The Adrenergic Pharmacology of Sympathetically-Maintained Pain

The authors seek to highlight some of the recent advances in understanding the pharmacology and pathophysiology of sympathetically-maintained pain, and to develop alternate, and possibly more specific, diagnostic tests for this phenomenon. Mechanical hyperalgesia in sympathetically-maintained pain can be explained by central sensitization so that the activation of A-beta mechanoreceptors now causes pain. The sensitization of central pain-signaling neurons is dynamic and reversible. The authors propose that an ongoing input from peripheral nociceptive afferents is necessary to maintain central sensitization. This nociceptive input may be due to an alpha-adrenoceptor mediated excitatory action of sympathetic efferents on sensory nerves that is independent of neurovascular transmission.

Neuropathic pain: redefinition and a grading system for clinical and research purposes

Pain usually results from activation of nociceptive afferents by actually or potentially tissue-damaging stimuli. Pain may also arise by activity generated within the nervous system without adequate stimulation of its peripheral sensory endings. For this type of pain, the International Association for the Study of Pain introduced the term neuropathic pain, defined as "pain initiated or caused by a primary lesion or dysfunction in the nervous system." While this definition has been useful in distinguishing some characteristics of neuropathic and nociceptive types of pain, it lacks defined boundaries. Since the sensitivity of the nociceptive system is modulated by its adequate activation (e.g., by central sensitization), it has been difficult to distinguish neuropathic dysfunction from physiologic neuroplasticity. We present a more precise definition developed by a group of experts from the neurologic and pain community: pain arising as a direct consequence of a lesion or disease affecting the somatosensory system. This revised definition fits into the nosology of neurologic disorders. The reference to the somatosensory system was derived from a wide range of neuropathic pain conditions ranging from painful neuropathy to central poststroke pain. Because of the lack of a specific diagnostic tool for neuropathic pain, a grading system of definite, probable, and possible neuropathic pain is proposed. The grade possible can only be regarded as a working hypothesis, which does not exclude but does not diagnose neuropathic pain. The grades probable and definite require confirmatory evidence from a neurologic examination. This grading system is proposed for clinical and research purposes.

Pain activation of human supraspinal opioid pathways as demonstrated by [11C]-carfentanil and positron emission tomography (PET)

The role of the supraspinal endogenous opioid system in pain processing has been investigated in this study using positron emission tomography imaging of [11C]-carfentanil, a synthetic, highly specific mu opioid receptor (mu-OR) agonist. Eight healthy volunteers were studied during a baseline imaging session and during a session in which subjects experienced pain induced by applying capsaicin topically to the dorsal aspect of the left hand. A pain-related decrease in brain mu-OR binding was observed in the contralateral thalamus consistent with competitive binding between [11C]-carfentanil and acutely released endogenous opioid peptides. This decrease varied directly with ratings of pain intensity. These results suggest that the supraspinal mu-opioid system is activated by acute pain and thus may play a substantial role in pain processing and modulation in pain syndromes.

Consumption of soy diet before nerve injury preempts the development of neuropathic pain in rats

BACKGROUND

A previous report using a partial sciatic nerve ligation (PSL) model for neuropathic pain in rats demonstrated that consumption of soy-containing diets preoperatively and postoperatively suppressed development of mechanical and heat allodynia, as well as hyperalgesia. The current study examined whether dietary soy suppresses these neuropathic sensory disorders when consumed either before or after PSL injury.

METHODS

Male Wistar rats were grouped into seven different feeding regimens. These rats were fed SOY (RMH-1000, PMI Feeds, St. Louis, MO), a diet containing 85% soy protein since weaning, and were then switched to noSOY (Bio-Serv Co., Frenchtown, NJ), a diet devoid of soy at certain time points before PSL injury (14, 7, 1 days, or 15 and 0 h). Postoperatively, these rats were fed SOY or noSOY diets. Levels of mechanical and heat allodynia and hyperalgesia were determined preoperatively and 3, 8, and 14 days after PSL injury.

RESULTS

Compared with groups fed preoperative noSOY, consumption of SOY before PSL injury significantly blunted postoperative levels of allodynia and hyperalgesia. Administering the SOY diet both before and after PSL injury provided no additional suppression of neuropathic pain. No pain suppression was noted in rats fed a noSOY diet preoperatively and SOY diet after PSL injury. Switching from SOY to noSOY feeding within 15 h of PSL injury was sufficient to allow for the full development of allodynia and hyperalgesia.

CONCLUSIONS

Consumption of a soy-containing diet suppressed the development of neuropathic pain after PSL injury. The pain-suppressing properties of dietary soy were the result of a preemptive effect (i.e., when consumed preoperatively), but not a palliative effect (i.e., when consumed postoperatively). This effect of soy-containing diets appears to be short-lived, since switching to a noSOY diet 15 h before ligation abrogated the suppressive effect of soy.

Nerve lesions and the generation of pain

This review addresses the issue of how axotomy of peripheral nerve fibers leads to pain and hyperalgesia. The point of axotomy (the nerve injury site), the dorsal root ganglia, and the dorsal horn of the spinal cord are candidate sites for generation of the pain signal that is likely to be critical for maintaining the neuropathic pain state. This review considers neuropathic pain from a "systems" perspective, tracing concepts of neuropathic pain from the work of Henry Head to the present. Surprisingly, the nerve injury site and the dorsal root ganglion belonging to a transected spinal nerve do not give rise to spontaneous activity in putative C-fiber nociceptors. The intact nociceptor belonging to adjacent uninjured spinal nerves, however, does acquire abnormal spontaneous activity and a chemical sensitivity to catechols. It is suggested that partially denervated tissues in the nerve, skin, and other locations may release substances that, in turn, sensitize the intact nociceptors. These abnormalities in the intact nociceptor, which arise in the context of Wallerian degeneration, probably play a role in creating or maintaining the abnormal pain state. These considerations probably also apply to the understanding of pain arising in other neuropathies. The findings relative to the "intact" nociceptor provide a rationale by which to understand how therapies distal to the nerve injury site may diminish pain.

Positron emission tomography in the detection and management of sarcomatous transformation in neurofibromatosis

Benign neurofibromas undergo sarcomatous transformation in approximately 5% of patients with neurofibromatosis type I. The clinical and radiologic diagnosis of sarcomatous change remains difficult. Positron emission tomography with F-18 fluorodeoxyglucose is a method to assess increased glucose metabolism in malignant tissue such as sarcomas. In this case report, positron emission tomography accurately distinguished malignant from benign neurofibromas. The technique may be useful as a noninvasive screening tool for malignant transformation of neurofibromas.

Capsaicin responses in heat-sensitive and heat-insensitive A-fiber nociceptors

The recently cloned vanilloid receptor (VR1) is postulated to account for heat and capsaicin sensitivity in unmyelinated afferents. We sought to determine whether heat and capsaicin sensitivity also coexist in myelinated nociceptive afferents. Action potential (AP) activity was recorded from single A-fiber nociceptors that innervated the hairy skin in monkey. Before intradermal injection of capsaicin (10 microg/10 microl) into the receptive field, nociceptors were classified as heat-sensitive (threshold, </=53 degrees C, 1 sec) or heat-insensitive afferents and as mechanically sensitive (von Frey threshold, <6 bar) or mechanically insensitive afferents. All heat-sensitive afferents (n = 16) were insensitive to mechanical stimuli but responded to the intradermal injection of capsaicin (69 +/- 7 APs in 10 min). Responsiveness to mechanical stimuli, thermal stimuli, and capsaicin varied in their receptive fields; the majority of receptive field sites (24 of 36) were responsive to only one or two stimulus modalities, whereas only eight sites responded to all three modalities. For most heat-insensitive afferents, the activity induced by the capsaicin injection did not exceed the activity induced by needle insertion alone. However, the largest response to capsaicin (314 +/- 98 APs in 10 min) was observed for five afferents that were insensitive to heat as well as mechanical stimuli and therefore may be classified as cutaneous chemoreceptors. These results suggest that A-fiber nociceptors play a role in the pain and hyperalgesia associated with capsaicin injection. Our finding that a subgroup of capsaicin-sensitive A-fiber nociceptors are insensitive to heat predicts the existence of heat-insensitive capsaicin receptors.

