UMLS:C0344307 - FACTA Search

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Query: UMLS:C0344307 (analgesia)
28,200 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Adenosine exerts its physiological actions by binding to G-protein coupled receptors, four of which have been identified and cloned to date (A1, A2a, A2b and A3). Here we report the development of anti-human adenosine A1, receptor anti-peptide polyclonal antibodies and their use to define the distribution of A1, receptors in human brain regions, spinal cord and trigeminal ganglia by an immunohistochemical approach. Although the distribution of adenosine A1, receptor and its mRNA in the human brain has been investigated in the past by autoradiography and in situ hybridization, this is the first demonstration of localization of the A1, receptors by immunohistochemical means. Our localization data broadly agree with immunohistochemical data published for the human brain obtained using other experimental approaches. Furthermore, we have demonstrated the novel finding that abundant expression of the adenosine A1, receptor protein occurs in the trigeminal ganglia, which may be suggestive of a role of this receptor in analgesia.
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PMID:Immunohistochemical localization of adenosine A1 receptors in human brain regions. 1113 65

Adenosine produces analgesia in the spinal cord and can be formed extracellularly through enzymatic conversion of adenine nucleotides. A transverse push-pull microprobe was developed and characterized to sample extracellular adenosine concentrations of the dorsal horn of the rat spinal cord. Samples collected via this sampling technique reveal that AMP is converted to adenosine in the dorsal horn. This conversion is decreased by the ecto-5'-nucleotidase inhibitor, alpha,beta-methylene ADP. Related behavioral studies demonstrate that AMP administered directly to the spinal cord can reverse the secondary mechanical hyperalgesia characteristic of the intradermal capsaicin model of inflammatory pain. The specific adenosine A(1) receptor antagonist 8-cyclopentyl-1,3-dimethylxanthine (CPT) inhibits the antihyperalgesia produced by AMP. This research introduces a novel microprobe that can be used as an adjunct sampling technique to microdialysis and push-pull cannulas. Furthermore, we conclude that AMP is converted to adenosine in the dorsal horn of the spinal cord by ecto-5'-nucleotidase and subsequently may be one source of adenosine, acting through adenosine A(1) receptors in the dorsal horn of the spinal cord, which produce antihyperalgesia.
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PMID:A novel transverse push-pull microprobe: in vitro characterization and in vivo demonstration of the enzymatic production of adenosine in the spinal cord dorsal horn. 1114 97

Adenosine is a modulator that has a pervasive and generally inhibitory effect on neuronal activity. Tonic activation of adenosine receptors by adenosine that is normally present in the extracellular space in brain tissue leads to inhibitory effects that appear to be mediated by both adenosine A1 and A2A receptors. Relief from this tonic inhibition by receptor antagonists such as caffeine accounts for the excitatory actions of these agents. Characterization of the effects of adenosine receptor agonists and antagonists has led to numerous hypotheses concerning the role of this nucleoside. Previous work has established a role for adenosine in a diverse array of neural phenomena, which include regulation of sleep and the level of arousal, neuroprotection, regulation of seizure susceptibility, locomotor effects, analgesia, mediation of the effects of ethanol, and chronic drug use.
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PMID:The role and regulation of adenosine in the central nervous system. 1128 4

