Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0344307 (analgesia)
28,200 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The periaqueductal gray matter (PAG) is an important center in the modulation of behavioral responses during nociception and stress. In the present experiment, extracellular excitatory amino acid overflow in the PAG was measured every 30 s during noxious stimulation. A combination of in vivo brain microdialysis in freely moving rats and capillary zone electrophoresis with laser induced-fluorescence detection allowed us to detect short lasting changes of excitatory amino acid in dialysates. A formalin injection in the hindpaw of the rat increased glutamate, arginine and aspartate concentration in PAG dialysates. This increase was calcium and nerve impulse-dependent, suggesting neuronal and glial origin of glutamate and arginine, respectively. Handling, pinching or saline injection in the hind paw did not increase glutamate showing that this neurochemical phenomenon is related to painful and persistent noxious stimulation. The results suggest that a rapid excitation of the PAG occurs during noxious stimulation. The role of glutamate and arginine in analgesia is discussed.
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PMID:Noxious stimulation increases glutamate and arginine in the periaqueductal gray matter in rats: a microdialysis study. 1092 6

The purpose of this study was to evaluate the possible contribution of metabotropic glutamate receptors (mGluRs) to cannabinoid-induced antinociception in the periaqueductal grey (PAG) matter of rats. Intra-PAG microinjection of WIN 55,212-2, a cannabinoid receptor agonist, increased the latency of the nociceptive reaction (NR) in a dose-dependent fashion in the plantar test. This effect was prevented by pretreatment with SR141716A, a selective antagonist of CB1 receptors. When injected alone, SR141716A produced, with the highest dosage used, a significant reduction in the latency of the NR. CPCCOEt, a selective mGlu1 receptor antagonist, was unable to prevent the analgesia produced by WIN 55,212-2. On the contrary, MPEP, a selective mGlu5 receptor antagonist, completely antagonized the effect of WIN 55,212-2. However, the analgesia induced by CHPG, a selective mGlu5 receptor agonist, was blocked by MPEP but not by SR141716A. When injected alone, CPCOOEt produced no effect, whereas MPEP produced, with the highest dosage used, a significant reduction in the latency of the NR. These data emphasize that mGlu5 receptors, but not mGluR1, may modulate nociception in the PAG. Similarly, a pretreatment with either 2-(S)-alpha-EGlu or (RS)-alpha-MSOP, selective antagonists for group II and III mGluRs, respectively, prevented the WIN 55,212-2-induced analgesia. When the higher dosage of (RS)-alpha-MSOP was used a decrease in the latency of the NR was observed. This was not the case for 2-(S)-alpha-EGlu. Pretreatment with DL-AP5, a selective antagonist of N-methyl-D-aspartate (NMDA) receptors, blocked the effect of WIN 55,212-2, and by increasing the dosage strongly reduced per se the latency of the NR. This study suggests that endogenous glutamate could tonically modulate nociception through mGlu and NMDA receptors in the PAG matter. In particular, the physiological stimulation of these receptors seems to be required for the cannabinoid-induced analgesia in this midbrain area.
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PMID:Metabotropic and NMDA glutamate receptors participate in the cannabinoid-induced antinociception. 1116 24

This review summarizes our studies using pharmacological, neurochemical and molecular biological methods on the nociception in the CNS and opioid receptors (OPRs). We designed an in vitro fluorometric on-line monitoring system including an immobilized glutamate dehydrogenase column, and for the first time actually demonstrated that capsaicin induced the release of glutamate from rat dorsal horn slices containing the terminal area of primary afferents, in concentration-dependent, extracellular Ca(2+)-dependent and tetrodotoxin-resistant manners. Further, such a release was shown to be inhibited through mu- and delta-opioid receptors and alpha 2-adrenoceptors. On the other hand, we found that intracerebroventricular injections of interleukin (IL)-1 beta in rats produced biphasic effects on the mechanical nociception in rats (hyperalgesia in lower concentrations but analgesia in higher ones) and that similar injections of cytokine-induced neutrophil chemoattractant-1 (CINC-1) facilitated mechanical nociception in rats. The above described facts suggest that glutamate and some sorts of cytokines (IL-1 beta and CINC-1) contribute to nociception at least from the primary afferents to the spinal dorsal horn neurons and in higher brain, respectively. We have cloned rat kappa- and mu-opioid receptors. Using cloned cDNA for OPRs, we demonstrated (1) the distribution of mRNAs for OPRs in the rat central nervous system, (2) coexistence of each type of mRNA for mu-, delta- and kappa-OPRs and pre-protachykinin A mRNA in the dorsal root ganglion neurons, (3) an increased expression of mu- and kappa-OPR mRNAs in the I-II layers of rat lumbar dorsal horn with an adjuvant arthritis in the hind limb, (4) the inhibitions of N- and Q-types of Ca2+ channels by mu- and kappa-OPR agonists and (5) cross-desensitization of the inhibition through a common intracellular phosphorylation-independent mechanism, (6) pharmacological characterization of "antagonist analgesics" as partial agonists at every type of OPRs, and (7) the key-structure(s) of OPRs for discriminative binding of DAMGO to mu-OPR.
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PMID:[Molecular neuropharmacology of nociceptive transmission and opioid receptors]. 1119 80