Early onset of spontaneous activity in uninjured C-fiber nociceptors after injury to neighboring nerve fibers

Ligation and transection of the L5 spinal nerve in the rat lead to behavioral signs of pain and hyperalgesia. Discharge of injured nociceptors has been presumed to play a role in generating the pain. However, A fibers, but not C fibers, in the injured L5 spinal nerve have been shown to develop spontaneous activity. Moreover, an L5 dorsal root rhizotomy does not reverse this pain behavior, suggesting that signals from other uninjured spinal nerves are involved. We asked if abnormal activity develops in an adjacent, uninjured root. Single nerve fiber recordings were made from the L4 spinal nerve after ligation and transection of the L5 spinal nerve. Within 1 d of the lesion, spontaneous activity developed in approximately half of the C fiber afferents. This spontaneous activity was at a low level (median rate, seven action potentials/5 min), originated distal to the dorsal root ganglion, and was present in nociceptive fibers with cutaneous receptive fields. The incidence and level of spontaneous activity were similar 1 week after injury. The early onset of spontaneous activity in uninjured nociceptive afferents could be the signal that produces the central sensitization responsible for the development of mechanical hyperalgesia. Because L4 afferents comingle with degenerating L5 axons in the peripheral nerve, we hypothesize that products associated with Wallerian degeneration lead to an alteration in the properties of the adjacent, uninjured afferents.

Soy-containing diet suppresses chronic neuropathic sensory disorders in rats

Partial sciatic nerve ligation (PSL) in rodents produces chronic neuropathic sensory disorders resembling neuropathic pain in humans. We previously reported that levels of allodynia and hyperalgesia after PSL injury were markedly attenuated by consumption of soy-containing diets. Here we aimed to show that dietary effect on pain behavior is not specific to a certain laboratory. For this purpose, experiments were conducted in a different laboratory (Baltimore rather than Jerusalem) and a different rat strain (Wistar rather than Sabra), with additional and different testing methods (radiant heat from a lamp rather than a CO(2) laser). Rats were fed two soy-free diets and a soy-containing one for 28 days. The sensitivity of rats to nonnoxious and noxious stimuli was determined before PSL injury, and levels of neuropathic sensory disorders were determined after it. We found that consuming the soy-containing diet prevented development of tactile and heat allodynia, but not mechanical hyperalgesia. This dietary effect was not correlated with calorie intake and weight gain or dietary concentration of fat and carbohydrates. We conclude that, regardless of experimental site, diet markedly affects chronic neuropathic sensory disorders in rats and should be standardized in animal models of pain.

IMPLICATIONS

Levels of chronic sensory disorders in a rat model of allodynia and hyperalgesia after partial sciatic nerve ligation depend on the consumption of a soy-containing diet. Further studies are needed to determine the role of diet in humans with chronic pain.

Effects of baseline skin temperature on pain ratings to suprathreshold temperature-controlled stimuli

Variations in baseline skin temperature can be encountered in experimental and clinical pain states. Such variations have been shown to greatly alter the response to radiant heat stimuli when the temperature of the stimulus is not controlled. We carried out a psychophysical investigation to examine the influence of baseline skin temperature on pain ratings to temperature-controlled heat stimuli. A CO(2) laser thermal stimulator was used to deliver heat stimuli under radiometer feedback temperature control to the volar forearm. Each stimulus consisted of a 30 s controlled baseline interval (at 34 or 38 degrees C) followed by a stepped increase in temperature (to 46 or 47 degrees C for 1, 2 or 4 s). A run comprised one presentation of each of these12 different stimuli to different locations. Each experiment contained three runs. In runs 2 and 3, the stimulus intensity and duration at a given location were not changed, but the baseline temperature was alternated between 34 degrees C and 38 degrees C. The intensity of pain was rated using the technique of magnitude estimation. Mean normalized pain ratings for suprathreshold stimuli applied from the higher base temperature (1.03+/-0.03) were slightly greater than from the lower base temperature (0.96+/-0.03). In contrast, pain ratings to the 47 degrees C stimuli (1.11+/-0.03) were substantially greater than to the 46 degrees C stimuli (0.88+/-0.03). Thus a 4 degrees C change in baseline temperature has a smaller affect (about 8%) on pain ratings than a 1 degrees C change in stimulus temperature (about 27%). This suggests that variations in baseline skin temperature encountered in experimental and clinical pain states have only a minor impact on pain sensitivity to suprathreshold temperature-controlled stimuli.

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.

Response of cutaneous A- and C-fiber nociceptors in the monkey to controlled-force stimuli

The goal of this study was to determine the capacity of primary afferent nociceptive fibers (nociceptors) to encode information about noxious mechanical stimuli in primates. Teased-fiber techniques were used to record from 14 A-fiber nociceptors and 18 C-fiber nociceptors that innervated the hairy skin. Stimulus-response functions were examined with an ascending series of force-controlled stimuli. Stimulus-interaction effects were examined with use of a series of paired stimuli in which the interval between the stimulus pairs was varied systematically. Both A-fiber and C-fiber nociceptors exhibited a slowly adapting response to the stepped force stimuli. The response of the A fibers increased monotonically with increasing force, whereas the response of the C fibers reached a plateau at low force levels. The slope of the stimulus-response function for the A fibers was significantly steeper than that for the C fibers, and the total response was greater. The A fibers also provided more discriminative information regarding stimulus intensity. The C fibers demonstrated a significant fatigue in response when the interstimulus interval between the paired stimuli was </=150 s, whereas the A fibers did not demonstrate a significant fatigue until the interstimulus interval was </=30 s. This fatigue in response was not due to changes in tissue compliance. These results suggest that A- and C-fiber nociceptors have different mechanical transduction mechanisms. A-fiber nociceptors exhibit steeper stimulus-response functions and less fatigue than C-fiber nociceptors.

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.

