Capsaicin-induced pain and sensitisation in the postpartum period.

BACKGROUND: Recovery from Caesarean delivery in women and surgical nerve injury in animals after delivery is more rapid than expected, an effect reversed in animals by spinal injection of an oxytocin receptor antagonist. We hypothesised that endogenous modulation of acute pain is altered postpartum. METHODS: Endogenous inhibition of acute pain in a conditioned pain modulation paradigm or endogenous sensitisation by topical capsaicin was tested in women who were breastfeeding 10-14 days after Caesarean delivery and age-matched controls (n=80 total: 20 per group and 20 per test). The study was powered to detect a difference in area of hyperalgesia after capsaicin of 33%. Capsaicin-evoked pain was recorded in women, and capsaicin-evoked mechanical hypersensitivity was measured in rats 48 h after delivery and in age-matched female and male animals. RESULTS: There was no effect of the postpartum period in the endogenous sensitisation assay in women, and the conditioned pain modulation assay failed to produce analgesia in either group. Postpartum women, however, reported less intense pain than controls at the end of topical capsaicin exposure (1.3 [1.4] vs 2.0 [2.0] on 0-10 verbal scale), and acute hypersensitivity after capsaicin was less in postpartum than control rats (withdrawal threshold 25 [15] vs 3.6 [1] g). CONCLUSIONS: These results agree with a recent report that oxytocin may desensitise the transient receptor potential for vanilloid-1 channel, although other explanations, including hormone effects, are possible. These results do not, however, support the inhibition of capsaicin-evoked spinal sensitisation in the postpartum period. CLINICAL TRIAL REGISTRATION: NCT01843517.

Inhibitory M2 muscarinic receptors are upregulated in both axotomized and intact small diameter dorsal root ganglion cells after peripheral nerve injury.

Acetylcholine reduces nociceptive input in part by activating inhibitory M2 muscarinic receptors on primary sensory neurons, and acetylcholinesterase inhibitors and muscarinic agonists produce analgesia in humans and animals. M2 muscarinic receptors are upregulated in animals with diabetic neuropathy, but their level of expression and function after peripheral nerve injury has not been previously examined. This study tested, using intracellular Ca(2+) response to membrane depolarization, the effect of the M2 muscarinic receptor agonist bethanechol on individual dorsal root ganglion cells from normal and L5-6 spinal nerve-ligated rats, followed by M2 muscarinic receptor immunostaining. We also examined functional transient receptor potential for vanilloids-1 activity by determining intracellular Ca(2+) response evoked by capsaicin in M2 muscarinic receptor immunoreactive cells. In normal dorsal root ganglion cells, bethanechol inhibited the Ca(2+) response in a concentration-related fashion, and this inhibition was blocked by the M2 muscarinic receptor antagonist gallamine. Cells expressing M2 muscarinic receptors by immunostaining were significantly inhibited by bethanechol, whereas those lacking positive staining were not. The proportion of studied dorsal root ganglion neurons with positive M2 muscarinic receptor staining increased significantly in the injured ipsilateral L5-6 and the uninjured ipsilateral L4 ganglia, but not in the contralateral dorsal root ganglion neurons compared with normals. In contrast, the proportion of neurons responding to capsaicin significantly decreased in the injured ipsilateral L5-6 dorsal root ganglion cells. These results suggest that inhibitory M2 muscarinic receptors are upregulated in small- and medium-sized axotomized dorsal root ganglion neurons and their uninjured neighbors following nerve injury, and may represent an appropriate target for analgesia in this setting.

alpha2-adrenoceptors inhibit the intracellular Ca2+ response to electrical stimulation in normal and injured sensory neurons, with increased inhibition of calcitonin gene-related peptide expressing neurons after injury.

