Pathophysiologie des Rückenschmerzes und seine Chronifizierung

The present article concentrates on mechanisms that lead to the excitation of nociceptors in soft tissues and nociceptive neurones in the spinal dorsal horn. These mechanisms may contribute to the so-called unspecific low back pain. Properties of nociceptors in soft tissues: A nociceptive ending in soft tissue contains a multitude of receptor molecules in its membrane. The molecular receptors include binding sites for algesic substances that are released during painful stimulation or pathologic alterations of the tissue: bradykinin (BK), serotonin (5-HT), prostaglandin E2 (PG E2), adenosine triphosphate (ATP) and protons (H(+)). The excitation and sensitisation of nociceptors by these substances can be explained by the binding of the substances to the receptor molecules in the membrane of the receptive ending and ensuing opening of ion channels or activation of metabolic cascades. Purinergic receptor molecules in the membrane of nociceptors are activated by ATP. These receptors may be of particular importance for deep somatic pain, because ATP is present in large amounts in muscle tissue and is released during muscle damage. ATP-sensitive nociceptors appear to be distinct from nociceptors that can be excited by protons. The conduction of nociceptive information from muscle to the spinal cord is partly carried by unmyelinated fibres that possess tetrodotoxin-resistant (TTX-r) Na(+)-channels. Therefore, a drug that specifically blocks TTX-r Na(+)-channels would be a new attractive tool in the treatment of patients with deep somatic pain. Chronic muscle lesions such as a myositis have been shown to be associated with a higher innervation density of the tissue with free nerve endings that contain the neuropeptide substance P (SP). Many of these endings are likely to be nociceptors. Since a painful stimulus that acts on a muscle with increased nociceptor density will excite more nociceptors and elicit more pain, the increase in nociceptor density constitutes a peripheral mechanism for hyperalgesia. In muscle free nerve endings - many of which are nociceptive - the neuropeptides SP, calcitonin gene-related peptide (CGRP) and somatostatin have been shown to be present. These substances are released from the receptive endings in muscle when they are stimulated. SP and CGRP have a strong effect on blood vessels and induce local vasodilatation and oedema. The local oedema in the vicinity of the nociceptor is associated with the release of BK from plasma proteins, which increases the excitability of the nerve ending (see below). Thus, a local vicious cycle forms that may contribute to the formation of trigger points. Sensitisation of nociceptors and peripheral hyperalgesia: Nociceptors are easily sensitised, i.e. following a conditioning stimulus they are more sensitive to the unconditioned stimulus. In animals and humans, the responses to injections of BK can be increased by 5-HT or PG E2. The responses of muscle nociceptors to mechanical stimuli are likewise enhanced after administration of BK. During overuse, ischemia or inflammation of soft tissues, the tissue concentrations of BK, PG E2, and 5-HT are elevated and sensitise muscle nociceptors. A sensitised nociceptor is excited and elicits pain when innocuous mechanical stimuli act on the muscle, e.g. during contractions or stretch. Therefore, in chronically altered soft tissues, weak everyday stimuli are likely to cause pain. Mechanisms at the spinal level: In experiments on rats in which a myositis of the gastrocnemius-soleus (GS) muscle was induced experimentally, the effects of a peripheral painful lesion on the discharge behaviour of sensory dorsal horn neurones were studied. One of the main effects of the myositis was an expansion of the input (target) region of the muscle nerve, i.e. the population of dorsal horn neurones responding to an electrical standard stimulus applied to the GS muscle nerve grew larger. One reason for the myositis-induced expansion of the input region is hyperexcitability of the neurones caused by the release of SP and glutamate from the spinal terminals of muscle afferents with ensuing activation of NMDA channels in dorsal horn neurones (central sensitisation). The central sensitisation is of clinical importance because it can explain the hyperalgesia and spread of pain in patients. In contrast to excitability, the resting activity of dorsal horn neurones - which is likely to induce spontaneous pain in patients - does not appear to depend on the release of SP and glutamate but on the concentration of nitric oxide (NO) in the spinal cord. A pharmacological block of the NO synthesis led to a significant increase in background activity without affecting the excitability of the dorsal horn neurones. Such an increase in background activity was observed exclusively in nociceptive neurones, i.e. a local lack of NO in the spinal cord induces spontaneous pain. According to data from animal experiments, a decrease in the spinal NO concentration occurs as a sequel of a chronic muscle lesion; therefore, a lack of NO is a probable factor for the induction of chronic spontaneous pain. Normally, lesion-induced pain subsides and does not develop into chronic pain. The mechanisms governing the return to normal neuronal behaviour after a peripheral lesion are not well studied. Probably, the activation of inhibitory mechanisms, e.g. increased spinal synthesis of GABA or elevated activity of the descending antinociceptive system contribute to the restoration of normal function. The final step in the transition from acute to chronic pain are structural changes that perpetuate the functional changes. In the rat myositis model, an increase in the number of synapses on the surface of NO-snythesizing cells was present 8 h following induction of the myositis. These data show that structural changes appear quite early in the development of a painful disorder. A novel hypothesis for the development of chronic pain states that a strong nociceptive input to the spinal cord leads to cell death predominantly in inhibitory interneurones. Most of these interneurones are assumed to be tonically active; when their number decreases, the nociceptive neurones are chronically disinhibited and elicit continuous pain also in the absence of a noxious stimulus.     

