Non-noxious A fiber afferent input enhances capsaicin-induced mechanical hyperalgesia in the rat.

Intradermal injection of capsaicin induces primary hyperalgesia at the injection site and secondary hyperalgesia in the surrounding undamaged skin. The secondary hyperalgesia is thought to be due to central sensitization of the dorsal horn neurons while primary hyperalgesia is caused by sensitization of nociceptors in the damaged skin. In this study, we asked if additional non-noxious afferent input from the undamaged skin influences the already developed secondary hyperalgesia, which follows an intradermal injection of capsaicin. Capsaicin dissolved in olive oil was injected into the middle of the hind paw of male Sprague-Dawley rats (250-300 g) under gaseous anesthesia. This produced a decrease in the mechanical threshold at the base of the toes for hind limb withdrawals lasting for 1-2h, thus showing a short-lasting (hours) secondary hyperalgesia. When the capsaicin injection was immediately followed by repeated non-noxious mechanical stimuli or weak electrical stimuli (A fiber strength) applied to the area of secondary hyperalgesia (toes) for 30 min, the reduction of the mechanical threshold lasted longer than 24h. These results suggest that non-noxious A fiber afferent input can powerfully modulate central sensitization in the spinal dorsal horn, causing the duration of the secondary hyperalgesia to be greatly extended.     

Mechanisms of adrenosensitivity in capsaicin induced hyperalgesia.

It is well known that iontophoresis of norepinephrine in capsaicin treated skin is followed by an increase in thermal hyperalgesia. It is unclear if this action on nocicepitive afferents involves the release of prostaglandins. The aim of the present study was to determine: (1) the effect of norepinephrine iontophoresis on spontaneous and evoked pain in the human skin after topical application of capsaicin; (2) the effect of cyclooxygenase (COX) inhibition on changes in pain perception induced by norepinephrine application. METHODS: Ten volunteers were included in the study. Iontophoresis of norepinephrine or saline was performed in a randomized cross over design on the volar aspect of the forearm after topical application of capsaicin. In the second part of the study single iv. injections of saline or acetylsalicylic acid were performed in a randomized double blind cross over design. After the injection norepinephrine iontophoresis was performed on the skin treated with topical capsaicin. Spontaneous pain, mechanical hyperalgesia as well as warm and heat pain thresholds were measured before and after each iontophoresis. RESULTS: Norepinephrine did enhance spontaneous pain and mechanical and thermal hyperalgesia in capsaicin treated skin. Inhibition of COX I and II had no effect on the norepinephrine induced changes in pain perception. CONCLUSION: The results do not support the assumption that in human skin sensitized by topical capsaicin application of norepinephrine acts on nociceptive afferents via the release of prostaglandins. Thus, a direct action of norepinephrine on adrenergic receptors in the membrane of the afferent fibers is most likely.     

The mu-opioid agonist remifentanil attenuates hyperalgesia evoked by blunt and punctuated stimuli with different potency: a pharmacological evaluation of the freeze lesion in humans

Experimental pain models inducing hyperalgesia, i.e. an increased sensitivity to noxious stimuli often present in clinical pain, are important tools for studying antinociceptive drug profiles. The correct interpretation of results obtained in these models necessitates their mechanistic understanding. This study evaluated the freeze lesion, an experimental model of hyperalgesia, in humans. Twelve healthy subjects were tested with mechanical (brush, punctuated and blunt) and electrical (5, 250, and 2000 Hz sine wave current) stimuli before and after freezing the skin, and during a computer-controlled infusion of the mu-opioid agonist remifentanil targeting five different plasma concentrations between 0 and 6 ng/ml in a two-staged, single occasion, randomized, and double blind study design. Pharmacodynamic modeling techniques were used to describe the effect of freezing and drug administration on the mechanical and electrical pain thresholds. Freezing the skin resulted in hyperalgesia to blunt and punctuated stimuli and lowered the respective pain threshold by 29 and 73%. Hyperalgesia to brushing or electrical stimuli was not detected. Remifentanil attenuated hyperalgesia to blunt stimuli about twice as potently as hyperalgesia to punctuated stimuli, as indicated by a significantly steeper linear relationship between the remifentanil plasma concentration and the increase of the pain threshold to blunt stimuli. Remifentanil attenuated electrical pain with greater potency for low frequency stimulation. The potency difference of remifentanil suggests that different neuronal mechanisms mediate hyperalgesia to blunt and punctuated stimulation. Absence of brush-evoked and electrical hyperalgesia is compatible with the view that mechanical hyperalgesia to blunt and punctuated stimulation of the freeze lesion is predominantly caused by a peripheral mechanism.     