Nicotinic agonists, such as epibatidine (EPI) and A-85380, when administered systemically, elicit analgesia. Intrathecal EPI also produces analgesia accompanied by nociceptive and pressor responses. Since spinal administration of drugs offers a well defined pathway connecting the site of administration with behavioral and autonomic responses, we have compared the responses to intrathecal epibatidine and A-85380 to delineate the role of nicotinic acetylcholine receptors in spinal neurotransmission. Following implantation of intrathecal catheters in rats, we monitored cardiovascular, nociceptive, and antinociceptive responses after administration of various nicotinic receptor agonists. Consistent with A-85380 displacement of epibatidine from isolated spinal cord membranes, A-85380 elicited pressor, nociceptive, and antinociceptive responses similar to EPI. Antinociception was preceded by nociception. Both antinociception and nociception were blocked by mecamylamine, methyllycaconitine, and alpha-lobeline, but dihydro-beta-erythroidine only blocked the antinociceptive response. Whereas prior administration of EPI desensitized the nociceptive and antinociceptive responses to EPI, A-85380 pretreatment only desensitized EPI-elicited nociception and not antinociception. 2-Amino-5-phosphopentanoic acid pretreatment blocked the nociceptive response to A-85380, indicating A-85380 stimulated release of glutamate onto N-methyl-D-aspartate receptors to produce the irritant response of nociception. Intrathecal phentolamine virtually abolished A-85380 antinociception, but had no effect on EPI antinociception. Hence, analgesia can be produced by stimulation of distinct spinal preterminal nicotinic receptor subtypes, resulting in the release of neurotransmitters. In the case of A-85380, these sites primarily appear to be localized on adrenergic bulbospinal terminals. Our data suggest that A-85380 and EPI act at separate preterminal spinal sites as well as on distinct nicotinic receptor subtypes to elicit an antinociceptive response at the spinal level.
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PMID:A-85380 and epibatidine each interact with disparate spinal nicotinic receptor subtypes to achieve analgesia and nociception. 1125 49

The spinal cord is one of the sites where non-steroidal anti-inflammatory drugs (NSAIDs) act to produce analgesia and antinociception. Expression of cyclooxygenase(COX)-1 and COX-2 in the spinal cord and primary afferents suggests that NSAIDs act here by inhibiting the synthesis of prostaglandins (PGs). Basal release of PGD(2), PGE(2), PGF(2alpha) and PGI(2) occurs in the spinal cord and dorsal root ganglia. Prostaglandins then bind to G-protein-coupled receptors located in intrinsic spinal neurons (receptor types DP and EP2) and primary afferent neurons (EP1, EP3, EP4 and IP). Acute and chronic peripheral inflammation, interleukins and spinal cord injury increase the expression of COX-2 and release of PGE(2) and PGI(2). By activating the cAMP and protein kinase A pathway, PGs enhance tetrodotoxin-resistant sodium currents, inhibit voltage-dependent potassium currents and increase voltage-dependent calcium inflow in nociceptive afferents. This decreases firing threshold, increases firing rate and induces release of excitatory amino acids, substance P, calcitonin gene-related peptide (CGRP) and nitric oxide. Conversely, glutamate, substance P and CGRP increase PG release. Prostaglandins also facilitate membrane currents and release of substance P and CGRP induced by low pH, bradykinin and capsaicin. All this should enhance elicitation and synaptic transfer of pain signals in the spinal cord. Direct administration of PGs to the spinal cord causes hyperalgesia and allodynia, and some studies have shown an association between induction of COX-2, increased PG release and enhanced nociception. NSAIDs diminish both basal and enhanced PG release in the spinal cord. Correspondingly, spinal application of NSAIDs generally diminishes neuronal and behavioral responses to acute nociceptive stimulation, and always attenuates behavioral responses to persistent nociception. Spinal application of specific COX-2 inhibitors sometimes diminishes behavioral responses to persistent nociception.
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PMID:Prostaglandins and cyclooxygenases [correction of cycloxygenases] in the spinal cord. 1127 57