Electrophysiological assessment of the cutaneous arborization of Adelta-fiber nociceptors

Little is known about the relationship between the branching structure and function of physiologically identified cutaneous nociceptor terminals. The axonal arborization itself, however, has an impact on the afferent signal that is conveyed along the parent axon to the CNS. We therefore developed electrophysiological techniques to investigate the branching structure of cutaneous nociceptors. Single-fiber recordings were obtained from physiologically identified nociceptors that innervated the hairy skin of the monkey. Electrodes for transcutaneous stimulation were fixed at two separate locations inside the receptive field. For 32 Adelta-fiber nociceptors, distinct steps in latency of the recorded action potential were observed as the intensity of the transcutaneous electrical stimulus increased, indicating discrete sites for action potential initiation. The number of discrete latencies at each stimulation location ranged from 1 to 9 (3.7 +/- 0. 2; mean +/- SE) and the mean size of the latency step was 9.9 +/- 1. 0 ms (range: 0.4-89.1 ms). For seven Adelta fibers, collision techniques were used to locate the position of the branch point where the daughter fibers that innervated the two locations within the receptive field join the parent axon. To correct for changes in electrical excitability at the peripheral terminals, collision experiments between the two skin locations and between each skin location and a nerve trunk electrode were necessary. Nine branch points were studied in the seven Adelta fibers; the mean propagation time from the action potential initiation site to the branch point was 31 +/- 5 ms corresponding to a distance of 54 +/- 10 mm. Almost half of the daughter branches were unmyelinated. These results demonstrate that collision techniques can be used to study the functional anatomy of physiologically identified nociceptive afferent terminals. Furthermore these results indicate that some nociceptive afferents branch quite proximal to their peripheral receptive field. Occlusion of action potential activity can occur in these long branches such that the shorter branches dominate in the response to natural stimuli.

Uninjured C-fiber nociceptors develop spontaneous activity and alpha-adrenergic sensitivity following L6 spinal nerve ligation in monkey

We investigated whether uninjured cutaneous C-fiber nociceptors in primates develop abnormal responses after partial denervation of the skin. Partial denervation was induced by tightly ligating spinal nerve L6 that innervates the dorsum of the foot. Using an in vitro skin-nerve preparation, we recorded from uninjured single afferent nerve fibers in the superficial peroneal nerve. Recordings were made from 32 C-fiber nociceptors 2-3 wk after ligation and from 29 C-fiber nociceptors in control animals. Phenylephrine, a selective alpha1-adrenergic agonist, and UK14304 (UK), a selective alpha2-adrenergic agonist, were applied to the receptive field for 5 min in increasing concentrations from 0.1 to 100 microM. Nociceptors from in vitro control experiments were not significantly different from nociceptors recorded by us previously in in vivo experiments. In comparison to in vitro control animals, the afferents found in lesioned animals had 1) a significantly higher incidence of spontaneous activity, 2) a significantly higher incidence of response to phenylephrine, and 3) a higher incidence of response to UK. In lesioned animals, the peak response to phenylephrine was significantly greater than to UK, and the mechanical threshold of phenylephrine-sensitive afferents was significantly lower than for phenylephrine-insensitive afferents. Staining with protein gene product 9.5 revealed an approximately 55% reduction in the number of unmyelinated terminals in the epidermis of the lesioned limb compared with the contralateral limb. Thus uninjured cutaneous C-fiber nociceptors that innervate skin partially denervated by ligation of a spinal nerve acquire two abnormal properties: spontaneous activity and alpha-adrenergic sensitivity. These abnormalities in nociceptor function may contribute to neuropathic pain.

Evidence for end-to-side sensory nerve regeneration in a human. Case report

Division of a peripheral nerve produces an axotomy leading to neurite outgrowth from the proximal stump and wallerian degeneration in the distal stump. Because there is no longer a connection between the distal stump and neuronal cell bodies in the anterior spinal cord or dorsal root ganglion, it is assumed that no neurites should exist in the distal stump. The authors present the case of a patient who unexpectedly had a neuroma on the proximal end of the distal segment of a previously severed nerve. The lateral antebrachial cutaneous nerve had been surgically severed. Innervated by the radial nerve, a neuroma subsequently formed in the distal segment. Our hypothesis is that the proximal end of the distal portion of a severed nerve may be innervated by collateral sprouts of axons that branch at points of more distal plexus formation. This invokes a similar pathophysiology to the controversial notion of end-to-side nerve sprouting. Neuromas that develop on the "wrong side" of a nerve become an additional potential source of pain in patients with injured nerves.

Myelinated mechanically insensitive afferents from monkey hairy skin: heat-response properties

To compare the heat responses of mechanically sensitive and mechanically insensitive A-fiber nociceptors, an electrical search technique was used to locate the receptive fields of 156 A-fibers that innervated the hairy skin in the anesthetized monkey (77 A beta-fibers, 79 A delta-fibers). Two-thirds of these afferents were either low-threshold mechanoreceptors (n = 91) or low-threshold cold receptors (n = 11). Nine A beta-fibers and 41 A delta-fibers were cutaneous nociceptors, and four A delta-fibers innervated subcutaneous tissue. The majority of cutaneous A-fiber nociceptors were heat sensitive (43/50 = 86%). Heat-insensitive cutaneous A-fiber nociceptors consisted of one cold nociceptor, three silent nociceptors, and three high-threshold mechanoreceptors. Two types of response were observed to an intense heat stimulus (53 degrees C, 30 s). Type I (n = 26) was characterized by a long latency (mean: 5 s) and a late peak discharge (16 s). Type II (n = 17) was characterized by a short latency (0.2 s) and an early peak discharge (0.5 s). Type I fibers exhibited faster conduction velocities (25 vs. 14 m/s) and higher heat thresholds (> 53 vs. 47 degrees C, 1-s duration) than type II fibers. The possibility that the type I heat response was a result of sensitization was tested in three fibers by determining the heat threshold to 30-s duration stimuli (42-46 degrees C). For this long stimulus duration heat thresholds were reproducible across multiple runs, and the threshold to the 1-s duration stimulus was not altered by these tests. Thus fibers with a type I heat response were not high-threshold mechanoreceptors that developed a heat response through sensitization. Fibers with a type II heat response had significantly higher mechanical thresholds (median: 15 bar) than fibers with a type I heat response (5 bar). This finding accounts for the observation that type II heat responses were infrequently observed in earlier studies wherein the search technique depended on mechanical responsiveness. Fibers with a type II response exhibited a graded response to heat stimuli, marked fatigue to repeated applications of heat stimuli, and adaptation to sustained heat stimuli similar to that seen in C-fiber nociceptors. First pain sensation to heat is served by type II A-fiber nociceptors that are mechanically insensitive. Type I A-fiber nociceptors likely signal pain to long-duration heat stimuli and may signal first pain sensation to mechanical stimuli.

Treatment of intractable pain with topical large-dose capsaicin: preliminary report

Complex regional pain syndromes (CRPS) and neuropathic pain are often poorly controlled by conventional pharmacologic interventions. We administered 8-methyl-N-vanillyl-noneamide (capsaicin) at doses of 5%-10% to individuals with such disorders in this trial. Previous limitations to trials with larger-dose, topical concentrations of capsaicin included intense burning sensations experienced after application. To enable patients to tolerate the high concentrations, we first performed regional anesthesia. All patients reported at least some relief. Of 10 patients, 9 obtained substantial analgesia that lasted 1-18 wk. At Week 1 after therapy, the mean verbal analog scale (VAS) scores decreased from 8.0 to 3.0. At Week 4 after therapy, mean VAS score was 4.5. Analgesia lasted from < 1 wk (1 patient) to more than 50 wk (1 patient). Patients received one to eight treatments. With one exception, patients receiving more than one treatment obtained additional relief with subsequent treatment. Pain responsive to opioids was the only side effect of treatment. Large-dose capsaicin administered with regional anesthesia may effectively minimize refractory CRPS and neuropathic pain. A double-blind, placebo-controlled study in patients with bilateral peripheral neuropathy using epidural anesthesia with and without large-dose topical capsaicin is in progress.

