Clinicopathological features and prognosis of esophageal squamous cell carcinoma in young patients.

Esophageal squamous cell carcinoma (ESCC) in the young patients is comparatively rare and has not been well studied. We analyzed the clinical and survival data of 127 ESCC patients <40 years at a single high-volume center and compared with those of 4109 ESCC patients ≥40 years who underwent surgery within the same period in this study. The average age was 36.5 ± 0.2 years for the young patient group, with the youngest aged 26 years. Young patients had a higher rate of family history, longer tumors, and a more advanced pT category than their older counterparts. Moreover, more patients in the young group underwent incomplete resection (19.7% vs. 8.9%, P < 0.001) and adjuvant therapy (40.9% vs. 30.8%, P = 0.015). The overall survival (OS) and cancer-specific survival (CSS) between patients <40 years and patients ≥40 years were not significant in the entire group. In the subgroup analysis, the OS and CSS rates for patients <40 years were significantly worse than patients ≥40 years in subgroups of pTNM stage III and incomplete resections. In conclusions, young patients with ESCC were more likely to have family history and present with advanced disease. The survival for young patients with ESCC was poorer than their older counterparts in patients with later stage diseases.

Inhibition of glycogen synthase kinase 3ß activity with lithium prevents and attenuates paclitaxel-induced neuropathic pain.

Paclitaxel (taxol) is a first-line chemotherapy-drug used to treat many types of cancers. Neuropathic pain and sensory dysfunction are the major toxicities, which are dose-limiting and significantly reduce the quality of life in patients. Two known critical spinal mechanisms underlying taxol-induced neuropathic pain are an increased production of pro-inflammatory cytokines including interleukin-1ß (IL-1ß) and suppressed glial glutamate transporter activities. In this study, we uncovered that increased activation of glycogen synthase kinase 3beta (GSK3ß) in the spinal dorsal horn was concurrently associated with increased protein expressions of GFAP, IL-1ß and a decreased protein expression of glial glutamate transporter 1 (GLT-1), as well as the development and maintenance of taxol-induced neuropathic pain. The enhanced GSK3ß activities were supported by the concurrently decreased AKT and mTOR activities. The changes of all these biomarkers were basically prevented when animals received pre-emptive lithium (a GSK3ß inhibitor) treatment, which also prevented the development of taxol-induced neuropathic pain. Further, chronic lithium treatment, which began on day 11 after the first taxol injection, reversed the existing mechanical and thermal allodynia induced by taxol. The taxol-induced increased GSK3ß activities and decreased AKT and mTOR activities in the spinal dorsal horn were also reversed by lithium. Meanwhile, protein expressions of GLT-1, GFAP and IL-1ß in the spinal dorsal horn were improved. Hence, suppression of spinal GSK3ß activities is a key mechanism used by lithium to reduce taxol-induced neuropathic pain, and targeting spinal GSK3ß is an effective approach to ameliorate GLT-1 expression and suppress the activation of astrocytes and IL-1ß over-production in the spinal dorsal horn.

Treatment and prognosis of limited disease primary small cell carcinoma of esophagus.