Nerve injury resulting in chronic pain is associated with novel excitatory effects of norepinephrine on injured peripheral nerve terminals and their cell bodies, due to actions on alpha2-adrenoceptors. Paradoxically, alpha2-adrenoceptor agonists administered near peripheral terminals or their cell bodies results in analgesia, not pain. This study tested, using intracellular Ca2+ response to stimulation, the effects of alpha2-adrenoceptor agonists on injured sensory neurons and classified their neuronal phenotype. Dorsal root ganglion cells from normal and spinal nerve-ligated rats were dissociated and activated twice with electrical field stimulation, while measuring Fura-2 fluorescence. Cells were perfused between stimulations with vehicle or alpha2-adrenoceptor agonists alone or with antagonists. Cells were considered inhibited if the ratio of their peak Ca2+ response to the second stimulus divided by the first was less than the 2.5th percentile for vehicle controls. alpha2-, But not alpha1-adrenoceptor agonists inhibited the Ca2+ response in a concentration related fashion, and this inhibition was blocked by alpha2-adrenoceptor antagonists. Clonidine inhibited a similar percentage of cells in the normal and spinal nerve-ligated group. In both groups, the large majority of clonidine-inhibited cells stained for isolectin B4. Spinal nerve ligation resulted in a 4-10-fold increase in the percentage of clonidine inhibited cells which immunostained for calcitonin gene-related peptide. These data are consistent with the known inhibition of Ca2+ currents by alpha2-adrenoceptors and suggest that, at the level of intracellular Ca2+, the key determinant of neurotransmitter release, alpha2-adrenoceptors are inhibitory after nerve injury, not excitatory. There is a shift in phenotype of sensory neurons which are inhibited by clonidine after nerve injury, which may explain clonidine's increased potency in the treatment of neuropathic compared with acute pain.

Perioperative administration of the alpha2-adrenoceptor agonist clonidine at the site of nerve injury reduces the development of mechanical hypersensitivity and modulates local cytokine expression.

The development of chronic pain after surgery is not rare. Nerve injury from complete or partial nerve section during surgery leads to macrophage recruitment and release of pro-inflammatory cytokines, leading in turn to sensitization. Macrophages also express alpha2-adrenoceptors, and we previously demonstrated a prolonged reduction in hypersensitivity following peri-neural injection of the alpha2-adrenoceptor agonist, clonidine, in rats with chronic nerve injury. The current study tested whether peri-neural clonidine at the time of injury could also prevent development of hypersensitivity. Rats underwent partial ligation of one sciatic nerve, and peri-neural saline, clonidine or a combination of clonidine and the alpha2A-adrenceptor-preferring antagonist, BRL44408, were administered before wound closure and, in some animals, also 24 and 48 h later. The single clonidine injection reduced hypersensitivity for only 5 h, whereas repeated injection for three days reduced hypersensitivity for 28 days. Peri-neural clonidine reduced the increase in tissue content of the proinflammatory cytokines IL-1beta and particularly TNFalpha in sciatic nerve, DRG and spinal cord while increasing concentrations of the anti-inflammatory cytokine TGF-beta1. Clonidine's effects on behavior and TNFalpha content were blocked by BRL44408. We conclude that peri-neural administration of clonidine at the site and time of injury reduces the degree of hypersensitivity in part by altering the balance of pro- and anti-inflammatory cytokines through activation of alpha2A-adrenoceptors. These results support testing of whether clonidine, as an adjuvant in continuous peripheral nerve blocks in settings of known major nerve injury, such as limb amputation, might prevent the development of chronic pain.

Exogenous and endogenous adenosine enhance the spinal antiallodynic effects of morphine in a rat model of neuropathic pain.