IMPLICATIONS

Sensory neuropathies are associated with many diseases. Pain from these disorders can produce greater disability than the primary disease processes themselves. Currently available therapies are limited. However, the intermittent application of large-dose topical capsaicin may provide significant pain relief, decrease chronic analgesic dependence, and decrease aggregate health care expenditures.

Neuropathic pain following partial nerve injury in rats is suppressed by dietary soy

Some humans with partial nerve injury present a syndrome of neuropathic sensory disorders which depend on the sympathetic activity (sympathetically-maintained pain, SMP). Several years ago we introduced a rat model for SMP, produced by tightly ligating 1/3-1/2 of the sciatic nerve, leading to a partial denervation of the hindpaw (Partial Sciatic Ligation, PSL model) [Seltzer, Z., Dubner, R. and Shir, Y., Pain, 43 (1990) 245-250]. After working with this model for several years we encountered difficulties in replicating it although rat strain, vendor, gender, age and weight, surgical approach and sensory testing procedures were not changed. We report here that this variability can be attributed, at least in part, to the diet the animals consumed. Rats fed perioperatively with soy-containing diets expressed significantly weaker neuropathic sensory disorders compared to rats fed on soy-free diets. We conclude that diet may greatly affect experimental outcome in the PSL model.

Secondary hyperalgesia to mechanical but not heat stimuli following a capsaicin injection in hairy skin

A psychophysical investigation was carried out to examine whether heat hyperalgesia exists within the secondary mechanical hyperalgesia zone surrounding a capsaicin injection site on hairy skin. A non-contact laser stimulator was used to deliver temperature controlled stimuli to sites within and outside the zone of mechanical hyperalgesia. Heat testing was carried out before and after the intradermal injection of 50 micrograms of capsaicin into the volar forearm. The zones of mechanical hyperalgesia to punctate and stroking stimuli and the region of flare were also mapped after the capsaicin injection. Heat pain thresholds inside the secondary mechanical hyperalgesic zone were not significantly different from thresholds outside the secondary mechanical hyperalgesia zone. In addition, pain ratings to an ascending series of heat stimuli delivered inside the zone of secondary hyperalgesia were not significantly different from pain ratings outside the zone of secondary hyperalgesia. Thus, there was no evidence for heat hyperalgesia within the zone of secondary hyperalgesia to punctate mechanical stimuli. Though the areas of punctate and stroking hyperalgesia were correlated, no correlation existed between the magnitude of capsaicin evoked pain and the areas mechanical hyperalgesia to punctuate and stroking stimuli or the area of flare. This suggests that independent mechanisms may mediate evoked pain, central sensitization that leads to mechanical hyperalgesia, and axon reflexive flare.

Nerve injury associated with laparoscopic inguinal herniorrhaphy

BACKGROUND

As laparoscopic herniorrhaphy becomes more popular, it is important to realize the potential for injury to surrounding neural structures, with attendant severe disability.

METHODS

Herein are discussed two patients with disabling neuralgia after laparoscopic herniorrhaphy.

RESULTS

Both patients were treated with transabdominal removal of their prosthetic materials and anchoring staples, with dramatic symptomatic improvement.

CONCLUSIONS

The surgeon should be aware of the anatomic considerations accompanying laparoscopic herniorrhaphy. In regard to nerve injury, laparoscopic herniorrhaphy may pose certain disadvantages over traditional hernia repairs. It may diminish the ability to appreciate the course of nerves in the inguinal region and their relationship to the spermatic cord, and injury to nerves may be difficult to recognize and treat.

An electromechanical stimulator system for neurophysiological and psychophysical studies of pain

We have developed a computer-based electromechanical stimulator system suited for neurophysiological and psychophysical studies of pain. The core of the stimulator is a servo-controlled linear motor capable of generating 1 kg of force over a 22-mm range. Forces collinear and tangenital to the interchangeable probe tip are calculated using the signal from 3 load cells (resolution: 1/8 g; range: 250 g) arranged in an equilateral triangle. Probe position is measured with an optical encoder (resolution: 1 micron; range: 25 mm). A microprocessor-based digital control system permits smooth switching of feedback control between force or position at the 1-kHz update rate. The stimulator is mounted on a microprocessor-controlled 3-axis translation system that allows automatic movement of the probe over a range of greater than 15 cm to an accuracy of better than 10 microns. The stimulator can be programmed to move in a coordinate system parallel to the skin surface being examined. An IBM-compatible computer is used to command stimulus paradigms and to display real-time motor performance and neural spike-train data. The system has been used to measure the response of nociceptive afferents in monkey to controlled force stimuli applied to various positions within the receptive field.

Response of C fibre nociceptors in the anaesthetized monkey to heat stimuli: correlation with pain threshold in humans

1. Ramped heat stimuli were used to compare the effects of rate of temperature change on the responses of monkey nociceptors and on heat pain threshold in human subjects. Recordings were made from twenty-five cutaneous C fibre mechano-heat nociceptors (CMHs) innervating the hairy skin in the anaesthetized monkey. Heat pain thresholds were determined on the volar forearm of eight human subjects using a converging staircase technique. 2. The heat pain threshold decreased as stimulus ramp rate increased. In contrast, the CMH heat threshold, defined as the surface temperature at which the first action potential occurred, increased as stimulus ramp rate increased. Thus, the properties of the heat stimulus that dictate heat pain threshold are different from the properties of the heat stimulus that govern the initiation of a response in nociceptors. 3. Peak discharge frequency of CMHs during the heat ramp increased with stimulus ramp rate. Heat pain threshold was correlated with achievement of a minimum discharge rate in nociceptors (0.5 Hz), rather than with the threshold for action potential initiation.

Response of C fibre nociceptors in the anaesthetized monkey to heat stimuli: estimates of receptor depth and threshold

1. Responses to ramped or stepped temperature stimuli were obtained from fifty-three cutaneous C fibre mechano-heat nociceptors (CMHs) in the hairy skin of the pentobarbitone-morphine anaesthetized monkey. A three-layer heat transfer model was developed to describe the temperature distribution within the skin and to estimate receptor depth and heat threshold. 2. Surface heat threshold, defined as the surface temperature when the first action potential occurs, increased as: (a) the rate of temperature rise for the ramped stimuli increased from 0.095 to 5.8 degrees C s-1; (b) the duration of stepped heat stimuli decreased from 30 to 1 s; and (c) the base temperature of stepped heat stimuli decreased from 38 to 35 degrees C. These results suggest that the heat threshold for CMHs is determined by the temperature at the depth of the receptor. 3. Receptor depth estimates from responses to ramped stimuli ranged from 20 to 570 microns with a mean of 201 microns. The estimated mean receptor heat threshold was 40.4 +/- 2.2 degrees C (+/- S.D.). No correlation was observed between depth and thermal or mechanical threshold. The average receptor depth and threshold, estimated from the responses to stepped heat stimuli, were 150 microns and 40.2 degrees C, respectively. 4. We conclude that: (a) the receptor endings of CMHs occur in the epidermis and dermis; (b) temperature at the level of the receptor determines threshold; (c) temperature at the receptor ending is much lower than skin surface temperature at threshold; and (d) the tight distribution of receptor heat thresholds suggests a uniform transducer mechanism for heat in CMHs.