Stickstoffmonoxid-Mangel im Rückenmark als möglicher Faktor für die Entstehung von Spontanschmerzen

AIM OF THE STUDY: The role of nitric oxide (NO) in the processing of nociceptive information is controversely discussed. The present review aims at answering the questions how a spinal lack of NO influences the discharge behaviour of dorsal horn neurones, and if the NO-synthesising neurones exhibit a change in histologically visualised cell numbers under the influence of a nociceptive input from the body periphery. METHODS: The data were obtained from anaesthetised rats. The impulse activity of single sensory dorsal horn neurones was recorded with glass microelectrodes. In the spinal segments studied, the NO synthase (NOS) was blocked with L-NAME. The NO-synthesising cells were visualized histochemically with the diaphorase reaction or immunohistochemically with antibodies to the NOS. RESULTS: The inhibition of the NO synthesis by L-NAME was followed by a marked increase in the background activity almost exclusively in nociceptive neurones. In the histological evaluation, the NO-synthesising neurones reacted to a nociceptive input with an initial increase in cell number which was followed by a decrease. CONCLUSIONS: Normally, a tonic release of NO in the spinal cord appears to exist which inhibits the discharges of nociceptive dorsal horn neurones. Accordingly, a local lack of NO synthesis leads to an increase in the electrical activity in these neurones. Under chronic painful conditions there is a decrease in the number of NO-synthesising cells which is associated with a lack of NO in the dorsal horn. If such changes occur also in patients they are likely to cause spontaneous pain. Thus, NO could be an important factor for spontaneous pain in patients with chronic painful lesions in the body periphery.     

Long-term changes in discharge behaviour of cat dorsal horn neurones following noxious stimulation of deep tissues

Certain pathological types of afferent input are supposed to lead to long-term changes in the responsiveness of dorsal horn neurones. This mechanism might be of importance for the development of neurological disturbances such as chronic pain. The present study was undertaken in order to find out whether dorsal horn neurones--particularly those processing input from deep tissues--exhibit long-lasting changes in response behaviour after a short-lasting noxious stimulation of deep tissue. In anaesthetized cats, the impulse activity of single dorsal horn cells was recorded extracellularly with glass microelectrodes. In a small number of cells that had multiple receptive fields (RFs), the algesic agent bradykinin was injected into a muscle RF and the properties of all RFs retested at regular time intervals. Following noxious chemical stimulation of one RF, the injected and the other RFs of the same neurone often showed changes which consisted of an increase in size, a lowering of mechanical threshold and appearance of new RFs. In an attempt to assess the influence of a single noxious stimulus on the entire population of dorsal horn cells, the properties of a greater sample of neurones were compared before and after injection of bradykinin into the deep tissues of the hind limb. Every cell encountered was classified as being driven by (1) cutaneous receptors only, (2) deep receptors only, (3) both input sources, or (4) electrical stimulation only (cell without receptive field). Following injection of bradykinin, the proportion of cells with both deep and cutaneous input and of those having background activity rose, and the percentage of cells without a receptive field decreased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tonic descending inhibition affects intensity coding of nociceptive responses of spinal dorsal horn neurones in the cat