Primary small cell carcinoma of esophagus (SCCE) is a relatively rare and highly aggressive tumor characterized by early dissemination and poor prognosis. The optimal treatment has not yet been established, and the role of surgery has remained controversial. Most of the limited diseases were treated conventionally by surgery, but the five-year survival rate was still very low. This retrospective study was designed to investigate the clinical characteristics, treatment, and prognostic factors of limited disease SCCE. Clinical data of 40 SCCE patients with clinically limited disease who received transthoracic esophagectomy with lymphadenectomy at the Cancer Hospital of Shantou University Medical College from November 1990 to December 2009 were reviewed to summarize the clinical characteristics and treatment impacted on the survival. Twenty-five cases of the 40 patients were treated with surgery alone, eight cases were treated with surgery + postoperative chemotherapy, four cases were treated with surgery + postoperative radiotherapy, and the other three were treated with surgery + postoperative radiochemotherapy. The Kaplan-Meier and log-rank methods were used to estimate and compare survival rates. Cox's hazard regression model was used to identify the prognostic factors with the entry factors of gender, age (≤ 60 years versus > 60 years), length of the primary lesion (≤ 5 cm versus > 5 cm), location of the primary lesion, macroscopic tumor type, pT, pN, pTNM stage, operation (radical/palliative), and chemotherapy (yes/no). The mean follow-up duration of this series was 24.7 months (1-121 months). Thirty-four patients died of the disease during the follow-up, five were still alive, and one was lost of follow-up. The median survival time of the 40 patients was 13.0 months (95% confidence interval 4.7-21.3), and the 6-, 12-, 24-, 36-, and 60-month overall survival rates (OS) were 77.5%, 56.4%, 28.9%, 23.7%, 10.5%, respectively. In univariate analysis, age (≤ 60 years versus >60 years) (P=0.049), operation (radical/palliative) (P=0.008), and chemotherapy (yes/no) (P= 0.013) significantly influenced the OS of the SCCE patients. In multivariate analysis, operation (P=0.015) and chemotherapy (P=0.031) were independent prognostic factors. The patients who received radical surgery and postoperative chemotherapy had relatively better survival. Surgical resection combined with chemotherapy should be recommended to patients with limited disease SCCE.

Minocycline prevents impaired glial glutamate uptake in the spinal sensory synapses of neuropathic rats.

Activation of glutamate receptors and glial cells in the spinal dorsal horn are two fundamental processes involved in the pathogenesis of various pain conditions, including neuropathic pain induced by injury to the peripheral or central nervous systems. Numerous studies have demonstrated that minocycline treatment attenuates allodynic and hyperalgesic behaviors induced by tissue inflammation or nerve injury. However, the synaptic mechanisms by which minocycline prevents hyperalgesia are not fully understood. We recently reported that deficient glutamate uptake by glial glutamate transporters (GTs) is key for the enhanced activation of N-methyl-d-aspartate (NMDA) receptors in the spinal sensory synapses of rats receiving partial sciatic nerve ligation (pSNL). In this study, we investigated how minocycline affects activation of NMDA receptors in the spinal sensory synapses in rats with pSNL by whole cell recordings of NMDA currents in spinal laminea I and II neurons from spinal slices. The effects of minocycline treatments on the dorsal horn expression of glial GTs and astrocyte marker glial fibrillary acidic protein (GFAP) were analyzed by immunohistochemistry. We demonstrated that normalized activation of NMDA receptors in synapses activated by both weak and strong peripheral input in the spinal dorsal horn is temporally associated with attenuated mechanical allodynia in rats with pSNL receiving intraperitoneal injection of minocycline. Minocycline ameliorated both the downregulation of glial GT expression and the activation of astrocytes induced by pSNL in the spinal dorsal horn. We further revealed that preventing deficient glial glutamate uptake at the synapse is crucial for preserving the normalized activation of NMDA receptors in the spinal sensory synapses in pSNL rats treated with minocycline. Our studies suggest that glial GTs may be a potential target for the development of analgesics.

Glial glutamate transporter 1 regulates the spatial and temporal coding of glutamatergic synaptic transmission in spinal lamina II neurons.

Glutamatergic synaptic transmission is a dynamic process determined by the amount of glutamate released by presynaptic sites, the clearance of glutamate in the synaptic cleft, and the properties of postsynaptic glutamate receptors. Clearance of glutamate in the synaptic cleft depends on passive diffusion and active uptake by glutamate transporters. In this study, we examined the role of glial glutamate transporter 1 (GLT-1) in spinal sensory processing. Excitatory postsynaptic currents (EPSCs) of substantia gelatinosa neurons recorded from spinal slices of young adult rats were analyzed before and after GLT-1 was pharmacologically blocked by dihydrokainic acid. Inhibition of GLT-1 prolonged the EPSC duration and the EPSC decay phase. The EPSC amplitudes were increased in neurons with weak synaptic input but decreased in neurons with strong synaptic input upon inhibition of GLT-1. We suggest that presynaptic inhibition, desensitization of postsynaptic AMPA receptors, and glutamate "spillover" contributed to the kinetic change of EPSCs induced by the blockade of GLT-1. Thus, GLT-1 is a key component in maintaining the spatial and temporal coding in signal transmission at the glutamatergic synapse in substantia gelatinosa neurons.

