Peripheral neural mechanisms of cutaneous hyperalgesia following mild injury by heat

LaMotte, R. H.; Thalhammer, J. G.; Torebjörk, H. E.; Robinson, C. Jane

doi:10.1523/jneurosci.02-06-00765.1982

Cited by 256 publications

(81 citation statements)

References 54 publications

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“…41 This would explain the long-lasting and robust hyperalgesia to heat in rodents 6,10 but not humans after incision (current study). The enhanced warm detection (warm hyperesthesia) after skin incision remained stable over the entire observation period of 72 h. However, sensitization of warm fibers has not been reported so far 30 and is thus unlikely to be the underlying mechanism. Alternatively, the warm hyperesthesia may be caused indirectly due to local warming by an increased blood flow 42 ; however, in rodents, local warming of the incision site is very discrete.…”

Section: Somatosensory Changes At the Site Of Incision (Primary Zone)mentioning

confidence: 88%

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Modality-specific Somatosensory Changes in a Human Surrogate Model of Postoperative Pain

Fißmer¹,

Klein

Magerl

et al. 2011

Anesthesiology

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Background: Postoperative pain remains a challenging problem in part because the underlying mechanisms are still not well understood. There is a compelling need for translational studies in human models of postoperative pain to bridge the gap between animal models und human clinical studies. Methods: Somatosensory changes using Quantitative Sensory Testing for up to 72 h after an experimental 4-mm incision were characterized in 20 male volunteers. Results: During incision, perceived pain was 29 on a 100-point numeric rating scale and declined rapidly over the next 60 min. After incision, thresholds at the site of incision were lowered to painful heat (primary heat hyperalgesia; P Ͻ 0.01, effect size: 0.68) but not to painful cold (P Ͼ 0.05, effect size: 0.00). Remote to the incision, mechanical pain thresholds were lowered, pain ratings were increased, and an area of hyperalgesia occurred (P Ͻ 0.05, effect size: 0.56; P Ͻ 0.01, effect size: 0.70; P Ͻ 0.01, respectively; secondary mechanical hyperalgesia). All signs of heat and mechanical hyperal-

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Section: Somatosensory Changes At the Site Of Incision (Primary Zone)mentioning

confidence: 88%

“…10,12 This fits well with the general finding that hyperalgesia to heat is typically restricted to the site of the injury in humans. 30,33,54 Moreover, we refrained from maintaining skin temperature because it is technically unfeasible to keep skin temperature constant at the incision side due to enhanced blood perfusion.…”

Section: Technical Considerationsmentioning

confidence: 99%

Modality-specific Somatosensory Changes in a Human Surrogate Model of Postoperative Pain

Fißmer¹,

Klein

Magerl

et al. 2011

Anesthesiology

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“…The primary hyperalgesia at the site of capsaicin application features increased sensory responses to both mechanical and heat stimuli, attributed to sensitization of cutaneous nociceptor terminals, both of the common polymodal type (Campbell and Meyer 1983;LaMotte et al 1982LaMotte et al , 1983LaMotte et al , 1992Torebjörk et al 1984) and of the more recently described mechano-insensitive type of C nociceptor (Davis et al 1993;Meyer et al 1991;Schmelz et al 2000b;Schmidt et al 1995). The neural mechanisms underlying the secondary hyperalgesia in surrounding skin remain unclear.…”

Section: Introductionmentioning

confidence: 99%

Two Types of C Nociceptors in Human Skin and Their Behavior in Areas of Capsaicin-Induced Secondary Hyperalgesia

Serra¹,

Campero²,

Bostock³

et al. 2004

Journal of Neurophysiology

117

111

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Ochoa. Two types of C nociceptors in human skin and their behavior in areas of capsaicin-induced secondary hyperalgesia. J Neurophysiol 91: 2770 -2781, 2004. First published February 4, 2004 10.1152/jn.00565.2003. Peripheral nociceptor sensitization is accepted as an important mechanism of cutaneous primary hyperalgesia, but secondary hyperalgesia has been attributed to central mechanisms since evidence for sensitization of primary afferents has been lacking. In this study, microneurography was used to test for changes in sensitivity of C nociceptors in the area of secondary hyperalgesia caused by intradermal injection of capsaicin in humans. Multiple C units were recruited by electrical stimulation of the skin at 0.25 Hz and were identified as discrete series of dots in raster plots of spike latencies. Nociceptors slowed progressively during repetitive stimulation at 2 Hz for 3 min. According to their response to mechanical stimulation, nociceptors could be classified as either mechano-sensitive (CM) or mechano-insensitive (CM i ). These two nociceptor subtypes had different axonal properties: CM i units slowed by 2% or more when stimulated at 0.25 Hz after a 3-min pause, whereas CM units slowed by Ͻ1%. This stimulation protocol was used before capsaicin injection to identify nociceptor subtype without repeated probing, thus avoiding possible mechanical sensitization. Capsaicin, injected 10 -50 mm away from the site of electrical stimulation, had no effect on any of 29 CM units, but induced bursts of activity in 11 of 15 CM i units, after delays ranging from 0.5 to 18 min. The capsaicin injections also sensitized a majority of the CM i units, so that 11 of 17 developed immediate or delayed responsiveness to mechanical stimuli. This sensitization may contribute a peripheral C fiber component to secondary hyperalgesia.

