Capsaicin and nociception.
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The antinociceptive effect of capsaicin to noxious chemical stimuli has been invariably verified. As to thermal or mechanical nociception, however, routine pharmacological methods resulted in conflicting findings. Therefore, using new techniques the nociceptive thresholds of different stimuli were determined on the hindpaw of the rat. After systemic (400 mg/kg s.c.), perineural (1% on the sciatic nerve) and local (5 micrograms into the hindpaw) application of capsaicin the threshold for noxious heat (47.4 +/- 0.08) was shifted upwards by 3.3 degrees C, 4.1 degrees C and 2.9 degrees C, respectively. The changes in mechanonociceptive threshold evoked by pin prick (186 +/- 9 mN force) were more variable. The response to percutaneous xylene application was abolished or markedly inhibited. After systemic application the responsiveness to noxious heat recovered faster than the effect of xylene. C-polymodal nociceptors and some A-delta mechanoheat-sensitive nociceptors isolated from the saphenous nerve of the rat were activated by capsaicin in nanogram doses given close arterially. Five micrograms capsaicin excited few slowly adapting A mechanoreceptors after a long latency, but not A-delta mechanonociceptors or other cutaneous receptors. Proportion of C-polymodal nociceptors was decreased, that of the C-mechanoreceptors was increased after systemic treatment. The role of polymodal-type nociceptors, interaction of other nociceptors, as well as secondary dynamic changes are stressed to explain the antinociceptive effect of capsaicin.Keywords:
Capsaicin
Nociceptor
Saphenous nerve
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We have studied the effect of NE 19550 (olvanil, N-(4-hydroxy-3-methoxyphenyl) methyl-9Z-octadecenamide), a capsaicin analogue with approximately equipotent antinociceptive activity in vivo compared with capsaicin, on nociceptive responses recorded from spinal dorsal horn neurones in vivo and from a spinal ventral root in vitro. In adult rats anaesthetized with halothane, antinociceptive doses of olvanil (20–40 μmol/kg, s.c.) reduced C-fibre responses evoked in wide dynamic range, lumbar dorsal horn neurones, by peripheral transcutaneous electrical stimulation. Intradermal injection of olvanil, localized to a discrete region of the peripheral receptive field, did not activate C-fibres nor change C-fibre evoked activation of dorsal horn neurones. Spinal intrathecal administration of olvanil attenuated C-fibre evoked responses and, at the highest concentration, significantly reduced Aβ-fibre evoked activity. In the neonatal rat spinal cord/tail preparation maintained in vitro, superfusion of the cord with olvanil (500 nM-5 μ M) did not evoke a depolarization but responses to peripheral noxious stimulation were attenuated. In a similar in vitro preparation of the neonatal rat spinal cord, the release of calcitonin gene-related peptide-like immunoreactivity (CGRP-LI) was measured in spinal cord superfusates. Capsaicin (2–10 μM) evoked a large release of CGRP-LI but olvanil (2–10 μM) produced only a small or undetectable release. Following the administration of each substance, however, the release of CGRP-LI evoked by a depolarizing potassium stimulus was significantly attenuated. These data indicate that C-fibre input to the dorsal horn was attenuated by acute systemic doses of olvanil that were antinociceptive in behavioural tests. This effect was unlikely to be due to impairment of C-fibre function by a peripheral locus of action but was more consistent with an action in the spinal cord in which the reduced release of a neurotransmitter substance from afferent nerve terminals may play a prominent role.
Capsaicin
Dorsal root ganglion
Nociceptor
Lumbar Spinal Cord
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Capsaicin can produce a selective and long-lasting neural blockade. Resiniferatoxin (RTX) is an ultrapotent vanilloid agonist with a unique spectrum of activities different from that of capsaicin. We sought to determine whether a single application of RTX to a peripheral nerve could completely prevent the long-lasting mechanical hyperalgesia caused by carrageenan injection. In rat experiments, RTX (0.001%) was administered percutaneously to the sciatic and saphenous nerves before the intraplantar injection of carrageenan. Responses to noxious mechanical (pressure on the paw) and thermal (hot plate) stimulations and changes in paw circumference were measured at various time intervals for 8 days after treatment. The administration of RTX resulted in mechanical and thermal hypoalgesia (for 2 and 8 days, respectively). Inflammatory hyperalgesia was completely prevented by the precarrageenan injection of RTX. Inflammatory enhancement of paw circumference was reduced by RTX (12.0 +/- 2.4 mm versus 6.9 +/- 3.4 mm, P < 0.005). We suggest that the selective nature of the effect of vanilloid agonists on nociception could provide an opportunity for prolonged neural blockade when early mobilization and/or preservation of protective sensation are required.We report that an ultrapotent vanilloid agonist resiniferatoxin can provide a selective and long-lasting neural blockade. Applied to the sciatic and saphenous nerves, it completely prevented pain hypersensitivity caused by prolonged inflammatory process (injection of carrageenan into the paw).