The effect of cannabinoids on excitatory transmission in the substantia gelatinosa was investigated using intracellular recording from visually identified neurons in a transverse slice preparation of the juvenile rat spinal cord. In the presence of strychnine and bicuculline, perfusion of the cannabinoid receptor agonist WIN55,212-2 reduced the frequency and the amplitude of spontaneous excitatory postsynaptic currents (sEPSCs). Furthermore, the frequency of miniature EPSCs (mEPSCs) was also decreased by WIN55,212-2, whereas their amplitude was not affected. Similar effects were reproduced using the endogenous cannabinoid ligand anandamide. The effects of both agonists were blocked by the selective CB(1) receptor antagonist SR141716A. Electrical stimulation of high-threshold fibers in the dorsal root evoked a monosynaptic EPSC in lamina II neurons. In the presence of WIN55,212-2, the amplitude of the evoked EPSC (eEPSCs) was reduced, and the paired-pulse ratio was increased. The reduction of the eEPSC following CB(1) receptor activation was unlikely to have a postsynaptic origin because the response to AMPA, in the presence of 1 microM TTX, was unchanged. To investigate the specificity of this synaptic inhibition, we selectively activated the nociceptive C fibers with capsaicin, which induced a strong increase in the frequency of EPSCs. In the presence of WIN55,212-2, the response to capsaicin was diminished. In conclusion, these results strongly suggest a presynaptic location for CB(1) receptors whose activation results in inhibition of glutamate release in the spinal dorsal horn. The strong inhibitory effect of cannabinoids on C fibers may thereby contribute to the modulation of the spinal excitatory transmission, thus producing analgesia at the spinal level.
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PMID:Cannabinoid-induced presynaptic inhibition of glutamatergic EPSCs in substantia gelatinosa neurons of the rat spinal cord. 1143 86

Evidence from the last several decades indicates that the excitatory amino acid glutamate plays a significant role in nociceptive processing. Glutamate and glutamate receptors are located in areas of the brain, spinal cord and periphery that are involved in pain sensation and transmission. Glutamate acts at several types of receptors, including ionotropic (directly coupled to ion channels) and metabotropic (directly coupled to intracellular second messengers). Ionotropic receptors include those selectively activated by N-methyl-D-aspartate, alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid and kainate. Metabotropic glutamate receptors are classified into 3 groups based on sequence homology, signal transduction mechanisms and receptor pharmacology. Glutamate also interacts with the opioid system, and intrathecal or systemic coadministration of glutamate receptor antagonists with opioids may enhance analgesia while reducing the development of opioid tolerance and dependence. The actions of glutamate in the brain seem to be more complex. Activation of glutamate receptors in some brain areas seems to be pronociceptive (e.g. thalamus, trigeminal nucleus), although activation of glutamate receptors in other brain areas seems to be antinociceptive (e.g. periaqueductal grey, ventrolateral medulla). Application of glutamate, or agonists selective for one of the several types of glutamate receptor, to the spinal cord or periphery induces nociceptive behaviours. Inhibition of glutamate release, or of glutamate receptors, in the spinal cord or periphery attenuates both acute and chronic pain in animal models. Similar benefits have been seen in studies involving humans (both patients and volunteers); however, results have been inconsistent. More research is needed to clearly define the role of existing treatment options and explore the possibilities for future drug development.
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PMID:Glutamate receptors and nociception: implications for the drug treatment of pain. 1146 12