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“…The resulting pain intensity and duration often increase after the initial tissue or nerve damage. Tissue and peripheral nerve injury can sensitize primary afferents and spinal cord dorsal horn neurons, which results in secondary pain hypersensitivity (LaMotte et al 1982; Torebjork et al 1992; Woolf et al 1988). The release of inflammatory mediators from injured tissues and inflammatory cells, including prostaglandins (Martin et al 1987; Trebino et al 2003) and bradykinin (Liang et al 2001;Rueff and Dray 1993), can stimulate and sensitize nociceptors (peripheral sensitization).…”

mentioning

confidence: 99%

Increased Nociceptive Input Rapidly Modulates Spinal GABAergic Transmission Through Endogenously Released Glutamate

Zhou

Zhang

Chen³

et al. 2007

Journal of Neurophysiology

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Stimulation of nociceptive primary afferents elicits pain by promoting glutamatergic transmission in the spinal cord. Little is known about how increased nociceptive input controls GABAergic tone in the spinal dorsal horn. In this study, we determined how increased nociceptive inflow affects GABAergic spontaneous inhibitory postsynaptic currents (sIPSCs) of lamina II neurons by using whole cell recordings in rat spinal cord slices. Bath application of capsaicin for 3 min induced a long-lasting inhibition of sIPSCs in 50% of the neurons tested. In the other half of the neurons, capsaicin either increased the frequency of sIPSCs (34.6%) or had no effect on sIPSCs (15.4%). The GABA A current elicited by puff application of GABA was not altered by capsaicin. Capsaicin did not inhibit sIPSCs in rats treated with intrathecal pertussis toxin. Also, capsaicin failed to inhibit sIPSCs in the presence of ionotropic glutamate receptor antagonists or in the presence of both LY341495 and CPPG (group II and group III metabotropic glutamate receptor antagonists, respectively). However, when LY341495 or CPPG was used alone, capsaicin still decreased the frequency of sIPSCs in some neurons. Additionally, bradykinin significantly inhibited sIPSCs in a population of lamina II neurons and this inhibitory effect was also abolished by LY341495 and CPPG. Our study provides novel information that stimulation of nociceptive primary afferents rapidly suppresses GABAergic input to many dorsal horn neurons through endogenous glutamate and activation of presynaptic group II and group III metabotropic glutamate receptors. These findings extend our understanding of the microcircuitry of the spinal dorsal horn involved in nociception. I N T R O D U C T I O NNociceptive information generated from noxious stimuli is relayed primarily by unmyelinated primary afferents to secondorder neurons in the superficial dorsal horn of the spinal cord. The resulting pain intensity and duration often increase after the initial tissue or nerve damage. Tissue and peripheral nerve injury can sensitize primary afferents and spinal cord dorsal horn neurons, which results in secondary pain hypersensitivity (LaMotte et al. 1982; Torebjork et al. 1992; Woolf et al. 1988). The release of inflammatory mediators from injured tissues and inflammatory cells, including prostaglandins (Martin et al. 1987; Trebino et al. 2003) and bradykinin (Liang et al. 2001;Rueff and Dray 1993), can stimulate and sensitize nociceptors (peripheral sensitization). Furthermore, increased release of glutamate from primary afferents and activation of postsynaptic ionotropic glutamate receptors (iGluRs) in the spinal cord can enhance the excitability of dorsal horn neurons (central sensitization) (Dougherty et al. 1992;Leem et al. 1996). However, the cellular mechanisms for the hypersensitivity of dorsal horn neurons after tissue and nerve injury are not fully known.The lamina II of the spinal cord is a critical site for the relay and processing of dynamic modulation of sensory information. Ye...

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Peripheral neural mechanisms of cutaneous hyperalgesia following mild injury by heat

Cited by 256 publications

References 54 publications

Modality-specific Somatosensory Changes in a Human Surrogate Model of Postoperative Pain

Modality-specific Somatosensory Changes in a Human Surrogate Model of Postoperative Pain

Two Types of C Nociceptors in Human Skin and Their Behavior in Areas of Capsaicin-Induced Secondary Hyperalgesia

Increased Nociceptive Input Rapidly Modulates Spinal GABAergic Transmission Through Endogenously Released Glutamate

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