Clinical and experimental findings in humans and animals with chemotherapy-induced peripheral neuropathy.

Pain arises from numerous causes in cancer patients. Well known to cancer care providers, but perhaps less well so to others, is that the main causes of pain in cancer patients in fact arise due to cancer treatments more so than the disease itself. In this paper clinical and laboratory findings on the characteristics of chemotherapy-induced neuropathic pain are reviewed and a scheme for the underlying mechanisms is outlined.

Inhibition of glutamate uptake in the spinal cord induces hyperalgesia and increased responses of spinal dorsal horn neurons to peripheral afferent stimulation.

Glutamate is a primary excitatory neurotransmitter in the mammalian CNS. Glutamate released from presynaptic neurons is cleared from the synaptic cleft passively by diffusion and actively by glutamate transporters. In this study, the role of glutamate transporters in sensory processing in the spinal cord has been investigated in behavioral, in vivo and in vitro experiments. Intrathecal application of a non-selective glutamate transport inhibitor, L-trans-pyrrolidine-2,4-dicarboxylic acid (10 microl of 100 microM solution) induced hypersensitivity to peripheral mechanical and thermal stimuli. Topical application of L-trans-pyrrolidine-2,4-dicarboxylic acid (100 microM) onto the dorsal surface of the L3-L6 spinal cord increased spontaneous activities, innocuous and noxious stimulus-evoked responses and after-discharges of wide dynamic range neurons in the L4-5 spinal segments. Whole cell recordings made from superficial dorsal horn neurons in an isolated whole spinal cord from newborn rats (2-3 weeks old) revealed that bath-applied L-trans-pyrrolidine-2,4-dicarboxylic acid (100 microM) produced partial membrane depolarization, increased spontaneous action potentials with decreased neuronal membrane resistance and time constant, but without significant changes of capacitance. Finally, the amplitude and duration of primary afferent evoked-excitatory postsynaptic currents recorded from neurons in the substantia gelatinosa in the spinal slices from young adult rats (6-8 weeks old) were increased in the presence of L-trans-pyrrolidine-2,4-dicarboxylic acid (100 microM). This study indicates that glutamate transporters regulate baseline excitability and responses of dorsal horn neurons to peripheral stimulation, and suggests that dysfunction of glutamate transporters may contribute to certain types of pathological pain.

Altered discharges of spinal wide dynamic range neurons and down-regulation of glutamate transporter expression in rats with paclitaxel-induced hyperalgesia.

Changes in the signaling of wide dynamic range neurons and the expression of glutamate transporters in the lumbar spinal dorsal horn of rats with Taxol-induced hyperalgesia are detailed in this report. Deep spinal lamina neurons have significantly increased spontaneous activity and after-discharges to noxious mechanical stimuli, increased responses to both skin heating and cooling, and increased after-discharges and abnormal windup to transcutaneous electrical stimuli. The expression of glutamate transporter proteins in the dorsal horn is decreased at the time point corresponding to the physiological changes. These results suggest a state of increased excitability develops in spinal pain-signaling neurons as a consequence of decreased glutamate clearance. These changes in dorsal horn neurobiology likely in turn contribute to the hyper-responsiveness to sensory stimuli seen in animals treated with Taxol and may play a role in the pain seen in cancer patients receiving Taxol.

Response properties of dorsal root reflexes in cutaneous C fibers before and after intradermal capsaicin injection in rats.

