Neuropathic pain is enhanced in delta-opioid receptor knockout mice

We have evaluated the possible involvement of delta-opioid receptor (DOR) in the development and expression of neuropathic pain. For this purpose, partial ligation of the sciatic nerve was performed in DOR knockout mice and wild-type littermates. The development of mechanical and thermal allodynia, as well as thermal hyperalgesia was evaluated by using the von Frey filament model, the cold-plate test and the plantar test, respectively. In wild-type and DOR knockout mice, sciatic nerve injury led to a neuropathic pain syndrome revealed in these nociceptive behavioural tests. However, the development of mechanical and thermal allodynia, and thermal hyperalgesia was significantly enhanced in DOR knockout mice. These results reveal the involvement of DOR in the control of neuropathic pain and suggest a new potential therapeutic use of DOR agonists.     

Inflammatory pain is enhanced in delta opioid receptor-knockout mice

To examine the involvement of opioid receptors in inflammatory pain, we compared Complete Freund's Adjuvant-induced hyperalgesia in mice lacking mu, delta or kappa receptors under the same experimental conditions. Mechanical allodynia and thermal hyperalgesia were measured using von Frey filaments and the plantar test, respectively. All three receptor-knockout mice, as well as wild-type animals, developed inflammatory hyperalgesia following Complete Freund's Adjuvant administration. Mu-receptor mutants showed similar hyperalgesia to wild-types in the two tests. Kappa-receptor mutants exhibited enhanced mechanical allodynia compared with wild-type mice but similar thermal hyperalgesia. In contrast, mechanical allodynia and thermal hyperalgesia were both markedly augmented in delta-receptor mutants, indicating a role for an endogenous delta-receptor tone in the control of inflammatory pain. Treatment with the delta-selective agonist SNC80 produced antihyperalgesia, and this effect was abolished in the delta-receptor knockout mice. Altogether, these data demonstrate that delta receptors inhibit inflammatory pain when activated either endogenously or exogenously. We have previously shown enhanced neuropathic pain in delta-receptor knockout mice. The delta receptor definitely represents a promising target for treating chronic pain conditions.     

The role of TLR2 in nerve injury-induced neuropathic pain is essentially mediated through macrophages in peripheral inflammatory response

Activation of macrophages/microglia via toll-like receptors (TLRs) plays an important role in inflammation and host defense against pathogens. Pathogen-associated molecular patterns bind TLRs, thereby triggering NF-κB signaling and production of proinflammatory cytokines. Recent data suggest that nonpathogenic molecules resulting from trauma can also trigger inflammation via TLRs. We sought to determine whether peripheral nerve injury could induce the expression of TLR2 on the site of injury-damaged nerves and/or in the central nervous system and to investigate whether TLR2 is necessary for the development of nerve injury-induced neuropathic pain. We observed a significant increase in TLR2, IκB-α, and TNF-α mRNAs in damaged nerves. Increased inflammation-related molecules were found essentially on ED1(+) macrophages. Expression of both IκB-α and TNF-α in peripheral injured nerves was reduced in TLR2 deficient mice where the recruitment of ED1(+) cells is significantly impaired. Although after peripheral nerve injury, spinal microglia became highly activated showing an increase in Iba-1 immunoreactivity and an enlargement of their cell bodies, neither TLR2 mRNA nor IκB-α mRNA was detected in activated microglia. Nerve injury-evoked spinal microglial activation was not significantly altered in TLR2 KO mice. Paw withdrawal threshold and latency in response to mechanical and heat stimuli, respectively, decreased shortly after nerve lesion in wild type mice. In TLR2 KO mice, nerve injury-induced thermal hyperalgesia was completely abolished contrary to that seen in wild-type mice, whereas mechanical allodynia was partially reduced. We suggest that TLR2 is necessary for the development of neuropathic pain and its contribution is more important in thermal hypersensitivity than that of mechanical allodynia.     