Secondary hyperalgesia persists in capsaicin desensitized skin

Several lines of evidence suggest that secondary hyperalgesia to punctate mechanical stimuli arises from central sensitization to the input from primary afferent nociceptors. Conventional C-fiber nociceptors respond to heat stimuli and yet heat hyperalgesia is absent in the region of secondary hyperalgesia. This evidence suggests that the central sensitization to nociceptor input does not involve heat sensitive nociceptors. To test this hypothesis, we investigated whether desensitization of heat sensitive nociceptors by topical application of capsaicin led to an alteration in the secondary hyperalgesia. Two 2x2 cm areas on the volar forearm, separated by 1 cm, were treated in 10 healthy volunteers. One of the areas was desensitized by treatment with 10% topical capsaicin (6 h/day for 2 days). The other site served as vehicle control. Hyperalgesia was produced 2 days later by an intradermal injection of capsaicin (50 microg, 10 microl) at a point midway between the two treatment areas. Secondary hyperalgesia to noxious mechanical stimuli was investigated by using a blade probe (32 and 64 g) attached to a computer-controlled mechanical stimulator. In the area of topical capsaicin treatment, there was a marked increase in heat pain threshold and decrease in heat pain ratings indicating a pronounced desensitization of heat sensitive nociceptors. However, touch threshold and pain to pinching stimuli were not significantly altered. The intradermal capsaicin injection led to the development of a similar degree of secondary hyperalgesia at both the vehicle and capsaicin treatment areas. These results indicate that capsaicin insensitive nociceptive afferents play a dominant role not only in normal mechanical pain but also in secondary hyperalgesia to noxious mechanical stimuli.     

Persistent secondary hyperalgesia after gastrocnemius incision in the rat.

Secondary hyperalgesia, an exaggerated response to stimuli applied to undamaged tissue surrounding an injury, is a common consequence of tissue injury and inflammation. It is well established that the etiology of secondary hyperalgesia is sensitization of central neurons but the exact mechanism and its role in certain clinical pain states is unclear. In the present experiments, we studied responses to punctate and non-punctate mechanical stimuli and to heat applied to the plantar aspect of the hindpaw remote to an incision in the gastrocnemius region of the rat hindlimb. Median withdrawal thresholds to von Frey filaments were reduced 2h after incision of skin, fascia and muscle (gastrocnemius incision, n = 9) and remained reduced through postoperative day 6 (p < 0.05 vs sham). Only a transient reduction in withdrawal threshold occurred after incision of skin and fascia (skin incision, n = 10). No enhanced responsiveness to blunt mechanical stimulation or reduction in withdrawal latency to heat was present after gastrocnemius incision (p > 0.05 vs sham, n = 9 each group). Reduced withdrawal thresholds were blocked by i.t. administration of morphine and by local anesthetic injection at the test site 2h and 2 days after gastrocnemius incision. These pharmacological data provide evidence that reduced withdrawal thresholds after gastrocnemius incision are nociceptive behaviors indicating persistent secondary hyperalgesia. Because the behaviors have a similar time course to secondary hyperalgesia in postoperative patients, the model will be useful to evaluate the mechanisms for secondary mechanical hyperalgesia after incision, its pharmacological characteristics and its potential role in persistent postoperative pain.     

Effect of capsaicin treatment on nociceptors in rat glabrous skin one day after plantar incision

