UMLS:C0030193 - FACTA Search

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Query: UMLS:C0030193 (pain)
261,466 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The recent literature on the antinociceptive action of ionotropic glutamate receptor antagonists is reviewed with special emphasis on their clinical potential. Actually the glutamatergic pathways descending from the brain stem into the spinal cord may generate analgesia. However, physiologically more important is that glutamate and aspartate are apparently the main neurotransmitters along the ascending nociceptive pathways in the spinal cord. Glutamate, aspartate and their receptors can be detected in particularly high concentrations in the dorsal root ganglia and the superficial laminae (I, II) of the spinal cord. In low doses glutamate receptor antagonists only slightly elevate the threshold of the physiological pain sensation. However, they suppress the process of pathological sensitisation i.e. lowering of the pain threshold seen upon excessive or lasting stimulation of C-fibre afferents, a process that takes place during inflammation or other kinds of tissue injury. At electrophysiological level antagonists of both the NMDA- and AMPA/kainate receptors inhibit wind up i.e. lasting activation of the polymodal, second-order sensory neurones in the deeper layers of the dorsal horn. During sensitisation the resting Mg(++) blockade of transmembrane Ca(++) channels is abolished, certain second messenger pathways are activated, the transcription of many genes is enhanced leading to overproduction of glutamate and other excitatory neurotransmitters and expression of Na(+) channels in the primary sensory neurones activated at lower level of depolarisation. This cascade of events leads to increased excitability of the pain pathways. NMDA antagonists are apparently more potent in experimental models of neuropathic pain, whereas AMPA antagonists are more effective in abolition of hyperalgesia seen during experimental inflammation. Clinically, of the previously known NMDA antagonists amantadine, dextromethorphan and ketamine have been tested, the latter extensively. Ketamine has been found quite active in certain cases of neuropathic pain and it reduced the opiate demand when used for postoperative analgesia. However, in other types of clinical pain their efficacy is less convincing. Not being registered there are no clinical data on the AMPA antagonists. There are, however, some investigational new drugs and some novel compounds in the stage of preclinical development which antagonise the AMPA receptors in competitive fashion or allosterically. Of the latter molecules 2,3-benzodiazepines are particularly promising.
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PMID:The role of ionotropic glutamate receptors in nociception with special regard to the AMPA binding sites. 1194 38

Owing to different mechanisms of analgesia, we hypothesized that the combination of ketamine and tramadol could produce synergistic or additive antinociceptive effects. Swiss albino mice were administered intraperitoneally with ketamine, tramadol, a combination of ketamine and tramadol, or saline, and the resulting antinociceptive effects were tested in the mouse tail-flick and formalin tests. The potencies of the two drugs alone or in combination were obtained by fitting data to the Sigmoid Emax equation. Isobolographic analysis was performed to evaluate the interaction. CNS depression was also monitored. Results showed that tramadol exhibited apparent dose-dependent effects in the tail-flick test, and in phase 1 and phase 2 of the formalin test. Ketamine dose-dependently inhibited the phase 2 responses, but failed to modify the phase 1 and tail-flick responses. Combination of tramadol and ketamine produced significant synergistic interactions only in phase 2 of the formalin test (P < 0.05). The synergistic combinations also displayed less CNS depression than when an equianalgesic dose of ketamine was administered alone. We conclude that in the acute thermal or chemical pain model, ketamine is not effective and the net effect of ketamine and tramadol in combination was simply additive after systemic administration. However, the coadministration produced synergistic antinociception in the chemical-induced persistent pain model.
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PMID:Isobolographic analysis of the analgesic interactions between ketamine and tramadol. 1200 57