Adenosine analogs produce antinociception in normal animals and reduce allodynia and hyperalgesia following inflammation and nerve injury following spinal injection, yet none have been tested for clinical safety. While adenosine itself is in clinical trials for spinal administration, there is little data on the spinal effects of adenosine in animal models. In this study, we determined that the spinal administration of adenosine produced a dose-dependent reduction in tactile allodynia in rats following spinal nerve ligation without producing motor blockade. Although the maximal effect of adenosine was less than 50% reversal of allodynia, its duration of action was >24 h after a single spinal injection. In contrast, injection of a synthetic adenosine analog which produced an anti-allodynic action to a similar degree of effect resulted in a pronounced motor blockade. Spinal opioid action has been suggested to result in part from spinal adenosine release. We hypothesized that the reduced efficacy of spinal morphine in nerve injury-induced allodynia and hyperalgesia might reflect a disruption in this spinal opioid-adenosine mechanism. Spinal morphine itself produced a minimal reduction in allodynia in rats following spinal nerve ligation and this was enhanced in an additive manner by spinal adenosine. The maximal effect of this combination resulted in less than 60% reversal of allodynia. In contrast, spinal injection of adenosine deaminase or reuptake inhibitors greatly enhanced the effect of spinal morphine, resulting in over 80% reversal of allodynia. These results support the clinical testing of spinal adenosine alone and with morphine in the treatment of neuropathic pain, and further testing of the proposed opioid-adenosine link in normal and hyperesthetic conditions.

Morphine-induced spinal cholinergic activation: in vivo imaging with positron emission tomography.

Positron emission tomography (PET) imaging of spinal cord in monkeys with a cholinergic tracer demonstrates increased spinal cholinergic activity in response to an analgesic dose of morphine, and this PET result correlates with measurement of acetylcholine spillover into spinal cord extracellular space induced by morphine, as measured by microdialysis. Previous studies in rats, mice, and sheep demonstrate activation of spinal cholinergic neurons by systemic opioid administration, and participation of this cholinergic activity in opioid-induced analgesia. Testing the relevance of this observation in humans has been limited to measurement of acetylcholine spillover into lumbar cerebrospinal fluid. The purpose of this study was to apply a recently developed method to image spinal cholinergic terminals non-invasively via PET and to test the hypothesis that the tracer utilized would reflect changes in local cholinergic activity. Following Animal Care and Use Committee approval, seven adult male rhesus monkeys were anesthetized on three separate occasions. On two of the occasions PET scans were performed using [(18)F] (+)-4-fluorobenzyltrozamicol ([(18)F]FBT), which selectively binds to the vesicular acetylcholine (ACh) transporter in the presynaptic cholinergic terminals. PET scans were preceded by injection of either saline or an analgesic dose of IV morphine (10 mg/kg). On the third occasion, microdialysis catheters were inserted in the spinal cord dorsal horn and acetylcholine concentrations in dialysates determined before and after IV morphine injection. Morphine increased cholinergic activity in the spinal cord, as determined by blood flow corrected distribution volume of [(18)F]FBT in the cervical cord compared to the cerebellum. Morphine also increased acetylcholine concentrations in microdialysates from the cervical cord dorsal horn. The one animal which did not show increased spinal cholinergic activity by PET from this dose of morphine also did not show increased acetylcholine from this morphine dose in the microdialysis experiment. These data confirm the ability to use PET to image spinal cholinergic terminals in the monkey spinal cord and suggest that acute changes in cholinergic activity can be imaged with this non-invasive technique. Following preclinical screening, PET scanning with [(18)F]FBT may be useful to investigate mechanisms of analgesic action in normal humans and in those with pain.

Intraplantar injection of a cyclooxygenase inhibitor ketorolac reduces immunoreactivities of substance P, calcitonin gene-related peptide, and dynorphin in the dorsal horn of rats with nerve injury or inflammation.