In the central nervous system (CNS), adenosine is an important neuromodulator and regulates neuronal and non-neuronal cellular function (e.g. microglia) by actions on extracellular adenosine A(1), A(2A), A(2B) and A(3) receptors. Extracellular levels of adenosine are regulated by synthesis, metabolism, release and uptake of adenosine. Adenosine also regulates pain transmission in the spinal cord and in the periphery, and a number of agents can alter the extracellular availability of adenosine and subsequently modulate pain transmission, particularly by activation of adenosine A(1) receptors. The use of capsaicin (which activates receptors selectively expressed on C-fibre afferent neurons and produces neurotoxic actions in certain paradigms) allows for an interpretation of C-fibre involvement in such processes. In the spinal cord, adenosine availability/release is enhanced by depolarization (K(+), capsaicin, substance P, N-methyl-D-aspartate (NMDA)), by inhibition of metabolism or uptake (inhibitors of adenosine kinase (AK), adenosine deaminase (AD), equilibrative transporters), and by receptor-operated mechanisms (opioids, 5-hydroxytryptamine (5-HT), noradrenaline (NA)). Some of these agents release adenosine via an equilibrative transporter indicating production of adenosine inside the cell (K(+), morphine), while others release nucleotide which is converted extracellularly to adenosine by ecto-5'-nucleotidase (capsaicin, 5-HT). Release can be capsaicin-sensitive, Ca(2+)-dependent and involve G-proteins, and this suggests that within C-fibres, Ca(2+)-dependent intracellular processes regulate production and release of adenosine. In the periphery, adenosine is released from both neuronal and non-neuronal sources. Neuronal release from capsaicin-sensitive afferents is induced by glutamate and by neurogenic inflammation (capsaicin, low concentration of formalin), while that from sympathetic postganglionic neurons (probably as adenosine 5'-triphosphate (ATP) with NA) occurs following more generalized inflammation. Such release is modified differentially by inhibitors of AK and AD. Following nerve injury, there is an alteration in capsaicin-sensitive adenosine release, as spinal release now is less responsive to opioids, while peripheral release is less responsive to inhibitors of metabolism. Following inflammation, adenosine is released from a variety of cell types in addition to neurons (e.g. endothelial cells, neutrophils, mast cells, fibroblasts). ATP is released both spinally and peripherally following inflammation or injury, and may be converted to adenosine by ecto-5'-nucleotidase contributing an additional source of adenosine. Release of adenosine from both spinal and peripheral compartments has inhibitory effects on pain transmission, as methylxanthine adenosine receptor antagonists reduce analgesia produced by agents which augment extracellular levels of adenosine spinally (morphine, 5-HT, substance P, AK inhibitors) and peripherally (AK inhibitors, AD inhibitors). Increases in extracellular adenosine availability also may contribute to antiinflammatory effects of certain agents (methotrexate, sulfasalazine, salicylates, AK inhibitors), and this could have secondary effects on pain signalling in chronic inflammation. The purpose of the present review is to consider: (a). the factors that regulate the extracellular availability of adenosine in the spinal cord and at peripheral sites; and (b). the extent to which this adenosine affects pain signalling in these two distinct compartments.
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PMID:Adenosine in the spinal cord and periphery: release and regulation of pain. 1278 73

Adenosine analogues have been used by subarachnoid injection for the treatment of inflammatory and neuropathic pain. There is no data on the use of adenosine in peripheral nerve blocks. The aim of the present study was to determine the analgesic efficacy of adenosine in combination with a local anaesthetic solution for brachial plexus (BP) block. With local ethics committee approval, 50 consenting adult patients undergoing upper limb surgery were enrolled in this double-blind, prospective, randomized study. Patients with a history of bronchospastic disease were excluded. Patients were instructed not to take theophylline-containing drugs and beverages for at least one day before surgery or on the first postoperative day. A supraclavicular BP block was performed by injecting a mixture totalling 35 ml made up of prilocaine 1% 10 ml and lignocaine 2% 20 ml with adrenaline 1:200,000, and adenosine 10 mg in 5 ml saline (Group 1) or 5 ml saline (Group 2) as a placebo control group. Postoperative analgesia was assessed by time to first rescue analgesia, analgesic consumption in the first 24 hours, and VAS at rest at 4, 8, 12, 16, 20 and 24 hours. Side-effects were also noted. Vital signs were stable in both groups throughout the operation. There were no significant differences between the groups in onset of motor and sensory block. Time to first pain sensation from block was not significantly longer in the adenosine group (379 +/- 336 min) compared with controls (304 +/- 249 min, mean +/- SD, P = 0.14). Time to first analgesic requirements and analgesic consumption in the first 24 hours were also similar in both study groups. In the present study, the addition of adenosine to local anaesthetic in brachial plexus block did not significantly extend the duration of analgesia.
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PMID:Combination of adenosine with prilocaine and lignocaine for brachial plexus block does not prolong postoperative analgesia. 1471 26