The supraspinal inhibitory control of lumbar spinal dorsal horn neurones was investigated in N2O-anaesthetized cats by reversibly blocking conduction in the spinal cord. Dorsal horn neurones selected for this study had convergent input from myelinated (A-) and unmyelinated (C-) fibres in the posterior tibial and/or superficial peroneal nerves of the hind limb. Virtually all of them could also be excited by noxious heating of the skin of the footpad region and by low intensity mechanical stimulation of the foot. Variation of the temperature of noxious radiant skin heating (40-56 degrees C, 10 sec in duration) resulted in graded responses of the neurones. The stimulus-response functions (SRF) were monotonic; in the majority of 32 cases they were linear. Neurones could be classified according to their maximum discharge frequency in response to skin heating into 22 weakly sensitive units (responses below 100 Hz at 50 degrees C) and 10 highly sensitive units (above 100 Hz). Responses outlasted the period of skin heating by seconds to minutes. A reversible conduction block of spinal axons by cooling a 15 mm cord segment (L1) with a thermode at 0 degrees C affected the responsiveness of the dorsal horn neurones in 12 of 15 cases. The maximum discharge frequency to a certain temperature of skin heating was increased during the spinal block. The duration of heat-evoked discharges was either not changed or increased during the spinal block. The SRF were reversibly displaced during the spinal blockade to higher discharge frequencies and lower threshold temperatures of skin heating. In 8 of 12 cases the change in the SRF was a nearly parallel shift, whereas in 4 units the increase of responsiveness had a complex effect upon the SRF. The decrease in the threshold to skin heating ranged up to 4.5 degrees C; the mean decrease was 2 degrees C. It is confirmed that in anaesthetized cats, nociceptive spinal neurones are subject to a tonically active descending inhibition, which is interrupted by local spinal cooling. The effect of the spinal block on the SRF of the neurones suggests that this tonic inhibition is similar to that produced by electrical stimulation in the lateral reticular formation of the brain-stem.     

Selective changes of receptive field properties of spinal nociceptive neurones induced by noxious visceral stimulation in the cat.

This study was designed to examine the central changes in the receptive field properties of dorsal horn neurones induced by a period of visceral noxious stimulation. The aim of this investigation was to establish whether noxious stimulation of the visceral input to the spinal cord could influence transmission of cutaneous information through dorsal horn neurones. Single-unit electrical activity was recorded in the lower thoracic spinal cord of anaesthetized cats from dorsal horn neurones with a somatic receptive field in the ipsilateral flank. Changes in the properties of these receptive fields induced by reversible spinalization (by means of a cold block 4 or 5 segments rostral to the recording electrodes) and by a conditioning noxious stimulation of the biliary system (3 successive distensions of the gall bladder for 30 sec at 65-80 mm Hg at 1-min intervals) were analysed. Nineteen neurones have been studied, 10 of which could be driven by stimulation of the gall bladder. All of these 10 cells showed increases in the size of their cutaneous receptive fields following conditioning noxious stimulation of the biliary system. The increases were large and lasted for at least 20 min. None of the 9 spinal cord neurones without an input from the gall bladder were affected by the conditioning visceral stimulus even though 7 showed changes in receptive field size when the animals were spinalised. These results show that noxious stimulation of viscera can evoke increases in the somatic receptive fields of spinal cord neurones but only of those neurones which are also driven by the visceral stimulus.     

Acute muscle inflammation enhances the monosynaptic reflexes and c-fos expression in the feline spinal cord.