We previously reported that partial sciatic nerve ligation (PSNL) dramatically up-regulates cyclooxygenase 2 (COX2) in injured sciatic nerve, and local injection of the COX inhibitor, ketorolac, reverses tactile allodynia and suppresses increased phosphorylation of the transcription factor cAMP responsive element binding protein [Eur J Neurosci 15 (2002) 1037]. These findings suggest that peripheral prostaglandins (PGs) are over-produced and contribute to the central plasticity and the maintenance of neuropathic pain after nerve injury. PGs, particularly PGE2, are well known to facilitate the release of the pro-nociceptive neuropeptide substance P (SP) and calcitonin gene-related peptide (CGRP) from primary sensory afferents. Thus, suppressing peripheral PG over-production may inhibit the release of these two neuropeptides from primary afferents and thereby increase the content of these neuropeptides remaining in afferent terminals in the dorsal horn. In this study we tested this hypothesis by examining the immunoreactivities of SP and CGRP in the dorsal horn of PSNL rats intraplantarly injected with saline and ketorolac. Four weeks after PSNL, SP- and CGRP-immunoreactivities (IR) in the ipsilateral dorsal horn were not significantly different from the contralateral side. Five days following intraplantar injection of ketorolac, CGRP- and SP-IR in the ipsilateral and contralateral dorsal horn were dramatically reduced compared with saline-injected PSNL rats. Local ketorolac also suppressed PSNL-induced increase in dynorphin-IR in dorsal horn neurons. Since abundant production of PGs during inflammation is well documented, we further examined the effect of intraplantar ketorolac on neuropeptide expression in the dorsal horn following carrageenan inflammation. We observed that co-administration of ketorolac with carrageenan in the hindpaw also reduced SP- and dynorphin-IR in the ipsilateral and contralateral dorsal horn. These findings are in contrast to our hypothesis, suggesting that peripherally over-produced PGs following nerve injury and inflammation possibly contribute to the production of SP and CGRP in primary sensory neurons, to the up-regulation of dynorphin in the dorsal horn neurons, and finally to the mechanisms of neuropathic and inflammation pain.

Cyclooxygenase 2 in infiltrating inflammatory cells in injured nerve is universally up-regulated following various types of peripheral nerve injury.

We previously reported the up-regulation of cyclooxygenase 2 (COX2) in injured sciatic nerve of rats with partial sciatic nerve ligation (PSNL) and the reversal of PSNL-elicited tactile allodynia by local injection of the COX inhibitor ketorolac [Eur J Neurosci 15 (2002) 1037]. We further asked whether COX2 up-regulation in injured nerve is a universal phenomenon following various types of nerve injury. In the current study, we observed that abundant COX2 immunoreactive (IR) cell profiles appeared in injured nerves of rats following spinal nerve ligation (SNL), chronic constriction injury (CCI) and complete sciatic nerve transection. Most COX2-IR cells were identified as infiltrating macrophages. Partial injury induced greater COX2 up-regulation than complete injury. COX2 up-regulation reached a peak at 2-4 weeks, evidently declined by 3 months and disappeared by 7 months postlesion. These findings suggest that up-regulation of COX2 in injured nerve is a common event during the initial several months after nerve injury. We observed that local ketorolac-elicited anti-allodynia was closely associated with the abundance of COX2-IR cells in injured nerve, varying with the type of injury and time after injury. The anti-allodynia lasted the longest when local ketorolac was given 2-4 weeks after PSNL, CCI and SNL. The duration of local ketorolac's anti-allodynia was the longest in CCI rats, which also exhibited the most abundant COX2 up-regulation. Local ketorolac's anti-allodynia lasted much shorter when given 2-3 months after lesion. Local ketorolac failed to induce anti-allodynia 7 months after lesion, a time when COX2-IR cells completely disappeared from the injured nerve except a few cells at the injury site. Our data strongly suggest that during the initial several months after nerve injury, peripherally over-produced prostaglandins play an important role in the maintenance of neuropathic pain.

P75-expressing elements are necessary for anti-allodynic effects of spinal clonidine and neostigmine.