The aim of the present study was to clarify the neurophysiological changes associated with analgesic and behavioral effects of low-dose ketamine HCl in patients suffering from chronic neuropathic pain. Ten in-patients with neuropathic pain participated in this single-blind, placebo-controlled study after giving written informed consent. Following intravenous injections of a saline solution (placebo), three bolus injections of 5 mg ketamine HCl were administered at 5 min intervals. Changes in pain perception were assessed using a numerical rating scale for pain. Behavioral changes, including psychotomimetic effects, were assessed using the Brief Psychiatric Rating Scale (BPRS). Electroencephalograms (EEG) and electrooculograms (EOG) were recorded continuously throughout the testing period. One minute EEG and closed-eye eye movements were quantified. The effects of ketamine were evaluated by comparing the neurophysiological and behavioral parameters obtained from the placebo and ketamine trials. Pain reduction was significantly correlated with ketamine-induced changes in hallucinatory behavior and excitement as measured by the BPRS. Ketamine injections caused a significant decrease in the EEGalpha amplitude without an accompanying reduction in EEG frequency. The EEGalpha amplitude reduction at the right central electrode was significantly related to subjective pain relief. Subanesthetic doses of ketamine significantly decreased rapid eye movements, but did not initiate slow eye movements. In conclusion, the present EEG-EOG/behavioral results indicate that ketamine-induced failure of neural integration between cortical-subcortical regions induces psychotic symptoms and alters pain perception on neuropathic pain.
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PMID:Effects of low-dose ketamine on neuropathic pain: An electroencephalogram-electrooculogram/behavioral study. 1210 52

Ketamine is known to provide analgesic effects without an anesthetic when administered in a low dose. We previously reported that a tablet containing ketamine had analgesic effects in patients with neuropathic pain. In the present study, we compared the plasma concentration profiles of the enantiomers of ketamine and its active metabolite, norketamine, up to 8 h after the administration of 20 mg of ketamine by injection, after the administration of two tablets containing 25 mg of ketamine, after the administration of two sublingual tablets containing 25 mg of ketamine, after the insertion of a suppository containing 50 mg of ketamine, and after the application of a nasal spray containing 25 mg of ketamine to three healthy volunteers. The plasma concentration of ketamine biexponentially declined after the administration by injection; the value of T(1/2beta) for ketamine was approximately 120 min. The bioavailability of the tablet was estimated to be approximately 20%; the area under the plasma concentration-time curve, (AUC)(0-->8 h), of norketamine was approximately 500 ng h/ml in both enantiomers. The bioavailabilities of the sublingual tablet and the suppository were estimated to both be approximately 30%; the AUC(0-->8 h) of norketamine was 280-460 ng h/ml in both enantiomers. The plasma concentration profiles of the sublingual tablet and the suppository were almost similar to that of the tablet. The bioavailability of the nasal spray was estimated to be approximately 45%, which was the highest value among the preparations tested, and the AUC(0-->6 h) of norketamine was low (approximately 100 ng h/ml) in both enantiomers. These pharmacokinetic findings suggested that all of the ketamine preparations tested in this study may be useful for the alleviation of neuropathic pain. We propose that the type of ketamine preparation should be selected in accordance with the patient's disease condition and the required dosage amount of ketamine.
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PMID:Plasma concentration profiles of ketamine and norketamine after administration of various ketamine preparations to healthy Japanese volunteers. 1251 77

Cold allodynia and hyperalgesia are frequent clinical findings in patients with neuropathic pain. While there have been several clinical studies showing the involvement of central sensitization mechanisms and N-methyl-D-aspartate (NMDA) receptor activation in mechanical allodynia/hyperalgesia and ongoing pain, the mechanisms of thermal allodynia and hyperalgesia have received less attention. The aim of the present study was to examine the effect of the NMDA-receptor antagonist ketamine on thermal allodynia/hyperalgesia, ongoing pain and mechanical allodynia/hyperalgesia in patients with neuropathic pain (11 patients with post-traumatic neuralgia and one patient with post-herpetic neuralgia). All the patients were known to suffer from severe cold allodynia (cold pain detection threshold (CPDT): 23.8 degrees C, median value). The mu-opioid agonist alfentanil was used as an active control. The study design was double-blind and placebo-controlled and the drugs were administered i.v. (bolus dose and infusion). CPDT in the asymptomatic contralateral area was found to be significantly decreased (cold allodynia) compared to CPDT in site- and age-matched normal controls. Heat pain detection thresholds were found to be normal and no consistent heat hyperalgesia occurred. Alfentanil significantly reduced cold allodynia (by increasing CPDT) in symptomatic area (P=0.0076). Ketamine did not significantly increase the threshold. Significant and marked reductions of hyperalgesia to cold (visual analogue score at threshold value) were seen following both alfentanil (4.5 before, 1.4 after, median value) and ketamine (6.8 before, 0.4 after, median value). Alfentanil and ketamine also significantly reduced ongoing pain and mechanical hyperalgesia. It is concluded that NMDA-receptor mediated central sensitization is involved in cold hyperalgesia, but since CPDT remained unaltered, it is likely that other mechanisms are present.
Pain 2003 Feb
PMID:Cold allodynia and hyperalgesia in neuropathic pain: the effect of N-methyl-D-aspartate (NMDA) receptor antagonist ketamine--a double-blind, cross-over comparison with alfentanil and placebo. 1258 65

