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Query: UMLS:C0423716 (Neuropathic pain)
 1,417 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Neuropathic pain may result from sustained firing of sensory neurones. The questions are what initiates and what stops that firing? Spontaneous firing of a modified Hodgkin-Huxley model axon is induced here by: (1) a depolarizing shift in the K+ channel activation parameter; and (2) a positive change in the K+ equilibrium potential. The duration and pattern of spontaneous discharge is seen to be critically dependent on the level and kinetics of Na+ channel slow inactivation. Slow inactivation of voltage-gated ion channels could be major factors in the induction and treatment of neuropathic pain.
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PMID:Slow Na+ channel inactivation and bursting discharge in a simple model axon: implications for neuropathic pain. 913 79

Neuropathic pain or persistent dysesthesias may be initiated by mechanical, chemical, or ischemic damage to peripheral sensory nerves. In animal models of neuropathic pain, transection or constrictive injury to peripheral nerves produces ectopic discharges originating at both injury sites and related dorsal root ganglia (DRG), and, consequently, hyperexcitability in associated dorsal horn (DH) neurons of the spinal cord. Since ectopic discharges are inhibited by agents that block voltage-sensitive Na+ channels, it has been postulated that accumulation of Na+ channels in the membrane at nerve injury sites may contribute to, or be responsible for, the development of ectopic neuronal activity (ENA). The present study therefore, tested the sensitivity of ENA to intravenously administered tetrodotoxin (TTX), an extremely potent and selective Na+ channel blocker. Comparative effects of TTX on cardiac parameters such as heart rate (HR) and diastolic blood pressure (DBP) were also studied. Experiments were performed on adult male Sprague-Dawley rats in which the common sciatic nerve had been transected 4-10 days earlier. Neuromal activity was measured in fine bundles of microfilaments teased from sciatic nerves, and extracellular microelectrode recordings were made from DRG and DH neurons. Cardiovascular parameters were recorded simultaneously. Intravenously administered TTX induced dose-dependent inhibition of ENA, with that originating from neuromas being the most sensitive; ED50 values (expressed as microg/kg, with 95% confidence limits) for neuromal, DRG and DH neuron activity were: 0.8 (0.6-1.2), 4.3 (2.2-8.4) and 36.2 (16.1-81.3), respectively. Inhibition of ENA in neuromas and DRG did not recover within 10 min after 100 or 300 microg/kg TTX. By comparison, the ED50 value for the initial decrease of HR was 17.9 (15.0-21.5) microg/kg, and partial recovery occurred within approximately 3 min. These data support the hypothesis that Na+ channel accumulation contributes to the generation of ectopic discharges in neuromas and DRG, and suggest that TTX-sensitive Na+ channels located at the nerve injury site and DRG play an important role in the genesis of neuropathic pain.
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PMID:Tetrodotoxin inhibits neuropathic ectopic activity in neuromas, dorsal root ganglia and dorsal horn neurons. 927 86

Neuropathic pain may be produced, at least in part, by the increased activity of primary afferent neurons. Studies have suggested that an accumulation of voltage-gated sodium channels at the site of peripheral nerve injury is a primary precursory event for subsequent afferent hyperexcitability. In this study, a human sodium channel (hPN3, SCN10A) has been cloned from the lumbar 4/5 dorsal root ganglia (DRG). Expression of hPN3 in Xenopus oocytes showed that this clone is a functional voltage-gated sodium channel. The amino acid sequence of hPN3 is most closely related to the rat PN3/SNS sodium channels which are expressed primarily in the small neurons of rat DRGs. The homologous relationship between rPN3 and hPN3 is defined by (i) a high level of sequence identity (ii) sodium currents that are highly resistant to tetrodotoxin (TTX) (iii) similar tissue distribution profiles and (iv) orthologous chromosomal map positions. Since rPN3/SNS has been implicated in nociceptive transmission, hPN3 may prove to be a valuable target for therapeutic agents against neuropathic pain.
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PMID:A tetrodotoxin-resistant voltage-gated sodium channel from human dorsal root ganglia, hPN3/SCN10A. 983 20