Dilute capsaicin produces a differential effect on incision-related pain behaviors depending upon the test; it reduces heat hyperalgesia and guarding pain but not mechanical hyperalgesia. This suggests that common mechanisms for heat hyperalgesia and guarding pain occur, and distinct mechanisms exist for mechanical hyperalgesia. The purpose of the present study was to evaluate the effect of capsaicin treatment on the activity of cutaneous nociceptors sensitized by incision to understand the mechanisms for the selective action of dilute capsaicin on incisional pain. We compared the effect of 0.05% capsaicin vs. vehicle treatment on pain behaviors after incision and on the activity of nociceptors from these same rats using the in vitro glabrous skin–nerve preparation. Immunohistochemical expression of protein gene product 9.5 (PGP9.5), neurofilament 200, calcitonin gene related peptide (CGRP) and isolectin B4 (IB4) in skin was also evaluated 1 week after 0.05% capsaicin infiltration. Infiltration of 0.05% capsaicin decreased CGRP and IB4/PGP9.5-immunoreactivity of nociceptors in skin. The same dose of capsaicin that inhibited heat hyperalgesia and guarding behavior interfered with chemo- and heat sensitivity of C-fibers. Neither mechanical hyperalgesia nor mechanosensitivity of nociceptors was affected by capsaicin, suggesting that the concentration of capsaicin used in this study did not cause fiber degeneration. These results demonstrate that nociceptors desensitized by capsaicin contribute to heat hyperalgesia and guarding pain after plantar incision. These putative TRPV1-expressing C-fibers are sensitized to heat and acid after incision, and the transduction of heat and chemical stimuli after plantar incision is impaired by dilute capsaicin.     

Activation of TRPV1 and TRPA1 leads to muscle nociception and mechanical hyperalgesia

The involvement of TRPV1 and TRPA1 in mediating craniofacial muscle nociception and mechanical hyperalgesia was investigated in male Sprague–Dawley rats. First, we confirmed the expression of TRPV1 in masseter afferents in rat trigeminal ganglia (TG), and provided new data that TRPA1 is also expressed in primary afferents innervating masticatory muscles in double-labeling immunohistochemistry experiments. We then examined whether the activation of each TRP channel in the masseter muscle evokes acute nocifensive responses and leads to the development of masseter hypersensitivity to mechanical stimulation using the behavioral models that have been specifically designed and validated for the craniofacial system. Intramuscular injections with specific agonists for TRPV1 and TRPA1, capsaicin and mustard oil (MO), respectively, produced immediate nocifensive hindpaw responses followed by prolonged mechanical hyperalgesia in a concentration-dependent manner. Pretreatment of the muscle with a TRPV1 antagonist, capsazepine, effectively attenuated the capsaicin-induced muscle nociception and mechanical hyperalgesia. Similarly, pretreatment of the muscle with a selective TRPA1 antagonist, AP18, significantly blocked the MO-induced muscle nociception and mechanical hyperalgesia. We confirmed these data with another set of selective antagonist for TRPV1 and TRPA1, AMG9810 and HC030031, respectively. Collectively, these results provide compelling evidence that TRPV1 and TRPA1 can functionally contribute to muscle nociception and hyperalgesia, and suggest that TRP channels expressed in muscle afferents can engage in the development of pathologic muscle pain conditions.     

Cannabinoid agonists attenuate capsaicin-induced responses in human skin

The induction of hyperalgesia upon capsaicin administration requires activation of specific sub-classes of nociceptive afferent C-fibres providing nociceptive input to the central nervous system.It has been demonstrated in animal models that the endocannabinoid anandamide has anti-hyperalgesic properties upon capsaicin stimulation, albeit it also binds to vanilloid receptors. In the present study we topically administered the cannabinoid receptor ligand HU210 to human skin and investigated its effects on capsaicin-induced pain and hyperalgesia.We demonstrated that pre-treatment with HU210 significantly reduced the perception of pain following the administration of capsaicin. Heat pain thresholds were significantly reduced by capsaicin application measured 5 and 30min after administration. In contrast, at the HU210 pre-treated skin sites capsaicin failed to induce heat hyperalgesia during the fifth minute of administration. Secondary mechanical hyperalgesia to touch (allodynia) was measured during the fifth, 15th and 30th minute after capsaicin administration. In comparison to the ethanol control site, the area of touch-evoked allodynia was significantly reduced at the HU210 skin site during the first two measures. However, 30min after the administration of capsaicin no significant differences of allodynia were observed between the HU210 and ethanol pre-treated skin.The present study provided evidence for analgesic and anti-hyperalgesic properties of a topically applied cannabinoid receptor ligand, which might have important therapeutic implications in humans.     