Allodynia and hyperalgesia evoked by sciatic mononeuropathy in NKI receptor knockout mice

We have examined the participation of NK1 receptors in neuropathic pain by comparing behavioural responses after partial sciatic nerve ligation in wild-type (WT) and NK1 receptor knockout (KO) mice. Mechanical responses were tested with von Frey hairs, and cooling responses with acetone. WT and KO mice showed similar reactions before surgery. Nerve-ligated WT and KO mice showed equivalent spontaneous pain-related behaviour. Mechanical (mean threshold 20 +/- vs 9 +/- 1 mN) and cold allodynia (61 +/- vs 14 +/- 2 behaviours evoked by acetone) were significantly greater than in sham animals, but similar in WT and KO mice. We conclude that NK1 receptors are not essential for mechanical and cold allodynia evoked by partial nerve ligation.     

Membrane-associated prostaglandin E synthase-1 is required for neuropathic pain

It is widely accepted that prostaglandin (PG) E2 is the principal pro-inflammatory prostanoid and plays an important role in inflammatory pain. However whether PGE2 is involved in neuropathic pain remains unknown. PGE2 is produced from arachidonic acid via PGH2 by at least three PGE synthases (PGES), cytosolic PGES (cPGES), and membrane-associated PGES (mPGES)-1 and -2. In the present study, to clarify the involvement of PGE2 and identify PGES mediating neuropathic pain, we applied a neuropathic pain model prepared by L5 spinal nerve transection to mPGES-1 knockout (mPGES-1-/-) mice. Whereas they retained normal nociceptive responses, mPGES-1-/- mice did not exhibit mechanical allodynia and thermal hyperalgesia over a week. These results demonstrate that PGE2 produced by mPGES-1 is involved in neuropathic pain.     

TRPM2 contributes to inflammatory and neuropathic pain through the aggravation of pronociceptive inflammatory responses in mice

Accumulating evidence suggests that neuroimmune interactions contribute to pathological pain. Transient receptor potential melastatin 2 (TRPM2) is a nonselective Ca2?-permeable cation channel that acts as a sensor for reactive oxygen species. TRPM2 is expressed abundantly in immune cells and is important in inflammatory processes. The results of the present study show that TRPM2 plays a crucial role in inflammatory and neuropathic pain. While wild-type and TRPM2 knock-out mice showed no difference in their basal sensitivity to mechanical and thermal stimulation, nocifensive behaviors in the formalin test were reduced in TRPM2 knock-out mice. In carrageenan-induced inflammatory pain and sciatic nerve injury-induced neuropathic pain models, mechanical allodynia and thermal hyperalgesia were attenuated in TRPM2 knock-out mice. Carrageenan-induced inflammation and sciatic nerve injury increased the expression of TRPM2 mRNA in the inflamed paw and around the injured sciatic nerve, respectively. TRPM2 deficiency diminished the infiltration of neutrophils and the production of chemokine (C-X-C motif) ligand-2 (CXCL2), a major chemokine that recruits neutrophils, but did not alter the recruitment of F4/80-positive macrophages in the inflamed paw or around the injured sciatic nerve. Microglial activation after nerve injury was suppressed in the spinal cord of TRPM2 knock-out mice. Furthermore, CXCL2 production and inducible nitric oxide synthase induction were diminished in cultured macrophages and microglia derived from TRPM2 knock-out mice. Together, these results suggest that TRPM2 expressed in macrophages and microglia aggravates peripheral and spinal pronociceptive inflammatory responses and contributes to the pathogenesis of inflammatory and neuropathic pain.     

A subpopulation of rats show social and sleep-waking changes typical of chronic neuropathic pain following peripheral nerve injury

Neuropathic conditions for which treatment is sought, the so-called chronic pain syndrome, are characterized usually by complex behavioural disturbances as well as pain. In this study we evaluated whether social behavioural and sleep disruptions occurred after nerve injury. Before and after chronic constriction of the sciatic nerve, resident-intruder and sleep-wake cycles, as well as mechanical and thermal allodynia/hyperalgesia, were quantified. Sciatic nerve injury in all animals reduced withdrawal thresholds to tactile and thermal (cold) stimuli. Resident-intruder and sleep-waking behaviours were altered in some but not all animals. One group (30%, 'persistent change') had enduring reductions in dominant behaviour to an intruder and decreased slow-wave sleep and increased wakefulness during both light and dark cycles. Another group (25%, 'recovery') had a transient reduction in dominant behaviours and decreased slow-wave sleep and increased wakefulness during only the light cycle. In a third group (45%, 'no effect') resident-intruder and sleep-waking behaviours remained normal. Our finding that the degree of 'pain' as inferred from the allodynia/hyperalgesia was identical in all animals suggests that the alterations to resident-intruder and sleep-wake cycles were independent of the level of sensory disturbance. An absence of correlation between intensity of sensory disturbances and measures of disability (loss of sleep, familial/social problems) is also characteristic of human neuropathic pain. These data indicate that: (i) in a subpopulation of animals sciatic injury results in two of the major complex behavioural changes which are characteristic of neuropathic pain in humans; (ii) testing only for allodynia and hyperalgesia is not sufficient to detect this subpopulation.     