Neuropathic pain is thought to arise from ectopic discharges at the site of injury within the peripheral nervous system, and is manifest as a general increase in the level of neuronal excitability within primary afferent fibres and their synaptic contacts within the spinal cord. Voltage-activated Na+ channel blockers such as lamotrigine have been shown to be clinically effective in the treatment of neuropathic pain. Na+ channels are structurally diverse comprising a principal a subunit (of which there are variable isoforms) and two auxiliary subunits termed beta1 and beta2. Both beta subunits affect the rates of channel activation and inactivation, and can modify alpha subunit density within the plasma membrane. In addition, these subunits may interact with extracellular matrix molecules to affect growth and myelination of axons. Using in situ hybridization histochemistry we have shown that the expression of the beta1 and beta2 subunits within the dorsal horn of the spinal cord of neuropathic rats is differentially regulated by a chronic constrictive injury to the sciatic nerve. At days 12-15 post-neuropathy, beta1 messenger RNA levels had increased, whereas beta2 messenger RNA levels had decreased significantly within laminae I, II on the ipsilateral side of the cord relative to the contralateral side. Within laminae III-IV beta2 messenger RNA levels showed a small but significant decrease on the ipsilateral side relative to the contralateral side, whilst expression of beta1 messenger RNA remained unchanged. Thus, differential regulation of the individual beta subunit types may (through their distinct influences on Na+ channel function) contribute to altered excitability of central neurons after neuropathic injury.
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PMID:The sodium channel auxiliary subunits beta1 and beta2 are differentially expressed in the spinal cord of neuropathic rats. 1018 42

Neuropathic pain, a form of chronic pain caused by injury to or disease of the peripheral or central nervous system, is a formidable therapeutic challenge to clinicians because it does not respond well to traditional pain therapies. Our knowledge about the pathogenesis of neuropathic pain has grown significantly over last 2 decades. Basic research with animal and human models of neuropathic pain has shown that a number of pathophysiological and biochemical changes take place in the nervous system as a result of an insult. This property of the nervous system to adapt morphologically and functionally to external stimuli is known as neuroplasticity and plays a crucial role in the onset and maintenance of pain symptoms. Many similarities between the pathophysiological phenomena observed in some epilepsy models and in neuropathic pain models justify the rational for use of anticonvulsant drugs in the symptomatic management of neuropathic pain disorders. Carbamazepine, the first anticonvulsant studied in clinical trials, probably alleviates pain by decreasing conductance in Na+ channels and inhibiting ectopic discharges. Results from clinical trials have been positive in the treatment of trigeminal neuralgia, painful diabetic neuropathy and postherpetic neuralgia. The availability of newer anticonvulsants tested in higher quality clinical trials has marked a new era in the treatment of neuropathic pain. Gabapentin has the most clearly demonstrated analgesic effect for the treatment of neuropathic pain, specifically for treatment of painful diabetic neuropathy and postherpetic neuralgia. Based on the positive results of these studies and its favourable adverse effect profile, gabapentin should be considered the first choice of therapy for neuropathic pain. Evidence for the efficacy of phenytoin as an antinociceptive agent is, at best, weak to modest. Lamotrigine has good potential to modulate and control neuropathic pain, as shown in 2 controlled clinical trials, although another randomised trial showed no effect. There is potential for phenobarbital, clonazepam, valproic acid, topiramate, pregabalin and tiagabine to have antihyperalgesic and antinociceptive activities based on result in animal models of neuropathic pain, but the efficacy of these drugs in the treatment of human neuropathic pain has not yet been fully determined in clinical trials. The role of anticonvulsant drugs in the treatment of neuropathic pain is evolving and has been clearly demonstrated with gabapentin and carbamazepine. Further advances in our understanding of the mechanisms underlying neuropathic pain syndromes and well-designed clinical trials should further the opportunities to establish the role of anticonvulsants in the treatment of neuropathic pain.
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PMID:Anticonvulsants for neuropathic pain syndromes: mechanisms of action and place in therapy. 1112 21