Evidence for two different heat transduction mechanisms in nociceptive primary afferents innervating monkey skin

1. Mechano- and heat-sensitive A fibre nociceptors (AMHs) and C fibre nociceptors (CMHs) in hairy skin (forty-six AMHs and twenty-one CMHs) and in glabrous skin (fifty-nine AMHs and ten CMHs) of anaesthetized monkeys were tested with a 30 s, 53 degrees C heat stimulus, delivered by a laser thermal stimulator (0.1 s rise time, 7.5 mm diameter). 2. Two types of heat response were observed in hairy skin AMHs. Type I AMHs had a peak discharge towards the end of the stimulus, response latencies to heat of up to several seconds, a median heat threshold greater than 53 degrees C, and a mean conduction velocity of 25 m s-1 (n = 33). Type II AMHs had a peak discharge within 1-3 s, a mean response latency of 120 ms, a median heat threshold of 46 degrees C, and a mean conduction velocity of 15 m s-1 (n = 13). Type I AMH fibres were sensitized to heat, whereas heat responses of type II AMHs were suppressed following the intense heat stimulus. 3. In glabrous skin, only type I AMHs were found. The absence of type II AMHs is consistent with the absence of first pain to heat in glabrous skin. 4. C fibre nociceptors in hairy skin had a peak discharge near stimulus onset, a mean response latency of 100 ms and a median heat threshold of 41 degrees C. Heat responses of CMHs in glabrous skin were not significantly different from those in hairy skin. 5. Only type II AMHs had response latencies that were short enough to explain first pain to heat. Heat thresholds of type II AMHs were significantly higher than those of CMHs. 6. These results suggest two different heat transduction mechanisms in nociceptive afferents. For one, heat energy is quickly transduced into action potentials, and the peak discharge is reached soon after stimulus onset. For the other, the transduction of heat is distinctly slower, and the peak discharge occurs near the end of the stimulus. Chemically mediated sensitization may be involved in the second transduction mechanism.

A psychophysical study of secondary hyperalgesia: evidence for increased pain to input from nociceptors

Substantial evidence suggests that the hyperalgesia to mechanical stimuli that occurs in an area of uninjured skin surrounding a site of injury (area of secondary hyperalgesia) arises from activity in low-threshold mechanoreceptors (LTMs). In this study, we have investigated if activity in mechanically sensitive nociceptors also contributes to this secondary hyperalgesia. It is known that all woollen fabrics excite LTMs, but that only the prickly ones activate mechanically sensitive nociceptors. Therefore, we have conducted a psychophysical study using a range of prickly and non-prickly woollen fabrics applied to normal and hyperalgesic skin to assess the roles of LTMs and nociceptors in secondary hyperalgesia. We have studied in 10 normal volunteers the sensations of fabric-evoked prickle and pain in normal and hyperalgesic skin. Secondary hyperalgesia was produced by intradermal injection of capsaicin (25 micrograms) into the volar skin of the forearm. Five woollen fabrics (2 non-prickly, 2 prickly and 1 intermediate) were presented, in a blind manner, to the skin before and after the capsaicin injection. The sensation of fabric-evoked prickle was not changed in hyperalgesic skin. On the other hand, little if any pain was evoked by the fabrics when applied to normal skin, but substantial pain was produced by all fabrics when applied to hyperalgesic skin. The pain ratings were graded with the ratings of prickle so that fabrics that evoked the greatest prickle also evoked significantly more pain. The magnitude of pain increased linearly with prickle sensation; the slope of this regression function increased substantially in hyperalgesic skin.(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic opioid therapy as alternative treatment for post-herpetic neuralgia

Neurosurgical procedures such as the dorsal root entry zone operation, ganglionectomy, and spinal-cord stimulation have been offered to patients with intractable post-herpetic neuralgia (PHN). Poor efficacy or high morbidity have limited the overall usefulness of these procedures. We recently conducted a preliminary open-label study with long-acting oral opioids. The mean pretreatment pain score, on a scale of 0 to 10 (0 = no pain) was 9.0 +/- 0.3 (mean +/- SEM, N = 20). At two months of treatment the average pain score was 4.0 +/- 0.4 (p < 0.001, paired t test), and at six months the average pain score was 3.8 +/- 0.2 (p < 0.001, N = 16). These observations warrant a controlled opioid trial for patients affected by PHN.

Cellular components necessary for mechanoelectrical transduction are conveyed to primary afferent terminals by fast axonal transport

Axonal transport of neurotransmitter receptors is a well established phenomenon. In this study, we sought to determine whether the cellular components necessary for mechanical-to-electrical transduction in primary afferents are also conveyed to the peripheral terminals via fast axonal transport. In previous studies, severed cutaneous nerves have been shown to develop mechanical sensitivity at their ligated ends within hours of injury. Since the rate of development of this mechanical sensitivity was temperature dependent, we postulated that axonal transport was involved. In this study, we performed two experiments in which the rate of axonal transport was modified. In the first experiment, the nerve was cut at a proximal site to block the supply of additional transported components to the distal end of the nerve. At a point 80 to 120 mm distal to this proximal cut, a nerve crush and ligation were performed either 3 or 12 h after the proximal nerve ligation. The centripetally conducted action potentials generated by applying mechanical stimuli to the nerve subjacent to the distal ligature were recorded 10 h after the distal ligature was placed. Given a fast axonal transport rate of 400 mm/day, transported molecules should traverse a 100-mm segment within 6 h. Consistent with this calculation, 29% of the myelinated fibers responded to mechanical stimuli when the time lapse between lesions was 3 h, whereas only 3% responded when the time between lesions was 12 h. In the second experiment, axonal transport was enhanced by a prior nerve injury (conditioning lesion).(ABSTRACT TRUNCATED AT 250 WORDS)

Angioleiomyoma involving the sciatic nerve--CT demonstration. Case report

An angioleiomyoma adjacent to the sciatic nerve was responsible for an 11-year history of pain and dysfunction in the sciatic nerve distribution, which required numerous therapeutic procedures and intermittent use of narcotic analgesics. Diagnosis was finally made when results of a sciatic nerve block suggested possible mechanical compression of the nerve and computed tomography examination of the pelvis was extended further caudal than usual, demonstrating the tumor adjacent to the sciatic nerve near the ischial tuberosity. Only one previous case of nerve dysfunction due to impingement by an angioleiomyoma has been reported.

Chemosensitivity and sensitization of nociceptive afferents that innervate the hairy skin of monkey

1. A large proportion of the cutaneous nociceptor population in monkey either does not respond to mechanical stimuli or has very high mechanical thresholds (> 6 bar). The goal of this study was to determine whether these mechanically insensitive nociceptive afferents (MIAs) differ from mechanically sensitive nociceptive afferents (MSAs) with regard to responses to chemical stimuli. 2. Teased-fiber techniques were used to record from 28 A delta-fiber (16 MIAs and 12 MSAs) and 23 C-fiber (10 MIAs and 13 MSAs) nociceptors in hairy skin of pentobarbital sodium-anesthetized monkeys. An electrocutaneous search technique was used to locate the putative receptive fields of the MIAs. The response to mechanical and heat stimuli was determined before and after intradermal injection of a standard mixture of algesic/inflammatory mediators (bradykinin, histamine, serotonin, and prostaglandin E1). 3. All 25 MSAs, but only 65% of the MIAs, responded to the chemical stimulus. The A delta-fibers, both MSAs and responsive MIAs, and the responsive C-fiber MIAs gave a robust discharge. In contrast, the C-fiber MSAs (the conventional polymodal C-fiber nociceptors) exhibited a significantly weaker response. Three MIAs responded only to the chemical mixture and not to mechanical or heat stimuli. 4. Before injection of the chemical mixture, a significantly smaller proportion of C-fiber MIAs (50%) than of C-fiber MSAs (92%) responded to heat stimuli, whereas a similar proportion (38%) of A delta-fiber MIAs and MSAs were heat sensitive. 5. Approximately one-half of the MIAs and MSAs were sensitized to mechanical stimuli after the chemical injection, as manifest by a decreased threshold and/or an enlarged receptive field. 6. The chemical injection sensitized 90% of A delta-fiber MSAs, but only 8% of A delta-fiber MIAs, to heat stimuli. In contrast, 38% of C-fibers were sensitized. 7. In 14 fibers, the chemical stimulus resulted in sensitization to mechanical stimuli without sensitization to heat stimuli, or vice versa. This dissociated sensitized state suggests that the molecular mechanisms of sensitization to heat and mechanical stimuli differ. 8. In conclusion, a large proportion of primate cutaneous nociceptors respond to intradermal injection of algesic/inflammatory mediators and may also become sensitized to mechanical and/or heat stimuli.