Estrogen affects neuropathic pain through upregulating N-methyl-D-aspartate acid receptor 1 expression in the dorsal root ganglion of rats

Estrogen affects the generation and transmission of neuropathic pain,but the specific regulatory mechanism is still unclear.Activation of the N-methyl-D-aspartate acid receptor 1(NMDAR1) plays an important role in the production and maintenance of hyperalgesia and allodynia.The present study was conducted to determine whether a relationship exists between estrogen and NMDAR1 in peripheral nerve pain.A chronic sciatic nerve constriction injury model of chronic neuropathic pain was established in rats.These rats were then subcutaneously injected with 17β-estradiol,the NMDAR1 antagonist D(-)-2-amino-5-phosphonopentanoic acid(AP-5),or both once daily for 15 days.Compared with injured drug na?ve rats,rats with chronic sciatic nerve injury that were administered estradiol showed a lower paw withdrawal mechanical threshold and a shorter paw withdrawal thermal latency,indicating increased sensitivity to mechanical and thermal pain.Estrogen administration was also associated with increased expression of NMDAR1 immunoreactivity(as assessed by immunohistochemistry) and protein(as determined by western blot assay) in spinal dorsal root ganglia.This 17β-estradiol-induced increase in NMDAR1 expression was blocked by co-administration with AP-5,whereas AP-5 alone did not affect NMDAR1 expression.These results suggest that 17β-estradiol administration significantly reduced mechanical and thermal pain thresholds in rats with chronic constriction of the sciatic nerve,and that the mechanism for this increased sensitivity may be related to the upregulation of NMDAR1 expression in dorsal root ganglia.     

Spinal Cord Stimulation in a Mouse Chronic Neuropathic Pain Model

Objective. Development of a spinal cord stimulation (SCS) system in a mouse model of chronic neuropathic pain. Materials and Methods. Male C57BL/6 mice (N = 6) underwent a partial ligation of the sciatic nerve. Development of mechanical hyperalgesia was tested using the withdrawal response to tactile stimuli with the von Frey test. An SCS system was implanted on day 14. On day 16, the mice were stimulated for 30 min (f = 50 Hz; pulse width 0.2 msec and stimulation at 2/3 of motor threshold). Repeated measure analysis of variance (anova ) and paired Student's t‐test with Bonferroni correction were used to evaluate the development of mechanical hyperalgesia and the therapeutic effect of SCS. Results. Five out of six mice developed marked mechanical hyperalgesia in the nerve‐lesioned paw that persisted for the duration of the study (16 days). No changes contralateral to the injury were observed. In four out of five mice, a successful implantation of the electrodes followed by stimulation was achieved. Then, SCS resulted in a fast and robust increase of withdrawal threshold back to pre‐injury levels. After termination of the SCS, the withdrawal threshold of the ipsilateral paw slowly decreased. No effect of SCS on the contralateral paw was noted. Conclusion. The development of a mouse SCS system is described that is practical in use, is reproducible, and shows a comparative therapeutic effect in treatment of chronic neuropathic pain as reported in rat.     