Vanilloid receptor 1 (TRPV1), a nonspecific cation channel expressed primarily in small sensory neurons, mediates inflammatory thermal pain sensation. The function and expression of TRPV1 are enhanced during inflammation and certain neuropathies, leading to sustained hyperalgesia. Activation of TRPV1 in the spinal cord and periphery promotes release of adenosine, which produces analgesia by activating A(1) and A(2A) adenosine receptor (AR) on central and peripheral neurons. This study provides evidence of a direct interaction of AR analogs with TRPV1. Adenosine analogs inhibit TRPV1-mediated Ca(2+) entry in human embryonic kidney (HEK293) cells stably expressing TRPV1 (HEK/TRPV1) and DRG neurons. This inhibition was independent of A(2A)AR activation. Specific binding of [(3)H]resiniferatoxin (RTX) in plasma membrane preparations was inhibited by CGS21680, an A(2A)AR agonist. Similar degrees of inhibition were observed with both agonists and antagonists of ARs. Adenosine analogs inhibited [(3)H]RTX binding to affinity-purified TRPV1, indicative of a direct interaction of these ligands with the receptor. Furthermore, specific capsaicin-sensitive binding of [(3)H]CGS21680 was observed in Xenopus oocyte membranes expressing TRPV1. Capsaicin-induced inward currents in DRG neurons were inhibited by adenosine and agonist and antagonist of A(2A)AR at nanomolar concentrations. Increasing the concentrations of capsaicin reversed the inhibitory response to capsaicin, suggesting a competitive inhibition at TRPV1. Finally, exposure of HEK/TRPV1 cells to capsaicin induced an approximately 2.4-fold increase in proapoptotic cells that was abolished by adenosine analogs. Together, these data suggest that adenosine could serve as an endogenous inhibitor of TRPV1 activity by directly interacting with the receptor protein.
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PMID:Direct interaction of adenosine with the TRPV1 channel protein. 1507 Nov 15

Adenosine (ADO) is an endogenous purine nucleoside that functions as an extracellular signalling molecule. It is released locally at sites of cellular trauma, and acts on specific cell-surface purinergic receptors (termed P1 receptors) near its site of release to exert its effects. Four subtypes of the P1 family of G-protein-coupled receptors have been identified and cloned: A1, A2A, A2B and A3. A considerable body of evidence, including experimental animal data and preliminary clinical reports, indicates that ADO is involved in modulating endogenous antinociceptive processes in the brain and spinal cord. ADO analogues provide analgesic activity after systemic or spinal administration in a broad spectrum of animal pain models. In addition, iv. ADO infusion has shown benefit in human pain states. The spinal cord is a key site for ADO-mediated modulation of nociception. ADO is well known to act as an inhibitory neuromodulator in the central and peripheral nervous system, and it may act to control N-methyl-D-aspartate (NMDA)- and substance P-mediated events in nociception and central sensitisation at the spinal level. ADO is also released at sites of inflammation and it exerts anti-inflammatory effects via multiple mechanisms involving several cell types. These include effects on neutrophil function, endothelial cell permeability, in vivo and in vitro release of tumour necrosis factor (TNF-alpha and collagenase expression in synoviocytes. Accordingly, ADO analogues are effective in several animal models of inflammation, including the rat adjuvant arthritis model. Several therapeutic approaches to pain and inflammation, based on mimicking or modulating the effects of endogenous ADO, are currently under preclinical and clinical investigation. These include the use of ADO itself, the use of direct-acting ADO receptor agonists and the use of agents designed to modulate the levels and, therefore, the actions of ADO in the extracellular space (ADO kinase (AK) inhibitors). Data emerging in the next several years should indicate whether these strategies represent a therapeutically useful new approach to analgesia and inflammation.
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PMID:Adenosine modulation: a novel approach to analgesia and inflammation. 1599 91