Cells expressing nerve growth factor are implicated in development of hypersensitivity following nerve injury and cholinergic neurons are implicated in reduction of such hypersensitivity by alpha2-adrenergic agonists. Intrathecal injection of the cell toxin, saporin, linked to an antibody to the low-affinity nerve growth factor, p75 (192-IgG saporin), an agent which destroys cholinergic neurons in the brain, was used in the current study to further elucidate these mechanisms. Mechanical hypersensitivity was established in rats by ligation of the L5 and L6 spinal nerves. Animals were pretreated with intrathecal saline or 192-IgG saporin, and one week later received intrathecal clonidine or neostigmine. Spinal cords were removed for acetylcholine and norepinephrine analysis and for cholinergic and p75 immunohistochemistry. Treatment with 192-IgG saporin had no effect on mechanical hypersensitivity following spinal nerve ligation, but blocked the anti-hypersensitivity effects of intrathecal clonidine and neostigmine. Destruction of p75-expressing fibers in the superficial dorsal horn by 192-IgG saporin was not accompanied by changes in acetylcholine or norepinephrine content or by reduction in cholinergic neuronal number in the spinal cord dorsal horn. Unlike in the brain, 192-IgG saporin does not destroy cholinergic neurons in the spinal cord dorsal horn and cannot be used as a tool for this purpose. P75-expressing elements are not necessary for the maintenance of mechanical hyperalgesia in this model of neuropathic pain, but their destruction disrupts the targets or circuitry activated by alpha2-adrenergic and cholinergic agents to reduce hypersensitivity.

Intrathecal S-nitroso-N-acetylpenicillamine and L-cysteine attenuate nerve injury-induced allodynia through noradrenergic activation in rats.

Spinal norepinephrine release and activation of spinal alpha(2)-adrenergic receptors represent important components of descending control of nociception. Recent studies have shown that nitric oxide is capable of stimulating neuronal norepinephrine release in the presence of thiol-containing compounds such as L-cysteine. In the present study, we tested a hypothesis in a rodent model of neuropathic pain that intrathecal injection of the nitric oxide donor S-nitroso-N-acetylpenicillamine and L-cysteine produces an antiallodynic action mediated by the spinal alpha(2)-adrenergic receptors. Allodynia was induced in rats by ligation of the left lumbar L5/L6 spinal nerves. Mechanical allodynia was quantified by application of von Frey filaments to the left hindpaw. Intrathecal injection of 20-100microg of S-nitroso-N-acetylpenicillamine in the presence of 200microg of L-cysteine, but not D-cysteine, dose-dependently attenuated the allodynia. Intrathecal injection of a combination of 100microg of S-nitroso-N-acetylpenicillamine and 50-200microg of L-cysteine also inhibited the allodynia in a dose-dependent manner. Pretreatment with a nitric oxide scavenger, carboxy-PTIO, or depletion of norepinephrine with a specific neurotoxin, N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine, prevented the antiallodynic action of intrathecal S-nitroso-N-acetylpenicillamine and L-cysteine. Furthermore, the antiallodynic effect produced by intrathecal injection of a combination of S-nitroso-N-acetylpenicillamine and L-cysteine was abolished by pretreatment with intrathecal injection of a non-specific alpha-adrenergic receptor antagonist, phentolamine, or an alpha(2) receptor antagonist, idazoxan. This study provides the first functional evidence that spinal nitric oxide interacts with the thiol-containing compounds to produce an antiallodynic effect in neuropathic pain. We propose that such an action is mediated by endogenous norepinephrine and spinal alpha(2)-adrenergic receptors.

Formation of 6-nitro-norepinephrine from nitric oxide and norepinephrine in the spinal cord and its role in spinal analgesia.

Spinally released norepinephrine is thought to produce analgesia in part by stimulating alpha(2)-adrenergic receptors, which in turn leads to nitric oxide synthesis. Also, nitric oxide is known to react with norepinephrine in vivo in the brain to form 6-nitro-norepinephrine, which inhibits neuronal norepinephrine reuptake. In the present study, we tested the hypothesis that formation of 6-nitro-norepinephrine occurs in the spinal cord and that intrathecal administration of 6-nitro-norepinephrine produces analgesia by stimulating norepinephrine release. 6-Nitro-norepinephrine was present in rat spinal cord tissue and microdialysates of the dorsal horn and intrathecal space. Intrathecal norepinephrine injection increased 6-nitro-norepinephrine. 6-Nitro-norepinephrine also stimulated norepinephrine release in dorsal spinal cord in vitro. Intrathecal injection of 6-nitro-norepinephrine produced antinociception and interacted additively with norepinephrine for antinociception. Spinal noradrenergic nerve destruction increased antinociception from intrathecally injected norepinephrine, but decreased antinociception from 6-nitro-norepinephrine. These results suggest a functional interaction between spinal nitric oxide and norepinephrine in analgesia, mediated in part by formation of 6-nitro-norepinephrine. Stimulation of auto-inhibitory alpha(2)-adrenergic receptors at noradrenergic synapses decreases norepinephrine release. Paradoxically, alpha(2)-adrenergic agonist injection increases and alpha(2)-adrenergic antagonist injection decreases norepinephrine release in the spinal cord. 6-Nitro-norepinephrine may be an important regulator of spinal norepinephrine release and could explain the positive feedback on norepinephrine release after activation of spinal alpha(2)-adrenergic receptors.