TRPM3 Channels Play Roles in Heat Hypersensitivity and Spontaneous Pain after Nerve Injury

Transient receptor potential melastatin 3 (TRPM3) is a heat-activated ion channel in primary sensory neurons of the dorsal root ganglia (DRGs). Pharmacological and genetic studies implicated TRPM3 in various pain modalities, but TRPM3 inhibitors were not validated in TRPM3^−/− mice. Here we tested two inhibitors of TRPM3 in male and female wild-type and TRPM3^−/− mice in nerve injury-induced neuropathic pain. We found that intraperitoneal injection of either isosakuranetin or primidone reduced heat hypersensitivity induced by chronic constriction injury (CCI) of the sciatic nerve in wild-type, but not in TRPM3^−/− mice. Primidone was also effective when injected locally in the hindpaw or intrathecally. Consistently, intrathecal injection of the TRPM3 agonist CIM0216 reduced paw withdrawal latency to radiant heat in wild-type, but not in TRPM3^−/− mice. Intraperitoneal injection of 2 mg/kg, but not 0.5 mg/kg isosakuranetin, inhibited cold and mechanical hypersensitivity in CCI, both in wild-type and TRPM3^−/− mice, indicating a dose-dependent off-target effect. Primidone had no effect on cold sensitivity, and only a marginal effect on mechanical hypersensitivity. Genetic deletion or inhibitors of TRPM3 reduced the increase in the levels of the early genes c-Fos and pERK in the spinal cord and DRGs in CCI mice, suggesting spontaneous activity of the channel. Intraperitoneal isosakuranetin also inhibited spontaneous pain related behavior in CCI in the conditioned place preference assay, and this effect was eliminated in TRPM3^−/− mice. Overall, our data indicate a role of TRPM3 in heat hypersensitivity and in spontaneous pain after nerve injury.SIGNIFICANCE STATEMENT Neuropathic pain is a major unsolved medical problem. The heat-activated TRPM3 ion channel is a potential target for novel pain medications, but the pain modalities in which it plays a role are not clear. Here we used a combination of genetic and pharmacological tools to assess the role of this channel in spontaneous pain, heat, cold, and mechanical hypersensitivity in a nerve injury model of neuropathic pain in mice. Our findings indicate a role for TRPM3 in heat hyperalgesia, and spontaneous pain, but not in cold and mechanical hypersensitivity. We also find that not only TRPM3 located in the peripheral nerve termini, but also TRPM3 in the spinal cord or proximal segments of DRG neurons are important for heat hypersensitivity.     

Submodality-Selective Hyperalgesia Adjacent to Partially Injured Sciatic Nerve in the Rat is Dependent on Capsaicin-Sensitive Afferent Fibers and Independent of Collateral Sprouting or a Dorsal Root Reflex

We studied submodality dependence of sensory changes produced by unilateral ligation of the sciatic or the saphenous nerve in the rat. We focused especially on sensory changes in the skin area adjacent to the innervation area of the injured nerve. Moreover, we examined the roles of capsaicin-sensitive nociceptive fibers, collateral sprouting and a dorsal root reflex in sensory changes observed behaviorally. Assessment of sensory changes was performed by a pattern of behavioral tests: hot-plate test and hindlimb withdrawal responses induced by radiant heat, hot-water bath, innocuous mechanical stimuli, and noxious mechanical stimuli. In one group, the saphenous nerve ipsilateral to the sciatic ligation was topically treated with capsaicin (1%) at the time of the surgery. A proximal stump of a saphenous nerve strand was orthodromically stimulated to induce a dorsal root reflex (an antidromic volley) in nociceptive fibers of the saphenous nerve trunk. For visualization of plasma extravasation induced by a dorsal root reflex, a dye-labeling (Evans blue) technique was used. A collateral sprouting of nociceptive fibers of the uninjured saphenous nerve was evaluated by determining the plasma extravasation response induced by antidromic stimulation of the saphenous nerve. Three and 10 days following the sciatic constriction injury, the hindlimb withdrawal threshold evoked by noxious mechanical stimulation of the medial side of the paw (the innervation are of the intact saphenous nerve) was significantly decreased. There was no corresponding thermal hyperalgesia adjacent to the injured sciatic nerve. Chronic constriction of the saphenous nerve did not produce any significant hyper- or hypoalgesia to mechanical or thermal stimulation of the uninjured sciatic nerve area. Topical treatment of the ipsilateral (intact) saphenous nerve at the time of the sciatic nerve ligation completely prevented the development of mechanical hyperalgesia in the medial side of the paw (the innervation area of the saphenous nerve). No dorsal root reflex in nociceptive fibers mediating the adjacent hyperalgesia could be evoked. No collateral sprouting of the uninjured nociceptive fibers of the saphenous nerve was observed. The results indicate that the constriction injury of the sciatic nerve produced a selective hyperalgesia to mechanical stimulation in the innervation area of the neighboring saphenous nerve. At the peripheral level, the mechanical hyperalgesia adjacent to the innervation area of the injured nerve was mediated by capsaicin-sensitive nociceptive fibers. Collateral sprouting of nociceptive fibers from the uninjured to the injured innervation area did not contribute to the present sensory findings. The sciatic nerve injury did not induce a dorsal root reflex in nociceptive fibers innervating the hyperalgesic saphenous nerve area.     