Role of kinins in pain and hyperalgesia: psychophysical studies in a patient with kininogen deficiency

1. Bradykinin is considered to be an important mediator of pain and hyperalgesia associated with injury and inflammation. Psychophysical studies were conducted in a patient with complete kininogen deficiency to determine whether the absence of bradykinin was associated with abnormalities in pain sensibility. Pain evoked by heat stimuli to the thenar eminence was tested before and after a localized burn, which has been shown to cause hyperalgesia in normal subjects. In addition, pain evoked by intradermal administration of bradykinin (0.1-10 micrograms) to the forearm and the effects of bradykinin on pain induced by heat stimuli were studied. The patient rated the intensity of pain evoked by all heat stimuli relative to the pain induced by a 3 s 45 degrees C stimulus. 2. The patient's heat pain threshold (45 degrees C) in the glabrous skin was similar to that of age-matched control subjects (n = 5) and to that previously observed in younger control subjects. 3. The burn resulted in a decrease in pain threshold and an increase in pain induced by suprathreshold stimuli. The magnitude of hyperalgesia was within the range observed in the age-matched control subjects and in younger control subjects. Thus, kinins are not essential for the development of hyperalgesia after heat injury. 4. In control subjects, intradermal injections of bradykinin produced pain and hyperalgesia to heat stimuli. In the patient, intradermal bradykinin injections induced minimal pain and no hyperalgesia to heat stimuli. Thus, congenital absence of kininogens may be associated with a deficiency in bradykinin receptors.

The plasticity of cutaneous hyperalgesia during sympathetic ganglion blockade in patients with neuropathic pain

In order to investigate the plasticity of cutaneous sensory abnormalities in neuropathic pain, we monitored sensory and vasomotor effects of diagnostic sympathetic ganglion blocks in 24 patients, who suffered from chronic pain and cutaneous hyperalgesia following peripheral nerve or tissue injury. Ongoing pain was rated on a visual analogue scale, and pain evoked by innocuous tactile and cooling stimuli (hyperalgesia) on a verbal rating scale. Skin temperatures were determined at symmetric sites. In two patients, cutaneous blood flow was measured with a laser Doppler device. The sympathetic blocks led to a significant reduction of the group mean ongoing pain (40%) and cutaneous hyperalgesia (50%). Between patients, however, there was a large variability that could not be related merely to adequacy of sympathetic blockade. Neither the magnitude of change in skin temperature nor the final skin temperature after the block correlated with the amount of pain relief. The relief of hyperalgesia, however, correlated with the relief of ongoing pain. Nine patients experienced pain relief of greater than 50%. In these patients, the time course of hyperalgesia relief was similar to the time course of relief of ongoing pain. Pain relief occurred simultaneously with or a few minutes before cutaneous vasodilatation. During the block, even vigorous mechanical or cold stimuli did not rekindle hyperalgesia. In all patients, pain and hyperalgesia returned within a day after the block. In three patients tested, passive warming of the limb to the temperature achieved by the sympathetic block had negligible effects on pain and hyperalgesia. The hyperalgesia of sympathetically maintained pain is thought to be due to sensitization of central pain-signalling neurons to mechanoreceptor input. The present data indicate that this sensitization is highly plastic even when the disease has persisted for months or years. It could be reversed within minutes by a sympathetic blockade, but returned when sympathetic block subsided. Mechanoreceptor input by itself was not sufficient to maintain or rekindle the central sensitization. This supports the hypothesis that low-grade activity of nociceptors, possibly due to development of alpha-adrenergic sensitivity after injury, is involved in the maintenance of central sensitization.

Peripheral and central mechanisms of cutaneous hyperalgesia

Hyperalgesia after cutaneous injury can be divided into two phenomena: Primary hyperalgesia occurs at the site of injury and is characterized by hyperalgesia to mechanical and heat stimuli. Secondary hyperalgesia occurs outside the injury site and is characterized by mechanical hyperalgesia only. Hyperalgesia in inflammatory processes corresponds to primary hyperalgesia. Hyperalgesia in referred pain and neuropathic pain resembles secondary hyperalgesia (Table 3). Evidence for the latter would be strengthened if hyperalgesia to cooling stimuli, which is observed in neuropathic pain, was also demonstrated in referred pain and in secondary hyperalgesia. Some of the more likely neural mechanisms to explain primary and secondary hyperalgesia are illustrated in Fig. 8. Primary hyperalgesia to heat stimuli has a counterpart in the sensitization of peripheral nociceptors to heat stimuli (Fig. 8A), leading to similar changes in central neurons. In addition, the enlargement of the mechanical receptive field of primary afferent nociceptors to include the site of injury may account for the primary hyperalgesia to mechanical stimuli (Fig. 8B). In the literature, there are some contradictions with respect to the stimulus modalities to which hyperalgesia and sensitization occur. In spite of the well-documented sensitization of primary afferent nociceptors to heat stimuli, there are few studies on its molecular mechanisms. On the other hand, there is pharmacological evidence for a peripheral mechanism of primary mechanical hyperalgesia, but little direct evidence that nociceptors can be sensitized to mechanical stimuli by injury. This contradiction should spawn further investigations into the mechanical response properties of nociceptors and into the molecular mechanisms of heat sensitization. Secondary hyperalgesia to mechanical stimuli is likely due to the sensitization of central pain signalling neurons (CPSNs). This sensitization could involve only input from nociceptors (Fig. 8C), since mechanical pain thresholds after a cutaneous injury are of the same order as those of nociceptors. Central sensitization could also be the result of enhanced connectivity between low-threshold mechanoreceptors and CPSNs (Fig. 8D). This form of sensitization may account for the pain to light touch associated with neuropathic pain. Receptive field plasticity is a prevalent property of dorsal horn neurons and probably plays a vital role with regard to hyperalgesia. The molecular mechanisms of synaptic plasticity are currently subject to intense experimental investigation and may provide new insights on the mechanisms of pain and hyperalgesia.