Resiniferatoxin
Hypoalgesia
Capsaicin
Saphenous nerve
Nociceptor
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Polymodal nociceptors respond to mechanical, thermal and chemical stimuli. Whereas sensitivities to heat and to the irritant substance capsaicin have recently been linked via the properties of the vanilloid receptor type 1 receptor ion channel, sensitivity to noxious mechanical stimuli such as the pinpricks used in clinical neurology seems to be unrelated. We investigated the peripheral neural basis of pinprick pain using quantitative psychophysical techniques combined with selective conduction block by nerve compression and selective desensitization by topical capsaicin treatment. Complete A-fibre block by compression of the superficial radial nerve (criterion: loss of first pain sensation) lowered the stimulus–response function for pinprick pain (–82 ± 6% versus baseline). Topical pretreatment of the skin with a 10% capsaicin cream also lowered the pinprick stimulus–response function (–32 ± 10%), whereas laser-evoked heat pain was eliminated completely (–96 ± 2%). Under combined capsaicin desensitization and A-fibre blockade, pinprick pain was eliminated completely (–98 ± 1%). Intradermal injection of 40 μg capsaicin into normal skin between two skin areas that had been pretreated with either capsaicin cream or vehicle produced secondary hyperalgesia with a 260% enhancement of the stimulus–response function for pinprick pain in both areas. In contrast, axon reflexive flare spread only into the vehicle-treated area. These results suggest that capsaicin-sensitive afferents, including polymodal A-fibre and C-fibre nociceptors, make a small contribution to pinprick pain and that capsaicin-insensitive C-fibres do not contribute significantly to either mechanical or heat pain. Pinprick pain is mediated primarily by capsaicin-insensitive A-fibre nociceptors, which include high-threshold mechanoreceptors and type I mechano-heat nociceptors. In addition, central sensitization to input from these A-fibre nociceptors is the primary mechanism that accounts for the enhanced pain in response to punctate mechanical stimuli in the zone of secondary hyperalgesia. These capsaicin-insensitive A-fibre nociceptors may also mediate hyperalgesia in neuropathic pain.
Nociceptor
Capsaicin
Axon reflex
Tachyphylaxis
Stimulus (psychology)
Saphenous nerve
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Capsaicin (Cap) is a pharmacological tool to inactivate nociceptive afferents. The present study was undertaken to investigate the effects of topical application of Cap to sciatic nerve on the formalin-induced expression of proto-oncogene proteins c-fos in the rat spinal cord using immunohistochemical display of fos-like protein. In rats subjected to formalin injection into the hind paw, numerous fos-like immunoreactivity (FLI) neurons were found in the spinal dorsal horn, with heavy labeling in laminae I-II and V-VI. Following pretreatment of Cap, formalin-induced FLI expression was significantly abolished. It was suggested that activation of Cap-sensitive unmyelinated nociceptive afferents following formalin injection was primarily responsible for the activation of c-fos gene. Our data also provided further evidence supporting that topical application was an effective way to block the transmission of noxious primary afferents.
Capsaicin
c-Fos
Immediate early gene
Hindlimb
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Capsaicin
Nociceptor
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Resiniferatoxin (RTX) is an ultrapotent capsaicin analog that binds to the transient receptor potential channel, vanilloid subfamily member 1 (TRPV1). There is a large body of evidence supporting a role for TRPV1 in noxious-mediated and inflammatory hyperalgesic responses. In this study, we evaluated low, graded, doses of perineural RTX as a method for regional pain control. We hypothesized that this approach can provide long-term, but reversible, blockade of a portion of nociceptive afferent fibers within peripheral nerves when given at a site remote from the neuronal perikarya in the dorsal root ganglia. Following perineural RTX application to the sciatic nerve, we demonstrated a significant inhibition of inflammatory nociception that was dose- and time-dependent. At the same time, treated animals maintained normal proprioceptive sensations and motor control, and other nociceptive responses were largely unaffected. Using a range of mechanical and thermal algesic tests, we found that the most sensitive measure following perineural RTX administration was inhibition of inflammatory hyperalgesia. Recovery studies showed that physiologic sensory function could return as early as two weeks post-RTX treatment, however, immunohistochemical examination of the DRG revealed a partial, but significant reduction in the number of the TRPV1-positive neurons. We propose that this method could represent a beneficial treatment for a range of chronic pain problems, including neuropathic and inflammatory pain not responding to other therapies.