We aimed to elucidate the role of alpha(1)-adrenoceptors in adenosine analgesia in the formalin test. Formalin was injected into the hind paw of male CD-1 mice after injection of adenosine A(1) or A(2a) receptor agonists, CPA, [N(6)-cyclopentyladenosine], and CGS21680 [2-p-(2-carboxyethyl)-phenylethylamino-5'-N-ethylcarboxamidoadenosine hydrochloride]. In the behavioral experiment, alpha(1)-adrenoceptors were blocked by an alpha(1)-adrenoceptor antagonist prazosin, 0.01 mg/kg i.p., and the time mice spent paw licking was recorded for the early (0-15 min) and late (15-60 min) phase of formalin pain. In the neurochemical experiments, mice were killed 15 or 45 min after formalin injection. The density of alpha(1)-adrenoceptors was assessed in various brain areas and in the lumbar spinal cord by [(3)H]prazosin autoradiography. Adenosine agonists produced analgesia in both phases of formalin pain, while prazosin showed a tendency to pronociceptive action in the late phase, and antagonized the effect of CGS21680. After formalin injection, alpha(1)-adrenoceptor density was elevated in some brain areas, mainly in the late phase (some contralateral amygdaloid and ipsilateral thalamic nuclei) and depressed in others (early phase in the ipsilateral spinal cord and late phase in both ipsi- and contralateral sensorimotor cortex). Elevation of alpha(1)-adrenoceptor density, which may be interpreted as a defensive response, did not develop in several cases of CPA-pretreated mice. This suggests that the analgesic effect of adenosine A(1) receptor activation renders the defensive response unnecessary. The depression of alpha(1)-adrenoceptors may suggest development of hypersensitivity in a given structure, and this was antagonized by CGS21680, suggesting the role of A(2a) receptors in control of inflammatory formalin pain.
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PMID:Changes induced by formalin pain in central alpha1-adrenoceptor density are modulated by adenosine receptor agonists. 2030 90

Adenosine exerts a key role in analgesia. In the present study, adenosine-induced Ca(2+) responses were revealed by using confocal microscopy imaging in the rat dorsal root ganglia (DRG) neurons in vitro. Our results showed that adenosine could evoke increases in the intracellular Ca(2+) concentration in the DRG neurons. In addition, by application of selective receptor antagonists, two types of receptors, A1R and A3R, were identified to be involved in the adenosine-induced Ca(2+) release from intracellular stores in neurons. Altogether, these results suggest that confocal microscopy imaging combined with fluorescent dyes could help to detect the analgesic-induced ion signaling in single cell.
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PMID:Evidence for A1 and A 3 receptors mediating adenosine-induced intracellular calcium release in the dorsal root ganglion neurons by using confocal microscopy imaging. 2435 76

More than 1.5 billion people worldwide suffer from chronic pain, yet current treatment strategies often lack efficacy or have deleterious side effects in patients. Adenosine is an inhibitory neuromodulator that was previously thought to mediate antinociception through the A1 and A2A receptor subtypes. We have since demonstrated that A3AR agonists have potent analgesic actions in preclinical rodent models of neuropathic pain and that A3AR analgesia is independent of adenosine A1 or A2A unwanted effects. Herein, we explored the contribution of the GABA inhibitory system to A3AR-mediated analgesia using well-characterized mouse and rat models of chronic constriction injury (CCI)-induced neuropathic pain. The deregulation of GABA signaling in pathophysiological pain states is well established: GABA signaling can be hampered by a reduction in extracellular GABA synthesis by GAD65 and enhanced extracellular GABA reuptake via the GABA transporter, GAT-1. In neuropathic pain, GABAAR-mediated signaling can be further disrupted by the loss of the KCC2 chloride anion gradient. Here, we demonstrate that A3AR agonists (IB-MECA and MRS5698) reverse neuropathic pain via a spinal mechanism of action that modulates GABA activity. Spinal administration of the GABAA antagonist, bicuculline, disrupted A3AR-mediated analgesia. Furthermore, A3AR-mediated analgesia was associated with reductions in CCI-related GAD65 and GAT-1 serine dephosphorylation as well as an enhancement of KCC2 serine phosphorylation and activity. Our results suggest that A3AR-mediated reversal of neuropathic pain increases modulation of GABA inhibitory neurotransmission both directly and indirectly through protection of KCC2 function, underscoring the unique utility of A3AR agonists in chronic pain.
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PMID:Engagement of the GABA to KCC2 signaling pathway contributes to the analgesic effects of A3AR agonists in neuropathic pain. 2587 79

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