The effects of bradykinin and sequence-related analogs on the response properties of cutaneous nociceptors in monkeys

The endogenous peptide bradykinin is found in plasma and inflammatory exudates and has been implicated as a chemical mediator of inflammatory pain and hyperalgesia. Two subtypes of bradykinin receptors, B1 and B2, have been described, and antagonists for the receptor subtypes have been synthesized. The bradykinin analogs [desArg9,Leu8]BK and DArg[Hyp3,DPhe7]BK have been reported to have antagonist activity at the B1 and B2 bradykinin receptors in smooth muscle, respectively. Behavioral studies in rats indicate that the bradykinin analogs can block the algesic effects of bradykinin. We wished to determine the effects of bradykinin and the bradykinin analogs (B1 and B2 analogs, respectively) on cutaneous nociceptors in the monkey. In addition, we wished to determine the type of bradykinin receptor that mediates the sensitizing effects of bradykinin. Recordings were made from single C-fiber and A-fiber nociceptive afferents (CMHs and AMHs) that innervated hairy skin. Heat sensitivity before and after the injections was determined with a heat test sequence consisting of stimuli that ranged, in 1 degree C increments, from 41 degrees to 49 degrees C. Intradermal injections of vehicle (neutral normal saline) failed to alter the heat response of CMHs. Bradykinin (10 nmol in 10 microliters) evoked activity in 6 of 10 CMHs and sensitized all the fibers to heat stimuli. After the bradykinin injection, the mean heat threshold of the CMHs decreased from 44 +/- 0.5 degrees to 42.7 +/- 0.5 degrees C (mean +/- SEM, p less than 0.02), and the total response to the heat test sequence increased by 87% (p less than 0.002). In a related psychophysical study in human volunteers, the same dose of bradykinin resulted in a comparable (115%) increase in ratings of pain (Manning et al., 1991). Bradykinin also evoked activity in 10 of 17 AMHs and sensitized 8 AMHs to heat stimuli. Bradykinin failed to alter the threshold for activation of CMHs to mechanical stimuli as measured by application of von Frey hairs to the receptive field. In contrast to bradykinin, intradermal injection of the B1 and B2 analogs (10 nmol in 10 microliters) evoked activity in 2 of 6 and 0 of 5 CMHs, respectively. A noteworthy finding was that both analogs enhanced the response of CMHs to heat stimuli by 50% (B1 analog, 1.5 +/- 0.1; B2 analog, 1.5 +/- 0.2). The B1 (n = 10) and B2 (n = 5) analogs did not evoke activity in any of the 15 AMHs tested.(ABSTRACT TRUNCATED AT 400 WORDS)

Topical application of clonidine relieves hyperalgesia in patients with sympathetically maintained pain

Patients with reflex sympathetic dystrophy or causalgia characteristically have ongoing pain and pain to light touch (hyperalgesia). Some of these patients obtain relief of their pain following interruption of sympathetic function to the affected area and, therefore, have sympathetically maintained pain (SMP). Evidence suggests that the pain and hyperalgesia in SMP are related to activation of peripheral adrenergic receptors. We wished to determine the contribution of alpha 1- and alpha 2-adrenergic receptors in SMP and thus examined the effects of local application of adrenergic agents in patients with SMP. The alpha 2-adrenergic agonist clonidine, available as a transdermal patch, was delivered topically to the patients' hyperalgesic skin. In four patients with SMP, clonidine eliminated or substantially reduced hyperalgesia to mechanical and cold stimuli. In three of these patients the effects were confined to the skin region beneath the patch, suggesting a peripheral and not central effect. The relief of hyperalgesia was not due to a local anesthetic effect since touch thresholds were unaffected. Topical clonidine did not relieve hyperalgesia of similar severity for two other patients whose hyperalgesia and pain were unaffected by sympathetic ganglion blocks (i.e., diagnosed as having sympathetically independent pain). In two SMP patients, intradermal injection of norepinephrine or phenylephrine (a specific alpha 1-adrenergic agonist) at a site treated with clonidine evoked intense pain and rekindled the pre-clonidine hyperalgesia at that site. It is likely that clonidine locally blocks the release of norepinephrine via activation of alpha 2 receptors on the sympathetic terminals. This study suggests, therefore, that SMP is mediated via alpha 1-adrenergic receptors located in the affected tissue.

Pain and hyperalgesia after intradermal injection of bradykinin in humans

Pain and hyperalgesia, the perceptual campanions of tissue injury and inflammation, are thought to be in part attributable to the sensitization of primary afferent nociceptors by endogenously released chemicals, such as bradykinin. Bradykinin (0.1 to 10 nmol in 10 microliters) evoked a dose-dependent pain, hyperalgesia to heat stimuli, and wheal and flare when injected in a double-blind manner into the volar forearm intradermally. Though hyperalgesia to mechanical stimuli is a conspicuous feature of inflammatory pain, none was measurable for any of the bradykinin doses in response to graded nylon monofilament probes. A second injection of bradykinin (5- or 30-minute intervals) at the same site produced markedly less pain and hyperalgesia to heat stimuli, indicating that the algesic and hyperalgesic effects of bradykinin undergo tachyphylaxis. These findings suggest that bradykinin alone cannot account for all aspects of the hyperalgesia that occurs after inflammation.

Mechanically insensitive afferents (MIAs) in cutaneous nerves of monkey

A problem in the study of nociceptors is that intense stimuli are used to locate the receptive field (RF), and thus the receptor may be damaged before the first responses are recorded. In addition, some nociceptors do not respond to the mechanical stimuli often used to search for the RF. To overcome these problems, an electrical search technique was developed to locate the RF of cutaneous nociceptors. In the hairy skin of anesthetized monkey, we used this technique to locate the RF of 63 A delta-fibers and 22 C-fibers that had extremely high thresholds or were unresponsive to mechanical stimuli. We refer to these afferents as mechanically insensitive afferents (MIAs). Ten A delta-fiber MIAs had a short latency response to stepped heat stimuli and could be responsible for first pain sensation. Five A delta-fiber MIAs and one C-fiber MIA did not respond to mechanical or heat stimuli but did respond to injection into the electrical RF of an artificial inflammatory soup containing histamine, bradykinin, prostaglandin E1, and serotonin. These chemoreceptors might be responsible for the pain and itch sensations that result from chemical stimuli. Some MIAs became more responsive to mechanical stimuli after injection into the RF of the inflammatory soup and, thus, may contribute to the hyperalgesia to mechanical stimuli associated with cutaneous injury. A large proportion of the A delta-fiber (48%) and C-fiber (30%) afferents in this study were insensitive to mechanical stimuli. The role of these MIAs in sensation needs to be studied further. The electrical search technique enables a systematic study of these afferents to be performed. This technique may also be of use to identify and characterize dorsal horn neurons that have inputs from MIAs.

Multiplanar CT evaluation of brachial plexopathy in breast cancer

Standard axial CT supplemented by two-dimensional reconstruction in coronal, sagittal, and oblique planes was used to evaluate 35 patients with a history of breast cancer and clinical symptoms suggestive of brachial plexopathy. In five patients, definite tumor recurrence was seen either within the axilla or the neurovascular bundle or near the origin of the brachial plexus at the C5-C7 level. In six patients, there was thickening around the plexus compatible with fibrosis or scarring. In these patients, no mass was seen. In 24 patients, no evidence of abnormality was noted. Reformatted views can supplement transaxial CT and are particularly effective in defining the course of the brachial plexus and detection of tumor recurrence. The oblique views along with orthogonal planes provide optimal visualization of the brachial plexus and are helpful in the detection of tumor involvement.