Primary and secondary hyperalgesia can be differentiated by postnatal age and ERK activation in the spinal dorsal horn of the rat pup

Noxious C-fibre stimulation produces increased sensitivity within the injured area (primary hyperalgesia), and a surrounding zone of secondary hyperalgesia. As significant changes in nociceptive processing occur during development, we compared C-fibre induced primary and secondary hyperalgesia in rat pups aged 3, 10 and 21 postnatal (P) days. Hyperalgesia was measured by electromyography flexion reflex recordings following mustard oil or capsaicin at the site of (primary hyperalgesia), or distant to (secondary hyperalgesia) hindpaw mechanical stimuli. Primary hyperalgesia was induced at all postnatal ages, whereas secondary hyperalgesia could not be demonstrated at P3 but was evident at P10 and P21. At P3, extracellular signal-regulated kinase (ERK) protein is present in the dorsal horn, but hindpaw capsaicin produced minimal ERK activation restricted to the fourth lumbar segment. At P21, capsaicin induced intense phosphoERK expression in the superficial dorsal horn throughout several lumbar segments, consistent with the spread of secondary hyperalgesia. Intrathecal administration of the MEK (ERK kinase) inhibitor PD98059 prevented mustard oil and capsaicin-induced secondary hyperalgesia at P21, but had no effect on primary hyperalgesia at P3 or P21. These results provide evidence that primary and secondary hyperalgesia are differentially modulated during development. Furthermore, since ERK activation is required for secondary hyperalgesia, phosphoERK expression can be used to map the spatial distribution of neuronal activation in the spinal cord. Understanding changing responses to injury in the developing nervous system is important for clinical paediatric practice, and will enhance our ability to target the most effective site with a developmentally appropriate analgesic regime.     

Spatial mapping of the zone of secondary hyperalgesia reveals a gradual decline of pain with distance but sharp borders

The purpose of this study was to examine how pain to punctate mechanical stimuli varies with position within the zone of secondary hyperalgesia. Secondary hyperalgesia was produced by an intradermal injection of capsaicin (50 microg) into the volar forearm of human volunteers (n=9). Before and at 20, 60 and 100 min after the capsaicin injection, a computer-controlled electromechanical stimulator was used to deliver controlled-force stimuli to the skin via a 12-mm wide, 100-microm thick blade probe. Three forces (16, 32 and 64 g; 1 s) were each applied in a random order to 10 sites spaced in 1-cm increments along a line starting 1 cm from the injection site and ending near the wrist. At 40 and 80 min after capsaicin injection the 'zone of hyperalgesia' was determined with use of a hand-held 20-g von Frey probe. Whereas, before capsaicin, the blade probe produced little or no pain, after capsaicin the 32-g and 64-g stimuli evoked pain consistently within but not outside the border of secondary hyperalgesia determined with the von Frey probe. Within the zone of hyperalgesia the average pain ratings to the 64-g stimulus decreased exponentially with distance from the injection site. Surprisingly, the space constant for this exponential decay was large (about 18 cm), and thus the decrease in pain ratings from the center to the edge of the secondary zone was small (37%). However, pain ratings dropped precipitously just outside the zone of secondary hyperalgesia. This finding unlikely reflects a ceiling effect because pain ratings within the zone of secondary hyperalgesia increased linearly with force. The relatively uniform pain ratings to the blade stimuli within the zone of secondary hyperalgesia and the sharp border that delimits the zone of hyperalgesia indicate that this sensory disturbance approaches being an 'all-or-nothing' phenomenon. Thus, a two-state model for central plasticity is needed to explain secondary hyperalgesia.     

Spontaneous discharge and increased heat sensitivity of rat C-fiber nociceptors are present in vitro after plantar incision

Postoperative pain is characterized by spontaneous pain at the surgical site and increased pain due to movements. To study postoperative pain mechanisms, we investigated discharge properties of mechano-heat sensitive C-fiber afferents innervating the rat glabrous hindpaw skin 1 day after plantar incision. Behaviors indicating spontaneous pain, heat and mechanical hyperalgesia were present 1 day after incision. Recording of afferents using in vitro glabrous skin-nerve preparation showed that more C-fibers from the incision had spontaneous discharge than control rats. The spontaneously discharging fibers from incised rats had lower heat response threshold compared with fibers without spontaneous activity. In all fibers less than 2 mm from the incision, an increased percentage responded to lower temperatures (35-41 degrees C), the mean heat response threshold was 3.1 degrees C less, the stimulus-response function for heat evoked response was shifted to the left and the total number of impulses in response to a 33-48 degrees C heat stimulus was increased. Heat responses of C-fibers more than 2 mm from the incision, however, were not different from control. The mean mechanical response thresholds, measured by a servo force-controlled stimulator, were not different between groups. The total spikes evoked at supra-threshold mechanical stimulation were not increased in afferents from the incision. In conclusion, 1 day after incision, when behaviors indicating spontaneous pain, heat and mechanical hyperalgesia are present, C-fibers close to incision showed spontaneous discharge and sensitization to heat but not to mechanical stimuli, in vitro.     