Neuropathic pain is frequently associated with hyperexcitability of primary afferents, characterized by spontaneous impulses and repetitive firing. Electrophysiology and molecular biology reveal changes in dorsal root ganglion Na+ channels under conditions of neuropathic pain, but the manner by which these changes alter the physiology of sensory afferents remains unknown. Equally mysterious is the mechanism by which i.v. local anaesthetic-like Na+ channel blockers suppress neuropathic pain behaviour at concentrations well below those reported for channel inhibition. We have compared the anti-allodynic actions of i.v. lidocaine (L) and stereoisomers of mexiletine (R-M, S-M), in rats after spinal nerve ligation, with their ability: (1) to inhibit fast, tetrodotoxin-sensitive neuronal Na+ currents, elicited by brief (1 ms) pulses, at 10 Hz, from 'resting' potentials (-80, -60 mV) and (2) to suppress the seconds long plateau and the repetitive firing produced in axons by slowing of Na+ channel inactivation (e.g. using scorpion alpha-toxins). Both L and R-M at 5-10 microM relieved allodynia; S-M was ineffective. Na+ currents also were inhibited by M, with affinities that were increased by both repetitive 'firing' (K(R,S) = 5 microM) and depolarization of the 'resting' membrane (K(R) = 15 microM; K(S) = 30 microM). Stereopotency ratios depended on the manner in which different states of the channel were inducted. Both L and M shortened the action potential's 'plateau' in alpha-toxin treated axons, without reducing the spike, and suppressed repetitive firing with IC(50)s = 5 microM, and no stereoselectivity. These findings together demonstrate that Na+ channel blockers, at 'therapeutic' concentrations, can inhibit neuronal hyperexcitability.
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PMID:Therapeutic concentrations of local anaesthetics unveil the potential role of sodium channels in neuropathic pain. 1177 46

Neuropathic pain is a debilitating chronic syndrome that often arises from injuries to peripheral nerves. Such pain has been hypothesized to be the result of an aberrant expression and function of sodium channels at the site of injury. Here, we show that intrathecal administration of specific antisense oligodeoxynucleotides (ODN) to the peripheral tetrodotoxin (TTX)-resistant sodium channel, NaV1.8, resulted in a time-dependent uptake of the ODN by dorsal root ganglion (DRG) neurons, a selective "knock-down" of the expression of NaV1.8, and a reduction in the slow-inactivating, TTX-resistant sodium current in the DRG cells. The ODN treatment also reversed neuropathic pain induced by spinal nerve injury, without affecting non-noxious sensation or response to acute pain. These data provide direct evidence linking NaV1.8 to neuropathic pain. As NaV1.8 expression is restricted to sensory neurons, this channel offers a highly specific and effective molecular target for the treatment of neuropathic pain.
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PMID:Inhibition of neuropathic pain by decreased expression of the tetrodotoxin-resistant sodium channel, NaV1.8. 1179 Apr 77

Neuropathic pain, whether of peripheral or central origin, is characterized by a neuronal hyperexcitability in damaged areas of the nervous system. In peripheral neuropathic pain, damaged nerve endings exhibit abnormal spontaneous and increased evoked activity, partly due to an increased and novel expression of sodium channels. In central pain, although not explored in detail, the spontaneous pain and evoked allodynia are also best explained by a neuronal hyperexcitability. The peripheral hyperexcitability is due to a series of molecular changes at the level of the peripheral nociceptor, in dorsal root ganglia, in the dorsal horn of the spinal cord, and in the brain. These changes include abnormal expression of sodium channels, increased activity at glutamate receptor sites, changes in gamma-aminobutyric acid (GABA-ergic) inhibition, and an alteration of calcium influx into cells. The neuronal hyperexcitability and corresponding molecular changes in neuropathic pain have many features in common with the cellular changes in certain forms of epilepsy. This has led to the use of anticonvulsant drugs for the treatment of neuropathic pain. Carbamazepine and phenytoin were the first anticonvulsants to be used in controlled clinical trials. Studies have shown these agents to relieve painful diabetic neuropathy and paroxysmal attacks in trigeminal neuralgia. Subsequent studies have shown the anticonvulsant gabapentin to be effective in painful diabetic neuropathy, mixed neuropathies, and postherpetic neuralgia. Lamotrigine, a new anticonvulsant, is effective in trigeminal neuralgia, painful peripheral neuropathy, and post-stroke pain. Other anticonvulsants, both new and old, are currently undergoing controlled clinical testing. The most common adverse effects of anticonvulsants are sedation and cerebellar symptoms (nystagmus, tremor and incoordination). Less common side-effects include haematological changes and cardiac arrhythmia with phenytoin and carbamazepine. The introduction of a mechanism-based classification of neuropathic pain, together with new anticonvulsants with a more specific pharmacological action, may lead to more rational treatment for the individual patient with neuropathic pain.
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PMID:Anticonvulsants in neuropathic pain: rationale and clinical evidence. 1188 43