C fiber dorsal root reflexes (DRR) contribute to neurogenic inflammation and possibly also to touch-evoked pain (allodynia) induced by intradermal capsaicin. The responses of C fibers in the sural nerve to graded mechanical stimuli before and following intradermal capsaicin were studied in 39 adult male rats. Two-thirds of 111 fibers were without spontaneous activity, while the remaining fibers averaged 1.41+/-0.25 spontaneous antidromic spikes per second. Among the quiescent C fibers only two had excitatory receptive fields, whereas the active C fibers showed three patterns of activity, an excitatory response, an inhibitory response, or no response to mechanical stimulation. The excitatory responses were to high intensity mechanical stimuli alone, while inhibitory responses were evoked in a graded fashion by both noxious and innocuous mechanical stimuli. Intradermal injection of capsaicin increased spontaneous and evoked DRRs in all C fibers with excitatory responses to mechanical stimuli, but none acquired responses to innocuous stimuli. Capsaicin initially produced inhibition of spontaneous activity in C fibers with inhibitory or no receptive fields, but this later resumed and achieved a rate higher than baseline. Mechanical stimuli re-applied following the resumption of spontaneous discharges failed to produce any response. Spontaneous DRRs were increased by topical application of 1 mM beta-alanine (a competitive antagonist for GABA transporters) and abolished by ipsilateral spinal nerve L5 lesion, verifying antidromic origin. The role of C fiber DRRs in normal sensory transmission and during hyperalgesia is discussed.

Cyclooxygenase inhibitors and thalidomide ameliorate vincristine-induced hyperalgesia in rats.

In this study ibuprofen (50.0 mg/kg, i.p.), rofecoxib (10.0 mg/kg, i.p.) and thalidomide (50.0 mg/kg, oral) were shown to prevent vincristine-induced mechanical hyperalgesia. Sprague-Dawley rats were injected every other day with vincristine (0.1 mg/kg) over 13 days. The animals were cotreated daily with vehicle (saline), ibuprofen, rofecoxib or thalidomide throughout the period of vincristine treatment. Mechanical withdrawal threshold to punctuate and radiant heat stimuli were determined prior to and then on alternate days throughout the treatment period. Vincristine vehicle-treated animals developed marked mechanical hyperalgesia from day 5 of chemotherapy and this lasted until the end of the experiment. Thermal thresholds were not altered by the administration of vincristine vehicle. Animals in the vincristine vehicle group neither gained nor lost weight during the treatment period. All three active drugs showed an antihyperalgesic effect on the responses to mechanical stimulation of the hind paw that was significant from day 5 for ibuprofen and thalidomide and from day 7 for rofecoxib. Thermal thresholds increased after the administration of both the NSAIDs and thalidomide. Rofecoxib was the only drug to show any beneficial effect in protecting the animals from failure to gain body weight.

Sensitization of dorsal root reflexes in vitro and hyperalgesia in neonatal rats produced by capsaicin.

The maturation of dorsal root reflexes (DRRs) in lumbar roots was characterized in neonatal rats at 1, 2 and 3 weeks after birth using an in vitro isolated spinal cord preparation with attached dorsal roots and dorsal root ganglia (DRG). Changes of DRRs in rats of increasing age were also tested by administration of capsaicin to the DRG and related to spinal mechanisms of hyperalgesia by defining the behavioral responses of neonatal rats to intradermal capsaicin. DRRs evoked by stimulating the adjacent root in 1 week old rats are characterized by highly desynchronized waveforms with power spectra concentrated at frequencies greater than 200 Hz. DRRs in 1 week old rats show very little change in amplitude or area with increasing afferent stimulation strength. In contrast DRRs in 2 and 3 weeks old rats are highly synchronized with power concentrated at frequencies less than 100 Hz and show a graded increase in amplitude and area with increasing stimulus strength. The recovery of DRR amplitude in a paired pulse stimulus protocol is faster in 1 week rats than in 2 or 3 weeks old rats. Finally, DRRs in 2 and 3 week old rats show increased amplitude and area following application of capsaicin to the DRG of the stimulating root whereas those in 1 week old rats do not. These changes parallel the behavioral responses of neonatal rats as 2 and 3 weeks old rats show secondary mechanical hyperalgesia following intradermal capsaicin, but 1 week old rats do not. Our data indicate that the spinal circuitry for DRRs in the neonatal period undergoes rapidly dynamic development in the rat. This development is sufficiently rapid that mechanisms of spinal sensitization induced by capsaicin can be studied in rats 2 weeks old and older.

Changes in sensory processing in the spinal dorsal horn accompany vincristine-induced hyperalgesia and allodynia.