Spinal cyclooxygenase-2 is involved in development of allodynia after nerve injury in rats.

Increased spinal cyclooxygenase activity is associated with nociception induced by tissue inflammation. In the present study, we examined the changes of cyclooxygenase-1 and cyclooxygenase-2 protein expression in several regions of the CNS associated with pain perception, and the role of spinal cyclooxygenase activity in the development of allodynia following nerve injury. Allodynia was induced by ligation of the left L5 and L6 spinal nerves in rats. Using western blot analysis, we found that the cyclooxygenase-2 protein levels in the dorsal spinal cord and thalamus (but not in the ventral spinal cord, cingulate cortex and locus coeruleus) increased significantly one day after nerve ligation, compared with those in the sham animals. The cyclooxygenase-2 protein levels in the above tissues were similar in nerve-injured and sham animals three and 14 days after surgery. In contrast, cyclooxygenase-1 protein was not detectable in any of the neural tissues examined one, three, and 14 days after nerve injury. In the behavioral experiments, we observed that intrathecal injection of 100microg of indomethacin immediately or one day after nerve ligation attenuated the development of tactile allodynia. However, intrathecal injection of indomethacin had no effect on established allodynia two weeks after nerve injury.Collectively, our results suggest that cyclooxygenase-2 is preferentially up-regulated in the dorsal spinal cord and thalamus in response to nerve injury in rats. Spinal cyclooxygenase-2 probably plays an important role in the early development, but not in the maintenance, of tactile allodynia caused by the nerve injury in this rat model of neuropathic pain.

Comparison of analgesic requirements after liver transplantation and cholecystectomy.

In a prospective study of 10 patients who underwent liver transplantation and 10 patients who underwent cholecystectomy, we analyzed the postoperative analgesic requirements and the resultant plasma morphine concentrations. Analgesia was more intense, with less medication, and the plasma morphine concentration was significantly lower in the liver transplant group than in the cholecystectomy group. This finding is most likely attributable to endogenous factors rather than to altered morphine pharmacokinetics.

Patient-controlled epidural analgesia during labor.

This study compared the safety, efficacy, local anesthetic usage, patient satisfaction, and anesthesia manpower demands of patient-controlled epidural analgesia and continuous epidural infusion during labor. After establishment of epidural analgesia, 88 parturients with vertex presentation were assigned randomly to receive either patient-controlled epidural analgesia or continuous epidural infusion, using 0.125% bupivacaine containing 1 microgram/mL of fentanyl. Inadequate analgesia was treated in both groups with a 10-mL "top-up" of 0.25% bupivacaine. Patients receiving patient-controlled epidural analgesia required significantly fewer supplemental top-up doses (36 versus 71%; P less than .05) and insignificantly less local anesthetic (13.6 +/- 0.6 versus 14.6 +/- 0.5 mL/hour; P = .10). The two groups did not differ in incidence of hypotension, high sensory blockade (above T8), mode of delivery, or patient satisfaction assessed by questionnaire. Use of local anesthetic solution was examined with respect to cervical dilatation and did not increase late in labor. Patients generally viewed infusion technology favorably. These findings suggest that patient-controlled epidural analgesia is safe and effective, reduces anesthesia manpower needs, and is well accepted.

NMDA causes release of nitric oxide from rat spinal cord in vitro.