Complement activation contributes to leukocyte recruitment and neuropathic pain following peripheral nerve injury in rats

Complement activation triggers inflammation and has been implicated in neurological diseases associated with pain. However, the role of complement in neuropathic pain has not been clearly defined. In this study, we tested whether complement is activated by partial ligation of the rat sciatic nerve, a widely used model of neuropathic pain, and whether complement activation or inhibition in peripheral nerve influences leukocyte recruitment and neuropathic pain. We found that C3 deposition significantly increased from 6 h to 7 days in the injured nerve and was associated with the extent of thermal hyperalgesia and mechanical allodynia. However, no deposition of the membrane attack complex was detected. Complement activation by endoneurial injection of aggregated rat immunoglobulin G into normal sciatic nerve produced significant thermal hyperalgesia and mechanical allodynia of the ipsilateral hindpaw at 2-7 days after injection. This was accompanied by increased deposition of C3 and recruitment of macrophages at 7 days following injection. Complement inhibition using systemic injections of soluble complement receptor 1 (AVANT Immunotherapeutics, Inc., Needham, USA) into rats markedly suppressed C3 deposition and T-cell and macrophage recruitment to the injured nerve, and produced significant alleviation of thermal hyperalgesia and mechanical allodynia. These results demonstrate that C3 activation in the nerve contributes to increased infiltration of inflammatory cells and to neuropathic pain behaviors following peripheral nerve injury. Complement inhibition may be a potential therapeutic treatment for neuropathic pain.     

Nociceptive responses and spinal plastic changes of afferent C-fibers in three neuropathic pain models induced by sciatic nerve injury in the rat

Peripheral nerve injuries induce plastic changes on primary afferent fibers and on the spinal circuitry, which are related to the emergence of neuropathic pain. In this study we compared three models of sciatic nerve injury in the rat with different degrees of damage and impact on regeneration capability: crush nerve injury, chronic constriction injury (CCI) and spared nerve injury (SNI). All three models were characterized by means of nerve histology, in order to describe the degenerative and regenerative process of injured axons. Nociceptive responses were evaluated by mechanical and thermal algesimetry tests. Crush animals displayed higher withdrawal thresholds on the ipsilateral paw compared to the contralateral during the time of denervation, while CCI and SNI animals showed mechanical and thermal hyperalgesia. Central plasticity was evaluated by immunohistochemical labeling of non-peptidergic (IB4-positive) and peptidergic (substance P-positive) nociceptive C-fibers on L4-L6 spinal cord sections. After crush nerve injury and SNI, we observed progressive and sustained reduction of IB4 and SP immunolabeling at the sciatic projection territory in the superficial laminae of the dorsal horn, which affected only the tibial and peroneal nerves projection areas in the case of SNI. After CCI, changes on SP-immunoreactivity were not observed, and IB4-immunoreactive area decreased initially but recovered to normal levels on the second week post-injury. Thus, nociceptive responses depend on the type of injury, and the immunoreactivity pattern of afferent fibers at the spinal cord display changes less pronounced after partial than complete sciatic nerve injury. Although signs of neuropathic pain appear in all three lesion models, nociceptive responses and central plasticity patterns differ between them.     