Abnormal sensation and pain are major dose-limiting factors in cancer chemotherapy with vincristine. In this study, we have adapted a model of this condition by using repeated daily intraperitoneal injections of vincristine in rats. Mechanical allodynia and hyperalgesia without change in responses to thermal stimuli were first observed following 5-8 days of vincristine treatment (0.1mg/kg/day) and then persisted throughout the remainder of the treatment interval (2-3 weeks). Electrophysiological recording from wide dynamic range (WDR) neurons in the lumbar (L4-L5) spinal dorsal horn in hyperalgesic rats demonstrated significantly increased spontaneous activity and after-discharges to noxious mechanical stimuli (von Frey filaments with a bending force greater than 58.02mN, skin compression 1.3 and 3N, 1mm(2)), increased acute A- and C-fiber responses, after-discharges and abnormal 'wind-up' to electrical stimuli (5mA, 2ms) at 0.1Hz applied across the receptive field. These results suggest a state of central sensitization develops in spinal WDR neurons with repeated vincristine treatment that contributes to the spontaneous pain and hyperalgesia seen in patients and the hyperresponsiveness to sensory stimuli seen in animals treated with vincristine.

Physiological changes in primate somatosensory thalamus induced by deafferentation are dependent on the spinal funiculi that are sectioned and time following injury.

The importance of spike bursts in thalamo-cortical processing of sensory information has received an increasing amount of interest over the past several years. Previously it has been reported that short high-frequency spike trains (3-8 action potentials occurring at 67-167 Hz), or spike bursts, are increased in both human and non-human primate thalamus following deafferentation. Here we examine the effects of lesion of the ventral spinal quadrant alone versus combined lesion of the ventral and dorsal spinal quadrants on the evoked and spontaneous spike trains in thalamic neurons. A total of 1175 neurons were sampled from 13 animals, three intact, six with ventral quadrant lesions (three with prolonged survival and three with short-term survival after spinal lesion) and four with combined ventral and dorsal quadrant lesions. Detailed analysis was conducted on 256 of these neurons, which revealed that thalamic neurons of animals with ventral quadrant lesions had elevated burst and non-burst spike rates while neurons from animals with combined ventral-dorsal lesions showed two types of change. Neurons in the forelimb areas showed increased bursts without a change in non-burst activity, while neurons in lateral VPL without receptive fields showed very low non-burst activity, but high burst spike rates. The magnitude of the effects produced by ventral-lateral spinal lesions was more pronounced in the short-term survival animals than in the long-term survival animals. These results show that the effects of deafferentation on the physiological properties of thalamic neurons are dependent on the afferent tract or tracts that are lesioned and the time after lesion.

Tuning of membrane properties regulates subliminal synapses in dorsal horn neurons of intact rats.

Functional plasticity in receptive field properties underlies the mechanism whereby spinal dorsal horn neurons encode changes in pain sensitivity following peripheral injury. Activation of "silent" or subliminal excitatory synapses was hypothesized to account for this injury-induced neural plasticity. To better characterize the mechanisms governing subliminal inputs, we adapted whole-cell patch clamp to the study of dorsal horn neurons in intact, anesthetized rats. In this report we show that the membrane properties of spinal cells correlate to functional class defined by action potential responses to cutaneous stimuli. In addition, we report the discovery of a novel "silent" population of neurons with solely subliminal excitatory inputs at rest that can be activated by membrane depolarization. Finally, an induced change in baseline membrane potential to a level nearer that of a different functional class results in a corresponding change in the responses to cutaneous stimuli of a given cell to that of the new functional class. In summary our findings suggest that biophysical membrane properties are key factors determining the functional profile of spinal neurons. The rapid change of such properties may regulate the function of silent synapses in spinal neurons and underlie rapid development of neural plasticity.

Age-dependency of analgesia elicited by intraoral sucrose in acute and persistent pain models.