Anatomic studies have localized nitric oxide synthase (NOS) activity in the rat spinal cord dorsal horn and intermediolateral cell column. Behavioral and electrophysiologic studies suggest that N-methyl-D-aspartate (NMDA) stimulates nitric oxide synthesis in the dorsal horn. This report describes a novel bioassay to determine directly in vitro whether NMDA causes release of nitric oxide from rat spinal cord. Modified Krebs-Henseleit solution at 26 degrees C was perfused over spinal cord slices from adult male rats, then dropped onto a ring of endothelium-denuded rat aorta. Following preconstriction with phenylephrine, NMDA (10(-10) to 10(-3) M) alone or with other drugs was added to the perfusion solution and vascular tension measured. NMDA-containing solutions applied directly on the preconstricted vessels without exposure to spinal cord tissue had no effect on vessel tone. In contrast, NMDA via the spinal cord perfusion caused concentration-dependent vascular relaxation, which was blocked by MK-801, hemoglobin, methylene blue, and several arginine analogues which inhibit NOS. [14C]citrulline assay suggested NOS in rat spinal cord was non-endothelial in nature. NMDA perfusion of spinal cord slices in vitro causes vascular relaxation in this bioassay due to actions on NMDA receptors and which is consistent with release of nitric oxide. These results support previous anatomical, behavioral, and electrophysiologic studies in rat spinal cord and describe a novel, sensitive, and simple bioassay for nitric oxide release from neural tissue in vitro.

Chronic intrathecal morphine administration produces homologous mu receptor/G-protein desensitization specifically in spinal cord.

Previous studies have shown that chronic i.v. treatment with morphine or heroin decreased mu opioid receptor activation of G-proteins in specific brain regions. The present study examined the effect of intrathecal (i.t.) morphine administration on receptor/G-protein coupling in the spinal cord. In spinal cord membranes, [35S]GTP gamma S binding was stimulated by agonists of several G-protein-coupled receptors, including mu opioid (DAMGO), delta opioid (DPDPE), GABA(B) (baclofen), cannabinoid CB(1) (WIN 55,212-2), muscarinic cholinergic (carbachol) and adenosine A(1) (PIA). [35S]GTP gamma S autoradiography revealed that most of this agonist activation of G-proteins was localized to laminae I and II of dorsal horn. To determine the effects of chronic morphine on these receptor activities, rats were treated for 7 days with 0.11 mg/kg/day i.t. morphine, and receptor activation of G-proteins was determined by [35S]GTP gamma S autoradiography of brain and spinal cord. In spinal cord sections, chronic morphine treatment decreased DAMGO-stimulated [35S]GTP gamma S binding in laminae I and II at all levels of spinal cord examined. There were no effects of morphine treatment on [35S]GTP gamma S stimulation in spinal cord by other receptor systems examined (Adenosine A(1) and GABA(B)), and no significant effects of chronic i.t. morphine treatment were observed in brain sections. These data show that homologous desensitization of mu receptor/G-protein coupling occurs specifically in spinal cord following chronic morphine administration.

S-nitroso-l-cysteine releases norepinephrine in rat spinal synaptosomes.

Although nitric oxide (NO) participates in development of hypersensitivity states in the spinal cord thought to underlie chronic pain, it also participates in analgesia produced by various drugs. In rats with a hypersensitivity state following peripheral nerve injury, spinal administration of an NO donor or l-cysteine alone produced no effect, whereas their combination, which yields s-nitroso-l-cysteine (SNC) powerfully reduced hypersensitivity. In the current study, we examined the ability of SNC to stimulate release of a known spinal analgesic neurotransmitter, norepinephrine (NE), as a possible mechanism of analgesic action of NO in the spinal cord. SNC (but not the NO donor alone or decomposed SNC) produced a concentration-dependent release of NE from rat spinal cord synaptosomes. The d-isomer of SNC was less potent than the l-isomer, and the effect of SNC was partially blocked by l-, but not d-leucine, implicating an interaction with the l-amino acid transporter. SNC-induced NE release was partially Na(+) dependent, but largely Ca(2+) independent. NE uptake inhibitors partially antagonized the effect of SNC, but guanylate cyclase inhibitors were without effect. These data are therefore consistent with NO stimulating NE release in the spinal cord via reaction with thiol containing compounds, such as cysteine, entry into NE terminals via active transport, and production of both exocytotic and carrier mediated release.