Dissociation of microglial activation and neuropathic pain behaviors following peripheral nerve injury in the rat

Peripheral nerve injury commonly leads to neuropathic pain states fostered, in part, by neuroimmunologic events. We used two models of neuropathic pain (L5 spinal nerve cryoneurolysis (SPCN) and chronic constriction injury (CCI)) to assess the role of spinal glial activation responses in producing pain behaviors. Scoring of glial responses subjectively encompassed changes in cell morphology, cell density and intensity of immunoreactivity with specific activation markers (OX-42 and anti-glial fibrillary acidic protein (GFAP) for microglia and astrocytes, respectively). Glial responses were compared with tactile sensitivity (mechanical allodynia) at 1, 3 or 10 days following SPCN and with thermal hyperalgesia at 10 days in the CCI group. Neuropathic pain behaviors preceded and did not closely correlate with microglial responses in either model. Perineural application of bupivacaine prior to SPCN prevented spinal microglial responses but not pain behaviors. Spinal astrocytic responses to SPCN were early, robust and not altered by bupivacaine. The current findings support the use of bupivacaine as a tool to suppress microglial activation and challenge the putative role of microglia in initiating or potentiating pain behaviors which result from nerve injury.     

Rac1-regulated dendritic spine remodeling contributes to neuropathic pain after peripheral nerve injury

Although prior studies have implicated maladaptive remodeling of dendritic spines on wide-dynamic range dorsal horn neurons as a contributor to pain after spinal cord injury, there have been no studies on dendritic spines after peripheral nerve injury. To determine whether dendritic spine remodeling contributes to neuronal hyperexcitability and neuropathic pain after peripheral nerve injury, we analyzed dendritic spine morphology and functional influence in lamina IV–V dorsal horn neurons after sham, chronic constriction injury (CCI) of the sciatic nerve, and CCI treatment with NSC23766, a selective inhibitor of Rac1, which has been implicated in dendritic spine development. 10 days after CCI, spine density increased with mature, mushroom-shaped spines preferentially distributed along dendritic branch regions closer to the cell body. Because spine morphology is strongly correlated with synaptic function and transmission, we recorded the response of single units to innocuous and noxious peripheral stimuli and performed behavioral assays for tactile allodynia and thermal hyperalgesia. Wide dynamic range dorsal horn neurons of CCI animals exhibited hyperexcitable responses to a range of stimuli. They also showed reduced nociceptive thresholds in the ipsilateral hind paw. 3-day treatment with NSC23766 significantly reduced post-CCI spine dimensions and densities, and attenuated injury-induced hyperexcitability. Drug treatment reduced behavioral measures of tactile allodynia, but not for thermal hyperalgesia. Together, our results demonstrate that peripheral nerve injury induces Rac1-regulated remodeling of dendritic spines on dorsal horn neurons, and suggest that this spine remodeling contributes to neuropathic pain.     

Altered pain behavior and regeneration after nerve injury in TNF receptor deficient mice

The pro-inflammatory cytokine tumor necrosis factor (TNF)-alpha is an important mediator in hyperalgesia, nerve injury, and regeneration. Here, we used mice deficient of TNF receptor (TNFR) 1 or 2 to investigate the role of TNF signaling via receptor in each pain behavior and nerve de- and regeneration after chronic constriction injury (CCI) of the sciatic nerve. We found an absence of thermal hyperalgesia in mice deficient of TNFR1 and a reduction in mechanical and cold allodynia in mice deficient of TNFR1 or TNFR2 compared with wild-type mice. Nerve conduction studies and nerve pathology did not reveal major differences between genotypes in the temporal course of de- and regeneration of the nerve. We propose that the functional effects of the TNFRs on pain symptoms are independent of effects on nerve regeneration. Furthermore, the differential action of TNF via each of its receptors should be taken into account when considering clinical trials with TNF inhibitors for pain.     

Functional recovery after peripheral nerve injury is dependent on the pro-inflammatory cytokines IL-1β and TNF: implications for neuropathic pain