Neuropathic pain is often resistant to opioids, so other medication classes, such as tricyclic antidepressants, anticonvulsants, and local anesthetics, are often used. Central sensitization, or pain 'wind-up', may perpetuate chronic neuropathic pain even when ongoing peripheral sensory input is absent. Wind-up is thought to cause allodynia, hyperalgesia, and hyperpathia. Receptors such as NMDA, AMPA, and M-glu have recently been identified for their role in central sensitization or pain 'wind-up'. Ketamine has been proposed recently for neuropathic pain secondary to its NMDA receptor activity. The current application as a topical gel stems from the theory that ketamine has peripheral action at both opioid and Na+-K+ channels. This case study involved 5 patients from 25 to 70 years old (3 RSD, 1 lumbar radiculopathy, 1 post-herpetic neuralgia). Dose used was determined by site and surface area of involvement and ranged from 0.093 mg/kg to 9.33 mg/kg. All five patients reported significant pain relief at initial application and wished to continue treatment. The average numerical analogue scale (NAS) score preapplication was 8.8. The average 15 minutes post application NAS was 1.6. Patients reported alterations in temperature sensation, feelings of relaxation and decreased tension in the area of application, and pain relief. Reduction in numerical pain scores postapplication of ketamine gel ranged from 53-100% using a 1-10 numerical pain intensity scale. No significant side effects were reported. Ketamine Gel may provide clinicians with a new option in the battle against chronic neuropathic pain. Until further information is available and larger trials can be conducted, we can only recommend this type of therapy for refractory cases in which all primary and secondary options have been exhausted.
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PMID:Topical ketamine gel: possible role in treating neuropathic pain. 1510 68

Neuropathic pain is caused by functional abnormalities of structural lesions in the peripheral or central nervous system, and occurs without peripheral nociceptor stimulation. Many common diseases, such as postherpetic neuralgia, trigeminal neuralgia, diabetic neuropathy, spinal cord injury, cancer, stroke, and degenerative neurological diseases may produce neuropathic pain. Recently, theories have been proposed that state there are specific cellular and molecular changes that affect membrane excitability and induce new gene expression after nerve injury, thereby allowing for enhanced responses to future stimulation. In addition, the ectopic impulses of neuroma, changes of sodium and calcium channels in injured nerves, sympathetic activation, and deficient central inhibitory pathway contribute to the mechanisms of neuropathic pain. Currently, treatment of neuropathic pain is still a challenge. Pharmacotherapies (antidepressants, antiepileptics) remain the basis of Dr. Long-Sun Ro neuropathic pain management. However, patient satisfaction in the results of the treatment of neuropathic pain is still disappointing. Since it has been established that intense noxious stimulation produces a sensitization of central nervous neurons, it may be possible to direct treatments not only at the site of peripheral nerve injury, but also at the target of central changes. In order to provide better pain control, the mechanism-based approach in treating neuropathic pain should be familiar to physicians. In the future, it is hoped that a combination of new pharmacotherapeutic developments, careful clinical trials, and an increased understanding of the contribution and mechanisms of neuroplasticity will lead to an improvement in the results of clinical treatments and prevention of neuropathic pain.
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PMID:Neuropathic pain: mechanisms and treatments. 1632 50


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