Muscarinic-mediated analgesia.

Systemic administration of cholinesterase inhibitors which cross the blood brain barrier have long been known to produce analgesia and enhance analgesia from opiates. A major site of analgesic action of cholinergic agents is the spinal cord. Muscarinic receptors are concentrated in the superficial layers of the dorsal horn of the spinal cord, an area of noxious sensory processing, and these reflect innervation primarily from cholinergic neurons with cell bodies deep in the neck of the dorsal horn. Spinal injection of cholinergic agonists results in analgesia which primarily reflects muscarinic receptor activation. Analgesia occurs in animal models of acute noxious stimulation and of chronic hypersensitivity pain. Although no cholinergic agonists have been tested for safety in humans, the cholinesterase inhibitor, neostigmine, has undergone such testing, and produces analgesia to experimental, acute postoperative, and chronic pain. Thus, muscarinic cholinergic agonists and cholinesterase inhibitors hold promise as non-opiate agents for the treatment of moderate to severe acute and chronic pain.

The puerperium alters spinal cord plasticity following peripheral nerve injury.

Tissue and nerve damage can result in chronic pain. Yet, chronic pain after cesarean delivery is remarkably rare in women and hypersensitivity from peripheral nerve injury in rats resolves rapidly if the injury occurs in the puerperium. Little is known regarding the mechanisms of this protection except for a reliance on central nervous system oxytocin signaling. Here we show that the density of inhibitory noradrenergic fibers in the spinal cord is greater when nerve injury is performed in rats during the puerperium, whereas the expression of the excitatory regulators dynorphin A and neuregulin-1 in the spinal cord is reduced. The puerperium did not alter spinal cord microgial and astrocyte activation. Astrocyte activation, as measured by glial fibrillary acidic protein (GFAP) expression, was not evident in female rats with injury, regardless of delivery status suggesting sex differences in spinal astrocyte activation after injury. These results suggest a change in the descending inhibitory/facilitating balance on spinal nociception neurotransmission during the puerperium, as mechanisms for its protective effect against injury-induced hypersensitivity.

Opioid-independent mechanisms supporting offset analgesia and temporal sharpening of nociceptive information.

The mechanisms supporting temporal processing of pain remain poorly understood. To determine the involvement of opioid mechanisms in temporal processing of pain, responses to dynamic noxious thermal stimuli and offset analgesia were assessed after administration of naloxone, a µ-opioid antagonist, and on a separate day, during and after intravenous administration of remifentanil, a µ-opioid agonist, in 19 healthy human volunteers. Multiple end points were sampled from real-time computerized visual analog scale ratings (VAS, 1 to 10) to assess thermal sensitivity, magnitude and duration of offset analgesia, and painful after sensations. It was hypothesized that the magnitude of offset analgesia would be reduced by direct opioid antagonism and during states of acute opioid-induced hypersensitivity (OIH), as well as diminished by the presence of exogenous opioids. Surprisingly, the magnitude of offset analgesia was not altered after naloxone administration, during remifentanil infusion, or after the termination of remifentanil infusion. Because thermal hyperalgesia was observed after both drugs, 8 of the original 19 subjects returned for an additional session without drug administration. Thermal hyperalgesia and increased magnitude of offset analgesia were observed across conditions of remifentanil, naloxone, and no drug within this subset analysis, indicating that repeated heat testing induced thermal hyperalgesia, which potentiated the magnitude of offset analgesia. Thus, it is concluded that the mechanisms subserving temporal processing of nociceptive information are largely opioid-independent, but that offset analgesia may be potentiated by heat-induced thermal hyperalgesia in a proportion of individuals.