IL-1β and TNF are potential targets in the management of neuropathic pain after injury. However, the importance of the IL-1 and TNF systems for peripheral nerve regeneration and the mechanisms by which these cytokines mediate effects are to be fully elucidated. Here, we demonstrate that mRNA and protein levels of IL-1β and TNF are rapidly upregulated in the injured mouse sciatic nerve. Mice lacking both IL-1β and TNF, or both IL-1 type 1 receptor (IL-1R1) and TNF type 1 receptor (TNFR1), showed reduced nociceptive sensitivity (mechanical allodynia) compared with wild-type littermates after injury. Microinjecting recombinant IL-1β or TNF at the site of sciatic nerve injury in IL-1β- and TNF-knock-out mice restored mechanical pain thresholds back to levels observed in injured wild-type mice. Importantly, recovery of sciatic nerve function was impaired in IL-1β-, TNF-, and IL-1β/TNF-knock-out mice. Notably, the infiltration of neutrophils was almost completely prevented in the sciatic nerve distal stump of mice lacking both IL-1R1 and TNFR1. Systemic treatment of mice with an anti-Ly6G antibody to deplete neutrophils, cells that play an essential role in the genesis of neuropathic pain, did not affect recovery of neurological function and peripheral axon regeneration. Together, these results suggest that targeting specific IL-1β/TNF-dependent responses, such as neutrophil infiltration, is a better therapeutic strategy for treatment of neuropathic pain after peripheral nerve injury than complete blockage of cytokine production.     

Effects of pre-emptively administered nociceptin on the development of thermal hyperalgesia induced by two models of experimental mononeuropathy in the rat

Pre-emptive analgesia is thought to be produced by the prevention of spinal facilitation evoked by nociceptive input to the spinal cord. Opioid receptor-like 1 (ORL1) receptor agonist has been reported to inhibit the development of spinal facilitation. We investigated the effect of nociceptin, an ORL1 receptor agonist, on the development of thermal hyperalgesia and the expression of Fos-like immunoreactivity (Fos-LI) in the spinal dorsal horn induced by two neuropathic pain models, the chronic constriction injury model and the partial sciatic nerve injury model. Chronic constriction injury is created by placing four loosely tied ligatures around the right sciatic nerve. Partial sciatic nerve injury was created by tight ligation of one third to one half of the right sciatic nerve. All drugs were injected intrathecally 10 min before the nerve injury. The anti-hyperalgesic effect of drugs was evaluated by the measurement of the paw withdrawal latency (PWL) against thermal nociceptive stimulation. The PWLs of the injured paws were measured 7, 14 and 21 days after the nerve injury. Expression of Fos-LI was examined 2 h after the nerve injury. Intrathecal injection of nociceptin significantly delayed the development of thermal hyperalgesia and decreased the expression of Fos-LI induced by chronic constriction injury, but not that induced by partial sciatic nerve injury. These data indicate that pre-emptive administration of nociceptin might be one strategy for the prevention of the development of neuropathic pain.     

Interleukin-1alphabeta gene-deficient mice show reduced nociceptive sensitivity in models of inflammatory and neuropathic pain but not post-operative pain

The pro-inflammatory cytokine interleukin-1 (IL-1) has been implicated in both inflammatory processes and nociceptive neurotransmission. To further investigate the role of IL-1 in different pain states, gene-disrupted mice lacking both IL-1alpha and IL-1beta genes (IL-1alphabeta (-/-)) were characterized in inflammatory, neuropathic, and post-operative pain models. IL-1alphabeta (-/-) mice showed normal sensorimotor function as measured by the rotorod assay compared to control mice (BALB/c). Acute and persistent formalin-induced nocifensive behaviors were reduced by 20% in IL-1alphabeta (-/-) mice as compared to control mice. IL-1alphabeta (-/-) mice also showed reduced inflammatory thermal and mechanical hyperalgesia compared to controls following the intraplantar administration of carrageenan or complete Freund's adjuvant (CFA). The duration of inflammatory hyperalgesia was shortened in IL-1alphabeta (-/-) mice versus controls in the CFA model. In contrast, deletion of IL-1alphabeta did not change the extent or the duration of post-operative pain developing after skin incision of the hind paw. Finally, time to onset, duration, and magnitude of mechanical allodynia were reduced in two models of neuropathic pain, spinal nerve L5-L6 ligation and chronic constriction injury of the sciatic nerve, in IL-1alphabeta (-/-) mice versus controls. These results demonstrate that IL-1alphabeta modulates both the generation and the maintenance of inflammatory and chronic neuropathic pain and that IL-1 may modulate nociceptive sensitivity to a greater extent in conditions of chronic as compared to acute pain.