Secondary hyperalgesia and perceptual wind-up following intradermal injection of capsaicin in humans

Wind-up and secondary hyperalgesia both are related to central sensitization, but whereas the former is explained by homosynaptic facilitation, the latter is due to heterosynaptic facilitation. To investigate possible interactions between both types of facilitation, we tested for alterations of perceptual wind-up in the secondary hyperalgesic skin zone adjacent to a capsaicin injection with light touch (by a cotton wisp) and punctate stimuli (calibrated von Frey hairs and pin pricks). Temporal summation of pain sensation (perceptual wind-up) was only observed with a clearly noxious stimulus (pin prick) presented at a repetition frequency of 0.6 s⁻¹, but not 0.2 s⁻¹. Pain ratings to trains of pin pricks reached a plateau after 3–4 repetitions, which was 1.65 times the initial rating (`wind-up ratio'). Injection of capsaicin induced a tenderness to mechanical stimuli in adjacent uninjured skin (secondary hyperalgesia), including hyperalgesia to light touch (allodynia) and hyperalgesia to punctate stimuli. Hyperalgesia to punctate stimuli was characterized by a leftward shift of the stimulus response function, corresponding to a decrease in pain threshold and an increase of painfulness of suprathreshold stimuli by a factor of 3–4. After capsaicin, the difference between the ratings of the first and last stimuli of trains of pin pricks was increased, but the ratio was unchanged. This behavior is equivalent to an increase in effective stimulus intensity, and could be mimicked by increasing the pin prick force from 20 mN to 40 and 80 mN in normal skin. Thus, the leftward shift of the stimulus response function fully accounts for all alterations of pain sensitivity to punctate stimuli in the zone of secondary hyperalgesia. We conclude that when the gain of spinal transmission was changed in secondary hyperalgesia, the gain of wind-up remained unchanged. These findings indicate that secondary hyperalgesia (heterotopic facilitation) and wind-up of pain sensation (homotopic facilitation) are independent phenomena.     

Vasodilatation in hyperalgesic rat skin evoked by stimulation of afferent A beta-fibers: further evidence for a role of dorsal root reflexes in allodynia.

In areas of secondary hyperalgesia, innocuous mechanical stimuli evoke pain (allodynia). We have proposed that this is produced by a central pre-synaptic interaction whereby A beta-fibers evoke spike activity (dorsal root reflexes) in nociceptive afferents (Pain, 68 (1996) 13). This activity should conduct centrally, evoking allodynia, and peripherally, evoking neurogenic vasodilatation. Here we tested this hypothesis by examining the effects of electrical stimulation of A beta-fibers on cutaneous blood flow before and after producing secondary hyperalgesia in anesthetized rats. Cutaneous blood flow was recorded in the hind paw skin innervated by the sural nerve using a laser Doppler flowmeter. The sural nerve was prepared for electrical stimulation, and the evoked activity was recorded from the sciatic nerve in continuity. Electrical stimulation (1 Hz, 4 x 0.2 ms pulses, 20 s) was applied to the sural nerve at 2T (A beta-fibers only) and 4T and 6T (A beta + A delta-fibers). Flux was recorded at baseline and after capsaicin or mustard oil application outside the sural nerve territory. The effects of intravenous administration of the calcitonin gene-related peptide (CGRP) receptor antagonist, alpha-CGRP(8-37), or of section of the sciatic nerve or of the L4-L6 dorsal roots were examined. Selective activation of the sural nerve A beta-fibers reliably evoked increases in cutaneous blood flow close to areas of chemical irritation or skin damage. A beta-fiber-evoked vasodilatation was abolished by sciatic nerve or dorsal root section and had a spatial arrangement and optimal stimulation pattern suggesting a central synaptic interaction similar to that responsible for dorsal root reflexes. The flux increases were dose-dependently and reversibly inhibited by alpha-CGRP(8-37), indicating that the A beta-fiber-evoked vasodilatation resulted from the antidromic activation of nociceptive cutaneous afferent fibers. These results support our hypothesis by showing activation of nociceptive primary afferents by A beta-fibers in areas of allodynia in a manner consistent with a pre-synaptic interaction evoking dorsal root reflexes.     