Treatment of pain in newborns is associated with problematic drug side effects. Previous studies demonstrate that an intraoral infusion of sucrose and other sweet components of mother's milk are effective in alleviating pain in infant rats and humans. These findings are of considerable significance, as sweet tastants are used in pain and stress management in a number of clinical procedures performed in human infants. The ability of sweet stimuli to induce analgesia is absent in adult rats, suggesting that this is a developmentally transient phenomenon. However, the age range over which intraoral sucrose is capable of producing analgesia is not known. We investigated the effects of intraoral sucrose (7.5%) on nocifensive withdrawal responses to thermal and mechanical stimuli in naive and inflamed rats at postnatal days (P) P0-21. In some rats, Complete Freund's adjuvant (CFA) was injected in a fore- or hindpaw to produce inflammation. In non-inflamed animals, for noxious thermal stimuli, sucrose-induced analgesia emerged at P3, peaked at P7-10, then progressively declined and was absent at P17. For mechanical forepaw stimuli, sucrose-induced analgesia emerged, and was maximal at approximately P10, then declined and was absent at P17. By contrast, maximal sucrose-induced analgesia for mechanical hindpaw stimuli was delayed (P13) compared to that for the forepaw, although it was also absent at P17. In inflamed animals, sucrose reduced hyperesthesia and hyperalgesia assessed with mechanical stimuli. Sucrose-induced analgesia in inflamed animals was initially present at P3 for the forepaw and P13 for the hindpaw, and was absent by P17 for both limbs. Intraoral sucrose produced significantly greater effects on responses in fore- and hindpaws in inflamed rats than in naive rats indicating that it reduces hyperalgesia and allodynia beyond its effects on responses in naive animals. These findings support the hypothesis that sucrose has a selective influence on analgesic mechanisms and that an enhanced sucrose effect takes place in hyperalgesic, inflamed animals as compared to naive animals. Taken together, these results indicate that intraoral sucrose alleviates transient pain in response to thermal and mechanical stimuli, and also effectively reduces inflammatory hyperalgesia and allodynia. Sucrose-induced analgesia is age-dependent and limited to the pre-weaning period in rats. The age-dependency of sucrose-induced analgesia and its differential maturation for the fore- and hindpaw may be due to developmental changes in endogenous analgesic mechanisms and developmental modulation of the interaction between gustatory and pain modulatory pathways.

Sensory processing in the deep spinal dorsal horn of neurokinin-1 receptor knockout mice.

BACKGROUND: The neurokinin-1 receptor and its primary ligand, substance P, are widely recognized as contributing to the spinal processing of nociceptive stimuli, yet the specific function of the neurokinin-1 receptor remains unclear. METHODS: To better clarify these functions, the authors examined the neurophysiologic responses of L4-L5 neurons in the deep dorsal horn to acute mechanical, thermal, and electrical stimuli in knockout and wild-type mice. In addition, the capacity of knockout and wild-type mice to show wind-up to repeated C-fiber stimuli and to show sensitization after cutaneous mustard oil was assessed. RESULTS: A total of 68 nociceptive neurons (35 in knockout, 33 in wild type) in laminae III-V were studied. No differences in the acute responses of neurons in knockout and wild-type mice to graded mechanical, thermal, or electrical stimuli or in the acute responses to mustard oil were observed. However, wind-up to repeated electrical stimulation at C-fiber intensity was significantly attenuated in the knockout mice compared with wild type controls. In addition, mustard oil-induced mechanical hypersensitivity was significantly reduced in the knockout mice. CONCLUSIONS: These results indicate that neurokinin-1 receptors do not play a significant role in the responses of nociceptive neurons in the deep spinal dorsal horn to acute noxious mechanical, thermal, electrical, or chemical stimuli. On the other hand, neurokinin-1 receptors are critical for the central hyperexcitability that is observed in these neurons with repeated C-fiber inputs and to the central sensitization induced by topical mustard oil application.

Functional plasticity in primate somatosensory thalamus following chronic lesion of the ventral lateral spinal cord.

The long-term consequences of thoracic spinothalamic tract lesion on the physiological properties of neurons in the ventral posterior lateral nucleus of the thalamus in monkeys were assessed. Neurons responding to both compressive and phasic brush stimuli (multireceptive neurons), but not brush-specific (low-threshold) neurons, in the partially deafferented thalamus showed increased spontaneous activity, increased responses evoked by cutaneous stimuli and larger mean receptive field size than the same types of cells in the thalamus with intact innervation. The spike train properties of both the spontaneous and evoked discharges of cells were also altered so that there was an increased incidence of spike-bursts in cells of deafferented thalamus. These changes were widespread in the thalamus, and included cells in both the fully innervated forelimb representation and the partially denervated hindlimb representation ipsilateral to the lesion. The spontaneous and evoked spike trains in the ipsilateral thalamus also show increased frequency of both spike-burst and non-burst events compared to the intact thalamus. These results indicate that chronic spinothalamic tract lesion produces widespread changes in the physiological properties of a discrete cell population of the thalamus.The findings in this study indicate that the thalamic processing of somatosensory information conveyed by the lemniscal system is altered by transection of the spinothalamic tract. This change in sensory processing in the thalamus would result in altered cortical processing of innocuous somatosensory inputs following deafferentation and so possibly contribute to the generation of the central pain syndrome.