Epidural opioids have been reported to provide superior analgesia in acute pain management. Despite the fact that the required doses are low, major side effects such as respiratory depression may still occur. In an effort to maximize analgesia and to minimize the rate of side effects, epidural NMDA receptor antagonists, especially ketamine, may be co-administered with opioids. This study investigated whether ketamine had beneficial effects on fentanyl- or morphine-induced antinociception in an acute pain model in rats. In male Wistar rats, an epidural catheter was placed under general anaesthesia. After 1 week the animals were subjected to the tail withdrawal reaction (TWR) test. After determination of the basal reaction latencies, fentanyl, morphine, ketamine or combinations of an opioid with ketamine were administered epidurally. TWR latencies were measured for up to 2h after treatment. Both opioids showed a dose related antinociceptive effect. Fentanyl had a fast onset and a short duration of action whereas the reverse was true for morphine. Ketamine exhibited only limited antinociceptive properties. In the combinations, ketamine improved morphine-induced antinociception both in terms of maximal possible effect (MPE) as well as in duration of action. The combination of fentanyl with ketamine did not result in any improvement, neither in terms of MPE nor in duration of action. Moreover, increasing doses of ketamine tended to decrease the MPE of various doses of fentanyl. These data confirm that ketamine, contrary to opioids, does not possess important antinociceptive properties in an acute test such as the TWR test. Furthermore, these data indicate that additive drugs such as ketamine may have different effects on different opioids.
Eur J Pain 2003
PMID:Epidural ketamine potentiates epidural morphine but not fentanyl in acute nociception in rats. 1260 Jul 93

Ketamine is an NMDA receptors antagonist, with a potent anaesthetic effect. NMDA receptors are involved in nociceptive modulation, in the wind-up phenomenon, in peripheral receptive fields expansion, in primary and secondary hyperalgesia, in neuronal plasticity. Ketamine effects are well-known: it produces a state of "dissociative anaesthesia", amnesia, and, at the same time, it mantains the respiratory drive effective and supports the sistemic arterial blood pressure. Anaesthesiologists are also familiar with its side-effects, like the increase of salivar and bronchial secretions, the possible increase of intracranial and pulmonary pressures and the dysphoric effect that may produce vivid and sometimes unpleasant dreams. Reviewing scientific data and studies about the use of ketamine in children, many considerations come out: at first they considered the effects of the racemic ketamine, then they evaluated the S-enantiomer. Many surveys studied the effects (analgesia, sedation, side-effects) of different doses or different routes of administration. Other studies were designed to compare ketamine to clonidine or opioids as adjuvants in paediatric regional anaesthesia with local anesthetic drugs, in order to prolong analgesia. In our Children's Hospital, we use ketamine in the operating room, in intensive care unit and for any procedure in hospital wards. The suggested doses are: Epidural or caudal route (as an ajuvant for local anaesthetic agents, in the treatment of postoperative pain): 0.5 mg/kg. Sedative/analgesic effect (for algesic procedures): 1-2 mg/kg i.v. Continuous infusion (intensive care unit): 0.5 mg/kg/h, with a range from 20-30 microg/kg/min to 80 microg/kg/min, depending on the age of the patient.
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PMID:Ketamine: a new look to an old drug. 1276 86