Early and late effects of prolonged topical capsaicin on cutaneous sensibility and neurogenic vasodilatation in humans.

Cutaneous sensibility and neurogenic vasodilatation (flare) were measured before, during and after long-term topical application of capsaicin in humans. Each subject applied a vehicle cream containing 0.075% capsaicin (Axsain, GalenPharma Inc.) to a 4 cm2 area of skin on one volar forearm and vehicle alone to an identical treatment area on the other forearm, according to a double-blind procedure. Each substance was applied 4 times/day for 6 weeks. Psychophysical measurements of sensory detection thresholds, magnitude of suprathreshold heat pain, magnitude and duration of histamine-induced itch and flare area were obtained before, at 1, 3 and 7 days after the first application, and once a week thereafter for a total of 8 weeks. Capsaicin produced mild burning in all subjects which diminished in magnitude and duration over several weeks. Capsaicin significantly altered detection thresholds for heat pain and the magnitude of pain produced by suprathreshold painful stimuli. Mean detection threshold for heat pain was lowered 1.6 degrees C following 1 day of capsaicin application but subsequently increased to become elevated 3.5 degrees C after 6 weeks of application. In addition, mean magnitude of suprathreshold heat pain diminished progressively after 1 week. Heat pain thresholds returned to or near pretreatment values within 2 weeks after discontinuing application. Detection thresholds for touch, cold sensation and pain induced by low temperature and by mechanical stimulation were not altered by capsaicin. Similarly, capsaicin did not alter the magnitude or duration of itch produced by intradermal injection of 1 microgram histamine. However, the area of flare produced by histamine was significantly reduced in capsaicin-treated skin. These studies demonstrate that prolonged application of capsaicin at low concentration selectively diminishes sensations of heat pain and neurogenic vasodilatation, presumably via desensitization of heat-sensitive nociceptors. It is also shown that the decrease in heat pain is temporary and is maintained with repeated capsaicin application. There appears to be a therapeutic role for capsaicin in cutaneous painful syndromes mediated, at least in part, by activity of heat-sensitive nociceptors.     

The peripheral apparatus of muscle pain: evidence from animal and human studies

The peripheral apparatus of muscle pain consists of nociceptors that can be excited by endogenous substances and mechanical stimuli. Histologically, the nociceptors are free nerve endings supplied by group III (thin myelinated) and group IV (nonmyelinated) afferents with conduction velocities less than 30 m/s. At the molecular level, nociceptors have receptors for algesic substances, such as bradykinin, serotonin, and prostagladin E2. The purinergic receptors and tetrodotoxin-resistant sodium channels might be new important targets for the treatment of muscle pain. Algesic substances (capsaicin, bradykinin, serotonin, potassium chloride, and hypertonic saline) and other stimuli (ischemia, strong mechanical stimuli, and electrical stimuli) have been shown to induce nociception from muscle in animals and muscle pain in humans. Muscle nociceptors can be sensitized to chemical and mechanical stimuli. Contrary to a former belief, the sensitization is not an unspecific process; rather, it is caused by endogenous algesic substances binding to highly specific receptor molecules in the membrane of the nociceptive ending. For example, animal studies showed that serotonin sensitizes muscle nociceptors to chemical and mechanical stimuli. Later, human studies showed that serotonin combined with bradykinin induces muscle hyperalgesia to pressure. The sensitization process by endogenous substances that are likely to be released during trauma or inflammatory injury is probably the best established peripheral mechanism for muscle tenderness and hyperalgesia.     

Experimental characterization of the effects of acute stresslike doses of hydrocortisone in human neurogenic hyperalgesia models

Relative hypothalamic-pituitary-adrenal axis dysfunction has been described as a common feature of several dysfunctional pain syndromes, and its end hormone cortisol may thus constitute a protective factor against the development of chronic pain. We investigated the potential influence of experimentally induced stresslike hypercortisolism on the induction of neurogenic hyperalgesia using 2 human surrogate models: secondary hyperalgesia after intradermal capsaicin injection into the volar forearm, and perceptual windup in normal skin. In a double-blind, placebo-controlled, randomized, crossover study, a psychophysical study was performed in 10 healthy subjects (median age 23 years) examining the effects of 40 mg orally administered hydrocortisone. Numeric pain ratings were assessed for punctate pinprick and light touch stimuli applied to the zone of secondary hyperalgesia adjacent to the capsaicin injection and to the contralateral control side. In addition, visual analog ratings were assessed for repetitive pinprick stimulation of the noninjected arm. Hydrocortisone significantly attenuated the late phase of capsaicin-induced pain by nearly 50%, and hyperalgesia to pinprick stimuli by 33% (both P < .05). Baseline mechanical pain and dynamic mechanical allodynia remained unaltered. Temporal summation (windup) to mechanical pain stimuli and electrically induced windup of second pain (tested in an independent cohort of 10 other subjects) were also unchanged. The selective effects of hydrocortisone on pinprick hyperalgesia but not pinprick pain suggest an antihyperalgesic rather than analgesic effect. The findings suggest that hypothalamic-pituitary-adrenal axis reactivity might be an important mechanism in resilience to dysfunctional pain syndromes.     