Quadrilateral space syndrome: diagnosis and operative decompression technique

We present a series of five patients with quadrilateral space syndrome. All patients had the diagnosis made on the basis of (1) tenderness over the quadrilateral space, (2) paresthesia over the lateral shoulder and upper posterior arm, and (3) deltoid weakness associated with decreased shoulder abduction. A history of trauma was present in each patient. The operative technique described utilizes a cosmetically acceptable incision and is without the need to divide the deltoid from its origin on the scapular spine. The technique minimizes postoperative bleeding and facilities rehabilitation. Arteriography of the posterior circumflex humeral artery was not found necessary to make the diagnosis of axillary nerve entrapment in the quadrilateral space.

Failed back surgery syndrome: 5-year follow-up in 102 patients undergoing repeated operation

The indications for repeated operation in patients with persistent or recurrent pain after lumbosacral spine surgery are not well established. Long-term results have been reported infrequently, and in no case has mean follow-up exceeded 3 years. We report 5-year mean follow-up for a series of repeated operations performed between 1979 and 1983. Patient characteristics and modes of treatment have been assessed as predictors of long-term outcome. One hundred two patients with "failed back surgery syndrome" (averaging 2.4 previous operations), who underwent a repeated operation for lumbosacral decompression and/or stabilization, were interviewed by a disinterested third party a mean of 5.05 years postoperatively. Successful outcome (at least 50% sustained relief of pain for 2 years or at last follow-up, and patient satisfaction with the result) was recorded in 34% of patients. Twenty-one patients who were disabled preoperatively returned to work postoperatively; 15 who were working preoperatively became disabled or retired postoperatively. Improvements in activities of daily living were recorded, overall, as often as decrements. Loss of neurological function (strength, sensation, bowel and bladder control) was reported by patients more often than improvement. Most patients reduced or eliminated analgesic intake. Statistical analysis (including univariate and multivariate logistic regression) of patient characteristics as prognostic factors showed significant advantages for young patients and for female patients. Favorable outcome also was associated with a history of good results from previous operations, with the absence of epidural scar requiring surgical lysis, with employment before surgery, and with predominance of radicular (as opposed to axial) pain.(ABSTRACT TRUNCATED AT 250 WORDS)

Systemic alpha-adrenergic blockade with phentolamine: a diagnostic test for sympathetically maintained pain

The diagnosis of sympathetically maintained pain (SMP) is typically established by assessment of pain relief during local anesthetic blockade of the sympathetic ganglia that innervate the painful body part. To determine if systemic alpha-adrenergic blockade with phentolamine can be used to diagnose SMP, we compared the effects on pain of local anesthetic sympathetic ganglion blocks (LASB) and phentolamine blocks (PhB) in 20 patients with chronic pain and hyperalgesia that were suspected to be sympathetically maintained. The blocks were done in random order on separate days. Patients rated the intensity of ongoing and stimulus-evoked pain every 5 min before, during, and after the LASB and PhB. Patients and the investigator assessing pain levels were blinded to the time of intravenous administration of phentolamine (total dose 25-35 mg). The pain relief achieved by LASB and PhB correlated closely (r = 0.84), and there was no significant difference in the maximum pain relief achieved with the two blocks (t = 0.19, P greater than 0.8). Nine patients experienced a greater than 50% relief of pain and hyperalgesia from both LASB and PhB and were considered to have a clinically significant component of SMP. We conclude that alpha-adrenergic blockade with intravenous phentolamine is a sensitive alternative test to identify patients with SMP.

Ectopic excitability of injured nerves in monkey: entrained responses to vibratory stimuli

1. The responses to mechanical stimulation of myelinated fibers that originate from an acutely cut nerve or a neuroma were studied in the anesthetized monkey. The superficial radial or sural nerve was tightly ligated and cut. Either immediately (acute experiment) or 2-6 wk later (chronic experiment), single-unit recording techniques were used to record the evoked neural activity after vibratory mechanical stimulation (5-100 Hz; 50-800 microns) near the injury site. 2. The 30 myelinated afferents studied in the chronic experiments displayed an entrained response (1 action potential for each stimulus cycle) to vibratory stimuli applied at or near the nerve injury site. For 19 fibers, the minimum amplitude for entrainment was determined as a function of frequency (tuning curve). For 11 others, complete tuning curves were not obtained, although the frequency range over which they were most sensitive could be estimated. The afferents could be classified into three groups on the basis of the frequency range over which they were most sensitive: 1) a low-frequency group that was most sensitive to frequencies less than or equal to 5 Hz (n = 7), 2) a mid-frequency group that was most sensitive to a broad range of frequencies (i.e., 20-75 Hz, n = 13), and 3) a high-frequency group that was most sensitive to frequencies greater than or equal to 100 Hz (n = 10). These three response classes are similar to the three classes of response associated with the different low-threshold mechanoreceptors (i.e., slowly and rapidly adapting and Pacinian-like mechanoreceptors).(ABSTRACT TRUNCATED AT 250 WORDS)

Dorsal root ganglionectomy for failed back surgery syndrome: a 5-year follow-up study

Dorsal root ganglionectomy has been suggested as a method for the treatment of chronic intractable radicular pain, with theoretical advantages over dorsal rhizotomy, which does not interrupt ventral root afferents. The indications for these procedures in patients with persistent pain following lumbosacral spine surgery are not well established. Long-term results have been reported infrequently, and no published series has a mean follow-up period of more than 30 months. The authors have reviewed their experience with a series of 13 patients with failed back surgery syndrome, in whom dorsal root ganglionectomy was performed. Patients were selected on the basis of clinical presentation and diagnostic root blocks suggesting a monoradicular pain syndrome. Follow-up data were obtained at a mean of 5.5 years following dorsal root ganglionectomy. Follow-up interviews to assess outcome were conducted by a disinterested third party. Treatment "success" (at least 50% sustained relief of pain and patient satisfaction with the result) was recorded in two patients at 2 years after surgery and in none at 5.5 years. Equivocal success (at least 50% relief, without clearcut patient satisfaction) was recorded in one patient at 2 and at 5.5 years postoperatively. Improvements in activities of daily living were recorded in a minority of patients. Loss of sensory and motor function was reported frequently by patients. A minority of patients had reduced or eliminated analgesic intake. These results suggest that dorsal root ganglionectomy has a limited role in the management of failed back surgery syndrome, and that methods to select patients to receive this procedure should be refined or alternative approaches should be considered.

Thoracic outlet syndrome. Neurosurgical perspective

Neurosurgeons have for the most part abdicated a role in thoracic outlet surgery and have left the diagnosis and treatment of these patients to thoracic, vascular, and general surgeons. We view this as unfortunate. Neurosurgeons are well-positioned to diagnose these conditions. The major source of confusion with regard to diagnosis is cervical spine disease or peripheral nerve entrapment diseases with which neurosurgeons are quite familiar. Orthopedic consultations with regard to shoulder pathology are encouraged. The supraclavicular approach to treatment is one with which most neurosurgeons will be comfortable. However, the transaxillary approach is also one which neurosurgeons should be able to master readily. Working with long instruments in deep holes is a familiar surgical environment. It should be stressed, however, that part of the reason for the controversy concerning TOS stems from the fact that the morbidity rate from the transaxillary approach is high in some centers. We believe this results from inadequate technique. Neurosurgeons with training that emphasizes a high regard for neural tissue should be able to master both approaches. Thoracic outlet syndrome is a disease that most neurosurgeons will see on a regular basis. Thus, it needs to be recognized, and patients need to be analyzed from a neurologic perspective. The differential diagnosis should be considered thoughtfully. Operative intervention by experienced surgeons in properly selected patients will yield satisfying results.