GABAA receptor blockade inhibits A beta fibre evoked wind-up in the arthritic rat.

To clarify the mechanisms of allodynia we have examined whether 'wind-up' of nociceptive withdrawal reflexes (NWR), a phenomenon characteristic of nociceptive C fiber spinal processing, can be mimicked by stimulation of tactile A beta fibers in monoarthritic decerebrate spinal rats. Knee joint monoarthritis was induced by carrageenan/kaolin under halothane anaesthesia 5 h before recordings. In arthritic, but not in control rats, wind-up of NWR of the semitendinosus muscle could be evoked by repeated stimulation of A beta fibres. By contrast, peroneus longus reflexes did not exhibit marked wind-up. Bicuculline (0.03-0.3 mg/kg, i.v.) dose-dependently inhibited this wind-up. Hence, reflex wind-up can be elicited by tactile A beta fibers in arthritis rats through a GABAA dependent mechanism.

On the cutaneous receptors contributing to withdrawal reflex pathways in the decerebrate spinal rat.

Previous studies indicate that the withdrawal reflex system in the rat has a "modular" organization, each reflex pathway performing a specific sensorimotor transformation. Here, we wished to clarify which cutaneous receptors contribute to this system and to determine whether there are differences in this respect between reflex pathways of different muscles. Withdrawal reflexes of the peroneus longus, extensor digitorum longus, and semitendinosus muscles were recorded with EMG techniques during high reflex excitability in decerebrate spinal rats (n=26). While maintained innocuous pressure on glabrous skin could elicit a sustained reflex activity in all muscles studied, vibration of glabrous skin (10-300 Hz) always failed to evoke a reflex response, suggesting that slowly adapting, but not rapidly adapting, low-threshold mechanoreceptive fibers from this type of skin contribute to withdrawal reflex pathways. Thermal stimulation in the innocuous range, i.e., cooling from 32 to 17 degrees C, or warming the skin from 32 to 41 degrees C, always failed to produce reflex responses, indicating that neither cold nor warm receptors contribute to withdrawal reflex pathways. When either cooling or warming the skin to the noxious temperatures of 1 degrees C or above 45 degrees C, respectively, a reflex discharge was often evoked in the muscles studied. Intradermal administration of histamine, a potent pruritogenic substance, produced very weak, or no, reflex response. In contrast, mustard oil produced vigorous reflex responses in all muscles studied. These findings suggest that some chemonociceptors contribute only weakly, or not at all, to withdrawal reflex pathways. The present data suggest that a selective set of cutaneous receptors contribute to withdrawal reflex pathways and that different withdrawal reflex pathways receive input from essentially the same cutaneous receptor types.

Developmental adaptation of rat nociceptive withdrawal reflexes after neonatal tendon transfer.

Nociceptive withdrawal reflexes (NWRs) were studied in adult rats in which the movement patterns produced by single muscles had been altered by neonatal tendon transfer. NWRs evoked by cutaneous noxious mechanical and thermal (CO2-laser) stimulation were recorded using electromyography in a decerebrate spinal preparation. The sensitivity distribution within the receptive fields of the NWRs of the extensor digitorum longus and the peronei muscles exhibited changes corresponding to the altered movement patterns. No detectable change of NWRs was found in normal muscles whose receptive fields overlapped that of the modified muscle. Furthermore, NWRs of muscles that regained an essentially normal function after neonatal tendon transfer did not differ from normal. It is proposed that a developmental experience-dependent mechanism, which takes into account the hindlimb movement pattern caused by contraction of single muscles, underlies the functionally adapted organization of adult NWRs.