The cannabinoid receptor agonist WIN 55,212-2 mesylate blocks the development of hyperalgesia produced by capsaicin in rats.

Although it is well known that cannabinoids produce antinociception in acute pain models, there is less information on the ability of cannabinoids to alleviate hyperalgesia. In the present study, we determined whether cannabinoids attenuated the development of hyperalgesia produced by intraplantar injection of capsaicin in rats. In normal, untreated animals, intraplantar injection of 10 microg capsaicin produces nocifensive behavior (elevation of the injected paw) suggestive of pain, an increase in the frequency of withdrawal from punctate mechanical stimuli applied to the paw (mechanical hyperalgesia) and a decrease in the latency of withdrawal from noxious heat (heat hyperalgesia). Separate groups of animals were pretreated intravenously with vehicle, the cannabinoid receptor agonist WIN 55,212-2 at doses of 1, 10, 100 or 200 microg/kg, or the enantiomer WIN 55,212-3 (100 microg/kg) 5 min before intraplantar injection of capsaicin into one paw. The duration of nocifensive behavior was measured during the first 5 min after capsaicin injection. Withdrawal responses to mechanical and heat stimuli applied to the plantar surface of both hindpaws were measured before and at 5 and 30 min after capsaicin. Pretreatment with WIN 55,212-2 produced a dose-dependent decrease in nocifensive behavior and in hyperalgesia to mechanical and heat stimuli produced by capsaicin, as compared with vehicle pretreatment. Doses of 100 and 200 microg/kg WIN 55,212-2 completely blocked the development of hyperalgesia to mechanical and heat stimuli without altering withdrawal responses on the contralateral control paw. Furthermore, these doses of WIN 55,212-2 had no effect on basal withdrawal responses to heat in animals that did not receive capsaicin. The inactive enantiomer WIN 55,212-3 did not alter the development of capsaicin-evoked pain or hyperalgesia. These data suggest that low doses of cannabinoids, which do not produce analgesia or impair motor function, attenuate chemogenic pain and possess antihyperalgesic properties.     

Patterns of hyperalgesia in complex regional pain syndrome

Complex regional pain syndrome (CRPS) is characterized by a triad of sensory, motor and autonomic dysfunctions, with long-standing pain and temperature differences of the affected and contralateral limb as predominant symptoms. The pathogenesis of the disorder still remains unclear. Among the main hypotheses of an underlying pathophysiology we find inflammatory processes and dysfunction of the sympathetic nervous system. Whether the main site of dysfunction is found centrally or peripherally is not known. With psychophysical methods we studied patterns of hyperalgesia to obtain a better understanding of the neuropathic pain component in CRPS. Forty patients in an acute phase of CRPS and a median duration of the disease of 10 weeks, were included in the study. Hyperalgesia to heat was tested with a thermode providing feedback-controlled temperature increases. Two forms of mechanical hyperalgesia were examined: phasic mechanical stimuli by using a custom-made impact stimulator for the determination of individual pain thresholds, tonic mechanical stimuli were applied using a pinch-device. Additionally a 'wind-up' paradigm was used to study a pain phenomenon of presumed central origin: a defined impact stimulus was given once and five times in repetition. A subpopulation of patients was reevaluated for mechanical hyperalgesia after i.v. injection of 500 mg acetyl-salicylic acid. Hyperalgesia to heat was insignificant. We found, however, a marked mechanical hyperalgesia to phasic impact stimuli (P < 0.005), whereas, static stimulation (squeezing skin folds) results were insignificant again. Wind-up related pain was also significantly enhanced in the affected limb (P < 0.02). The anti-inflammatory agent had no effect. These results indicate a non-inflammatory pathogenesis in CRPS presumably central in origin.     