Resiniferatoxin
Capsaicin
Nociceptor
Dorsal root ganglion
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Several lines of evidence suggest that different classes of nociceptive afferents mediate the responses produced by different rates of noxious skin heating. More specifically, low skin heating rates evoke nociceptive responses that appear to be mediated by the activation of capsaicin-sensitive C-fiber nociceptors, whereas high skin heating rates appear to produce responses mediated by the activation of other nociceptors. This hypothesis was examined by both electrophysiological and behavioral experiments. This report describes the results of experiments designed to determine whether pharmacologic treatments that selectively alter the activity of C-fiber nociceptive afferents also produce selective effects on foot withdrawal responses to either high or low rates of noxious foot heating. The results these experiments demonstrate that: (1) topical application of a low concentration of capsaicin, which sensitizes C-fiber nociceptors, selectively decreased the latency of responses to low heating rates; (2) topical application of a high concentration of capsaicin, that desensitizes C-fiber nociceptors, selectively increased the latency of responses to low heating rates; (3) low doses of systemic morphine, which selectively attenuate nociception produced by the activation of C-fiber nociceptors, selectively increased response latencies for low skin heating rates. These results support the conclusion that foot withdrawal responses evoked by low skin heating rates are mediated by the activation of capsaicin-sensitive C-fiber nociceptors and foot withdrawal responses evoked by high skin heating rates are mediated by the activation of other nociceptors. This conclusion is supported by the results of the accompanying electrophysiological study which provides direct evidence that low rates of skin heating preferentially activate C-fiber nociceptors while high rates of skin heating preferentially activate Aδ nociceptors.
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Capsaicin
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Capsaicin
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To address the mechanisms of hyperalgesia and dorsal horn plasticity following peripheral tissue inflammation, the effects of adjuvant-induced inflammation of the rat hindpaw on behavioral nociception and nociceptive neuronal activity in the superficial dorsal horn were examined in neonatally capsaicin-treated rats 6–8 weeks of age. Capsaicin treatment resulted in an 82% loss of unmyelinated fibers in L5 dorsal roots, a dramatic reduction of substance P-like immunoreactivity in the spinal cord, and a significant decrease in the percentage of dorsal horn nociceptive neurons that reponded to C-fiber stimulation and noxious heating of the skin. The thermal nociceptive threshold was significantly increased in capsaicin-treated rats, but behavioral hyperalgesia to thermal stimuli still developed in response to inflammation. Following inflammation, there was a significant decrease in mechanical threshold and an increase in response duration to mechanical stimuli in both vehicle- and capsaicin-treated rats, suggesting that a state of mechanical hyperalgesia was also induced. The capsaicin treatment appears to have differential effects on nociceptive specific (NS) and wide-dynamic-range (WDR) neurons in inflamed rats. Expansion of the receptive fields of nociceptive neurons, a measure of the effect of inflammation-induced CNS plasticity, was less extensive for NS than for WDR neurons in capsaicin-treated rats. Compared to vehicle-treated rats, a smaller population of NS neurons, but a similar percentage of WDR neurons, had background activity in inflamed capsaicin-treated rats. C-fiber strength electrical stimulation of the sciatic nerve produced expansion of the receptive fields in a greater portion of NS neurons (53%, P < 0.05) in capsaicin- than in vehicle-treated rats (32%). There was no difference in stimulation-induced expansion of the receptive fields for WDR neurons between vehicle- or capsaicin-treated rats. An Symbol receptor antagonist, MK-801, attenuated the behavioral hyperalgesia and reduced the receptive field size of dorsal horn neurons in inflamed capsaicin- and vehicle-treated rats. The data suggest that while capsaicin-sensitive primary afferents may be involved in neuronal plasticity induced by peripheral tissue inflammation, changes in the capsaicin-insensitive WDR and NS populations are sufficient to produce thermal and mechanical hyperalgesia after the loss of capsaicin-sensitive primary afferents.
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Nociceptor
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The antinociceptive effect of capsaicin to noxious chemical stimuli has been invariably verified. As to thermal or mechanical nociception, however, routine pharmacological methods resulted in conflicting findings. Therefore, using new techniques the nociceptive thresholds of different stimuli were determined on the hindpaw of the rat. After systemic (400 mg/kg s.c.), perineural (1% on the sciatic nerve) and local (5 micrograms into the hindpaw) application of capsaicin the threshold for noxious heat (47.4 +/- 0.08) was shifted upwards by 3.3 degrees C, 4.1 degrees C and 2.9 degrees C, respectively. The changes in mechanonociceptive threshold evoked by pin prick (186 +/- 9 mN force) were more variable. The response to percutaneous xylene application was abolished or markedly inhibited. After systemic application the responsiveness to noxious heat recovered faster than the effect of xylene. C-polymodal nociceptors and some A-delta mechanoheat-sensitive nociceptors isolated from the saphenous nerve of the rat were activated by capsaicin in nanogram doses given close arterially. Five micrograms capsaicin excited few slowly adapting A mechanoreceptors after a long latency, but not A-delta mechanonociceptors or other cutaneous receptors. Proportion of C-polymodal nociceptors was decreased, that of the C-mechanoreceptors was increased after systemic treatment. The role of polymodal-type nociceptors, interaction of other nociceptors, as well as secondary dynamic changes are stressed to explain the antinociceptive effect of capsaicin.
Capsaicin
Nociceptor
Saphenous nerve
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