Cannabinoid1 (CB1) receptors are located at CNS sites, including the spinal cord, involved in somatosensory processing. Analgesia is one of the tetrad of behaviors associated with cannabinoid agonists. Here, effects of a potent cannabinoid CB1 receptor agonist arachidonyl-2-chloroethylamide (ACEA) on evoked responses of dorsal horn neurons in anesthetized rats were investigated. Extracellular recordings of convergent dorsal horn neurons were made in halothane anesthetized Sprague-Dawley rats (n = 16). Effects of spinal application of ACEA on electrically evoked responses of dorsal horn neurons were studied. Mean maximal effects of 0.5, 5, 50, and 500 ng/50 microl ACEA on the C-fiber-mediated postdischarge response were 79 +/- 6, 62 +/- 10, and 54 +/- 7% (P < 0.01), 45 +/- 6% (P < 0.01), of control, respectively. ACEA (500 ng/50 microl) also reduced the C-fiber-evoked nonpotentiated responses of neurons (59 +/- 9% of control, P < 0.05) and Adelta-fiber-evoked responses of neurons (68 +/- 10% of control, P < 0.01). Minor effects of ACEA on Abeta-fiber-evoked responses were observed. Spinal pre-administration of the selective CB1 receptor antagonist SR141716A (0.01 microg/50 microl) significantly reduced effects of ACEA (500 ng/50 microl) on postdischarge responses of dorsal horn neurons. This study demonstrates that spinal CB1 receptors modulate the transmission of C- and Adelta-fiber-evoked responses in anesthetized rats; this may reflect pre- and/or postsynaptic effects of cannabinoids on nociceptive transmission. CB1 receptors inhibit synaptic release of glutamate in rat dorsolateral striatum, a similar mechanism of action may underlie the effects of ACEA on noxious evoked responses of spinal neurons reported here.
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PMID:Selective cannabinoid CB1 receptor activation inhibits spinal nociceptive transmission in vivo. 1173 61

The stimulation of glutamate receptors plays a relevant role in the development of behavioral sensitization to psychostimulants, while less clear results have been obtained on their role in morphine sensitization. We addressed this issue by comparing the development of cocaine and morphine sensitization under a continuous s.c. infusion of the N-methyl-D-aspartate (NMDA) antagonist dizocilpine (0.1 mg/kg/24 h). Moreover, we studied the expression of NMDA and alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) receptor subunits in discrete limbic areas of rats sensitized to morphine or cocaine with or without the concomitant dizocilpine infusion. It was observed that dizocilpine infusion did not prevent the development of morphine sensitization, while it prevented the development of tolerance to morphine-induced analgesia. Finally, morphine-sensitized animals did not present any modification in the subunit expression of glutamate receptors in the brain areas examined. In agreement with previous results, we found that dizocilpine infusion prevented the development of cocaine sensitization. Moreover, we observed that rats sensitized to cocaine presented a significant increase in the levels of GLUR1, NR1 and NR2B, in the nucleus accumbens, and of NR2B in the hippocampus compared to control animals. Such modifications were absent in rats administered cocaine under dizocilpine infusion. We conclude that: (i) morphine sensitization is a neuroadaptive phenomenon which does not appear to require NMDA receptor activity in order to develop; (ii) cocaine sensitization is clearly dependent on NMDA receptor activity, as dizocilpine infusion prevented the occurrence of glutamate receptors modifications as well as the development of sensitization.
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PMID:Dizocilpine infusion has a different effect in the development of morphine and cocaine sensitization: behavioral and neurochemical aspects. 1180 63

The physiology of nociception involves a complex interaction of peripheral and central nervous system (CNS) structures, extending from the skin, the viscera and the musculoskeletal tissues to the cerebral cortex. The pathophysiology of chronic pain shows alterations of normal physiological pathways, giving rise to hyperalgesia or allodynia. After integration in the spinal cord, nociceptive information is transferred to thalamic structures before it reaches the somatosensory cortex. Each of these levels of the CNS contain modulatory mechanisms. The two most important systems in modulating nociception and antinociception, the N-methyl-D-aspartate (NMDA) and opioid receptor system, show a close distribution pattern in nearly all CNS regions, and activation of NMDA receptors has been found to contribute to the hyperalgesia associated with nerve injury or inflammation. Apart from substance P (SP), the major facilitatory effect in nociception is exerted by glutamate as the natural activator of NMDA receptors. Stimulation of ionotropic NMDA receptors causes intraneuronal elevation of Ca2+ which stimulates nitric oxide synthase (NOS) and the production of nitric oxide (NO). NO as a gaseous molecule diffuses out from the neuron and by action on guanylyl cyclase, NO stimulates in neighboring neurons the formation of cGMP. Depending on the expression of cGMP-controlled ion channels in target neurons, NO may act excitatory or inhibitory. NO has been implicated in the development of hyperexcitability, resulting in hyperalgesia or allodynia, by increasing nociceptive transmitters at their central terminals. Among the three subtypes of opioid receptors, mu- and delta-receptors either inhibit or potentiate NMDA receptor-mediated events, while kappa opioids antagonize NMDA receptor-mediated activity. Recently, CRH has been found to act at all levels of the neuraxis to produce analgesia. Modulation of nociception occurs at all levels of the neuraxis, thus, eliciting the multidimensional experience of pain involving sensory-discriminative, affective-motivational, cognitive and locomotor components.
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PMID:Nociception, pain, and antinociception: current concepts. 1182 34


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