The idea of using Ketamine to treat chronic pain is mainly based on the central antinoceptive effect of the substance acting as a noncompetitive antagonist at the NMDA-receptor. In the present meta analysis over a period from 1/1981 up to 6/1996 twelve publications (1994-1996), which have dealt the use of Ketamine for patients with chronic pain, are evaluated and discussed. The entire positive evaluation of the drug is based on the results of the studies under consideration. The studies investigating 88 cases are classified, i.e. seven studies are assigned to level 3, two studies to level 4, and three studies to level 5. A significant reduction of pain has been proven for patients with neuropathic pain by four cross-over-studies comparing the drug with placebo. However, observations have been restricted to a few hours after the administration of the drug. A positive effect of Ketamine as compared with opioids has been demonstrated by three studies, one of them with statistical significance. Positive long term results have been observed by two studies considering the subcutaneous and intravenous application of Ketamine (72-480 mg, daily) to 14 cancer pain patients, to whom opioids have been administered with insufficient effects before. A successful five-week-application (oral) of Ketamine has been described convincingly in a case report of a patient with postherpetic neuralgia. Two studies interpret the additional intrathecal administration of Ketamine to cancer patients as a possibility of either impeding the development of tolerance of the local anesthetic or reducing morphine requirements. Only one paper has dealt with the known side effects of Ketamine. Here, the therapy had to break off in two cases. In nine cases the side effects could be suppressed by Droperidol. For the future, research with more study power is necessary to establish Ketamine in the therapy of chronic pain.
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PMID:[Ketamine for treatment of chronic pain: meta-analysis]. 1279 15

In a randomized, double-blinded study, we evaluated the analgesic effect of ketamine in the management of pain in a surgical intensive care unit after major abdominal surgery. Patients received morphine patient-controlled analgesia with either placebo (Group M) or ketamine (Group K). Morphine was administered with initial loading doses of 2 mg until the visual analog scale (VAS) score was <30 and thereafter with bolus doses of 1 mg and a lockout time of 7 min. Ketamine was administered with an initial bolus of 0.5 mg/kg followed by a perfusion of 2 micro g x kg(-1) x min(-1) during the first 24 h and 1 micro g x kg(-1) x min(-1) during the following 24 h. The 4-h cumulative morphine doses were measured over 48 h. The VAS scores at rest and at mobilization were measured every 4 h during 48 h. A total of 101 patients were enrolled, and 93 were analyzed (41 in Group K and 52 in Group M). VAS scores at rest and at mobilization were similar. The cumulative consumption of morphine was significantly smaller in Group K (P < 0.05). We concluded that small doses of ketamine were a valuable adjunct to opioids in surgical intensive care unit patients after major abdominal surgery.
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PMID:The effects of small-dose ketamine on morphine consumption in surgical intensive care unit patients after major abdominal surgery. 1293 13

Ketamine is increasingly being used as an adjuvant to opioids in the treatment of refractory cancer pain. This systematic review examines the available evidence. Randomized, controlled trials, with or without crossover, were included. Studies were identified from MEDLINE, EMBASE, CANCERLIT, the Cochrane Library, handsearched reference lists from review articles and chapters from standard textbooks on pain and palliative care and reference lists from papers retrieved. Four randomized, controlled studies were identified. Two were excluded due to poor quality. Both included studies concluded that ketamine improves morphine treatment in cancer pain. Quantitative meta-analysis was not possible. The available evidence is not sufficient to conclude that ketamine improves the effectiveness of opioid treatment in cancer pain. High quality, randomized, controlled trials with larger numbers of patients and standardized, clinically relevant routes of administration of ketamine are needed.
J Pain Symptom Manage 2003 Sep
PMID:Ketamine as adjuvant to opioids for cancer pain. A qualitative systematic review. 1527 89

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