Reflexes in sympathetic vasoconstrictor neurones arising from urinary bladder afferents are not amplified early after inflammation in the anaesthetised cat

Pathophysiological processes in the viscera can lead to pain and hyperalgesia and exaggerated motility-regulating reflexes. This may be due to sensitisation of visceral afferents (peripheral sensitisation), which has repeatedly been shown to occur as a consequence of e.g. inflammation, and/or to sensitisation of dorsal horn neurones (central sensitisation), which is less well documented in the visceral domain. As an indicator of peripheral sensitisation, we previously analysed the responses of sacral spinal afferents after inflammation of the urinary bladder. Here, we studied reflexes in sympathetic vasoconstrictor neurones supplying skeletal muscle and skin elicited by bladder distension stimuli (vesico-sympathetic reflexes) before and after induction of bladder inflammation. Our aim was to test whether these vesico-sympathetic reflexes are amplified after inflammation in a way that would support a major functional role for post-inflammatory central sensitisation processes. Bladder inflammation was induced in anaesthetised cats by instillation of turpentine or mustard oil and vesico-sympathetic reflexes were studied 1 and 2 h after induction of the inflammation. Inflammation enhanced on-going activity in vasoconstrictor neurones supplying skeletal muscle (after 1 h to 187.6+/-36.8%, mean+/-SEM, P<0.01, and after 2 h to 139.1+/-12.9%, P<0.05, of baseline activity) and decreased it in most sympathetic neurones supplying skin (to 91.7+/-12.5%, P>0.05, and to 71.6+/-11.3%, P<0.05, respectively, of baseline activity). Relative to the altered baseline activity vesico-sympathetic reflexes to graded distension of the inflamed bladder were quantitatively unchanged with a tendency to be diminished. Thus, the changes in on-going sympathetic vasoconstrictor activity and the distension-evoked reflexes directly mirrored the afferent input from the inflamed urinary bladder into the spinal cord, i.e. no increase of the gain of these reflexes was observed. These results suggest that in the first 2 h of inflammation, peripheral sensitisation processes play the main role for hyperalgesia and hyperreflexia of the urinary bladder. In contrast, central sensitisation appears to be of little importance during this time period.     

Mechanical hyperalgesia after an L5 spinal nerve lesion in the rat is not dependent on input from injured nerve fibers

An injury to a peripheral nerve in animals often leads to signs of neuropathic pain including hyperalgesia to heat, cold and mechanical stimuli. The role of injured and intact nerve fibers in mechanical hyperalgesia was evaluated in rats subjected to an L5 spinal nerve ligation-and-cut ('modified SNL lesion'). To assess the contribution of injured afferents, an L5 dorsal rhizotomy was performed immediately before, or 7 days after the modified SNL lesion. To study the role of adjacent intact spinal nerves, an L4 dorsal rhizotomy was performed 7 days after the modified SNL lesion. The up-down method of Dixon (Dixon WJ, Annu Rev Pharmacol Toxicol 1980;20:441-462) was used to measure the paw withdrawal threshold to mechanical stimuli at three sites on the rat hindpaw corresponding to the L3, L4, and L5 dermatomes. We found that the modified SNL lesion produced a significant, lasting (20 days) decrease of the mechanical withdrawal threshold. The severity and duration of mechanical hyperalgesia varied across testing sites. The L5 and L4 dermatome test sites developed the most severe and lasting mechanical hyperalgesia. In contrast, the L3 testing site developed significantly less severe and shorter lasting mechanical hyperalgesia. L5 dorsal rhizotomy, by itself, produced a transient decrease in mechanical withdrawal thresholds. L5 dorsal rhizotomy performed before, or 7 days after, the modified SNL lesion did not prevent or resolve the observed decrease in mechanical withdrawal thresholds. L4 dorsal rhizotomy performed 7 days after the modified SNL lesion resulted in an immediate reversal of mechanical withdrawal thresholds back to baseline values. These results suggest that, after L5 spinal nerve ligation-and-cut, mechanical hyperalgesia develops and persists independent of input from injured afferents. We propose that the Wallerian degeneration that develops after a nerve injury leads to interactions between the degenerating fibers of the injured spinal nerve and the intact fibers of adjacent spinal nerves. This leads to changes in the intact fibers that play a critical role for both initiation and maintenance of mechanical hyperalgesia.