonstrated that LPA (0.001-3 microM) increases intracellular calcium concentration in adult DRG neurons, suggesting that LPA can produce direct effects on. Incubation of spinal cord sections with LPA (1 microM) significantly (P<0.001) increased [(35)S]GTPgammaS binding in the superficial laminae of the dorsal horn of the spinal cord, suggesting that LPA may also have biological effects at this level. These data provide further evidence that exogenous LPA can modulate nociceptive processing and suggest that this may be mediated by a direct effect on primary afferent nociceptors.     

Involvement of spinal neurokinin-1 receptors in the maintenance but not induction of carrageenan-induced thermal hyperalgesia in the rat

The study was undertaken to assess the antihyperalgesic effect of L-732,138, (N-acetyl-L-tryptophan-3,5-bistrifluoromethyl benzyl ester), a non-peptide neurokinin-1 (NK1) receptor antagonist in rats when given intrathecally. The peripheral inflammation associated with behavioral hyperalgesia to a thermal stimulus was induced by intraplantar (i.pl.) injection of carrageenan. The thermal hyperalgesia was measured by paw withdrawal latency. Intrathecal (i.t.) injection of L-732,138 (100 nmol) at 3h after carrageenan markedly attenuated the paw withdrawal latency of the inflamed paw, but not that of the non-inflamed paw. L-732,138 (100 nmol, i.t.) given 10 min prior to carrageenan injection had no effect on the carrageenan-induced decrease in paw withdrawal latency to noxious thermal stimulus. The results demonstrate that NK1 receptor is involved in the maintenance but not the induction and development of thermal hyperalgesia evoked by carrageenan.     

Requirement of Metabotropic Glutamate Receptors for the Generation of Inflammation-evoked Hyperexcitability in Rat Spinal Cord Neurons

In the central nervous system the transmitter L-glutamate activates both ionotropic receptors coupled to cation channels and metabotropic receptors coupled to G-proteins. The role of metabotropic receptors in the processing of mechanosensory and nociceptive information was studied in a subset of spinal cord neurons with afferent input from the knee joint in anaesthetized rats using electrophysiological methods. The ionophoretic administration of L-2-amino-3-phosphonopropionic acid (L-AP3), an antagonist at the metabotropic receptor, had no effect on the responses to innocuous and noxious pressure applied to the normal knee joint, although the antagonist prevented the potentiation of these responses evoked by the ionophoretic administration of a specific agonist at the metabotropic receptor, trans -(±)-1-amino-(1S,3R)-cyclopentane-dicarboxylic acid ( t -ACPD). By contrast, in neurons that were rendered hyperexcitable by acute inflammation in the knee joint L-AP3 reduced the responses to pressure applied to the knee. When L-AP3 was applied during induction of inflammation and throughout the subsequent 1.5 h the spinal neurons did not develop hyperexcitability over this time period. L-AP3 did not impair the activation of ionotropic N -methyl-D-aspartate (NMDA) and non-NMDA receptors by the specific agonists. We conclude that spinal metabotropic glutamate receptors are not involved in the mediation of responses to innocuous and noxious mechanical stimuli applied under normal conditions. They are required, however, for the generation of inflammation-evoked hyperexcitability of spinal cord neurons, a form of functional plasticity underlying the painfulness in pathophysiological conditions such as inflammation.     

Suppression of nociceptive responses in parafascicular neurons by stimulation of substantia nigra: an analysis of related inhibitory pathways

A total of 166 neurons in parafascicular nucleus (PF) were studied, 85 from intact animals, 72 following dorsal spinal cord transection (D.Sp.C.X.), and 9 following complete transection of the spinal cord. Two patterns of nociceptive responses were identified following noxious stimulation and these responses were classified as 'nociceptive-on' and 'nociceptive-off' neurons, respectively. The effects of stimulating the substantia nigra (SNS) on the spontaneous and on the nociceptive evoked discharges were observed and compared in intact, D.Sp.C.X. and completely transected spinal cord rats. The results show that SNS significantly suppresses both the spontaneous and the nociceptive evoked discharges elicited by peroneal nerve stimulation. With an intact spinal cord, SNS suppressed both the spontaneous [-37 +/- 3.2% (P less than 0.05)] and the nociceptive evoked discharges [-52.8 +/- 2.8% (P less than 0.01)] of the 'nociceptive-on' cells respectively, while in the 'nociceptive-off' cells the same stimulation elicited an even more prominent suppression upon both discharges (-47.7 +/- 5.4%, P less than 0.01 and -64.9 +/- 5.0%, P less than 0.01), respectively. After D.Sp.C.X., the suppressive effects on the 'nociceptive-on' cells following SNS were diminished (-28.1 +/- 3.5% and -36.9 +/- 2.6%, respectively) but not abolished, while in the 'nociceptive-off' cells, the inhibitory effects on SNS were unchanged. In addition, the suppressive effects of SNS on the spontaneous activity of PF neurons in cases with completely cut spinal cords remains unchanged. These results suggest that SNS modulates the spontaneous and the noxious evoked responses of the PF neurons by way of supraspinal connections besides the previously described descending projecting pathways.     

The Role of Spinal Neurokinin-2 Receptors in the Processing of Nociceptive Information from the Joint and in the Generation and Maintenance of Inflammation-evoked Hyperexcitability of Dorsal Horn Neurons in the Rat

In spinal cord neurons in anesthetized rats, the role of neurokinin A and neurokinin-2 receptors in the processing of nociceptive information from the knee joint was studied. The specific non-peptide antagonist at the neurokinin-2 receptor, SR48968, its inactive R -enantiomer, SR48965, neurokinin A, substance P and ( R, S )-α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA), were administered ionophoretically close to neurons with input from the knee joint. SR48968 reduced the effects of exogenous neurokinin A, but not those of exogenous substance P and AMPA, indicating selective blockade of neurokinin-2 receptors. In most neurons with input from the normal knee joint, SR48968 reduced dose-dependently the responses to noxious pressure applied to the knee, and in ˜50% of the neurons the responses to innocuous pressure. The administration of SR48968 during the induction of an experimental joint inflammation markedly attenuated the development of inflammation-evoked hyperexcitability. In hyperexcitable neurons with input from the inflamed joint, SR48968 reduced the responses to noxious and innocuous pressure. The relative reduction of the responses was more pronounced than in neurons with input from the normal joint. None of the effects of SR48968 was mimicked by SR48965. These data show that neurokinin-2 receptors are involved in the spinal processing of nociceptive information from the normal joint. Furthermore, neurokinin-2 receptors must be coactivated at an early stage of inflammation, to allow the generation of hyperexcitability. Finally, neurokinin-2 receptors are involved in the maintenance of hyperexcitability during inflammation. In summary, spinal neurokinin-2 receptors are important in the generation of pain in the normal and inflamed joint.