The aim of this research was to study the changes of the motor reflex activity (monosynaptic reflex (MSR) of the flexor and extensor muscles) and Fos immunoreactivity in lumbo-sacral spinal cord after acute induced myositis of m. gastrocnemius-soleus (GS). The experiments were carried out on ischaemic decerebrated, spinalized in C1 cats. After infiltration of the GS muscle with carrageenan (2%) MSRs of flexors and extensors showed a significant increase in amplitude +127+/-24.5% and +155+/-28.5%, respectively, p<0.05. The exposed effect was initiated within 30 min and achieved a maximum 2.8h after the intramuscular injections of carrageenan. After analysis of dynamics of the MSRs, animals were perfused and c-fos expression in the spinal segments L6-S1 was evaluated. In comparison to sham-operated animals, the number of Fos-immunoreactive (Fos-ir) cells was noticeably increased in the lumbar cord of cats with carrageenan-induced myositis. The labeled cells were concentrated in the ipsilateral laminae I/II, neck of the dorsal horn (V/VI) and intermediate zone (VII), however, clear predominance of their concentration was found in the deep laminae. The effect of muscle inflammation was also expressed as a significant decline in the number of NADPH-d-reactive cells (p<0.05) in ipsilateral laminae I/II of L6/L7. The results show that the input from acutely inflamed muscles may induce an increase of the reflex responsiveness of flexors and extensors which is not mediated via the gamma-spindle-loop and which coincides with a significant increase in c-fos expression in the deep laminae of the lumbar spinal cord.     

Nociceptive input from the rat thoracolumbar fascia to lumbar dorsal horn neurones

In anaesthetised rats, systematic electrophysiological recordings from dorsal horn neurones in spinal segments Th13–L5 were made to obtain information about the spinal nociceptive processing from the lumbar thoracolumbar fascia. Six to fourteen percent of the neurones in the spinal segments Th13–L2 had nociceptive input from the thoracolumbar fascia in naïve animals, no neurones responsive to input from the lumbar fascia were found in segments L3–L5. The segmental location of the receptive fields in the fascia was shifted 2–4 segments caudally relative to the spinal segment recorded from. Most neurones were convergent in that they received additional input from other deep somatic tissues in the low back (87%) and from the skin in the abdominal wall or the proximal leg (50%). The proportion of neurones responsive to input from the thoracolumbar fascia rose significantly from 4% to 15% (P < 0.05) in animals with an experimentally-induced inflammation of a low back muscle (multifidus). Moreover, neurones in spinal segment L3 – that did not receive input from the fascia in normal animals – responded to fascia input in animals with inflamed muscle. The data suggest that the nociceptive input from the thoracolumbar fascia contributes to the pain in low back pain patients.     

The effect of conduction block on the spinal release of immunoreactive-neuropeptide Y (ir-NPY) in the neuropathic rat

Peripheral nerve injury may result in significant changes in neuropeptide production and the development of neuropathic pain behaviour. Rats with a chronic constriction injury of one sciatic nerve were used to study the spinal release of immunoreactive neuropeptide Y (ir-NPY), using the antibody-coated microprobe technique. Previous work has shown an increase in NPY synthesis by large to medium-sized primary afferent neurones, as well as a new area of ir-NPY release in the deep dorsal horn on the side of nerve injury, when compared to uninjured rats. The stimulus for spontaneous ir-NPY release was unclear, but may have been due to ectopic neuronal discharges developing after nerve injury. This study used local anaesthetic to block all electrical input from the injured nerve. No change was found in the new zone of spontaneous release of ir-NPY in the deep dorsal horn ipsilateral to nerve injury. It appears therefore, that ir-NPY is released from the central termination of primary afferent neurones, without regulation from neuronal activity in the primary afferent neurones themselves.     

A block of spinal nitric oxide synthesis leads to increased background activity predominantly in nociceptive dorsal horn neurones in the rat

Previous studies have shown that nitric oxide (NO) has a strong influence on the background (resting) activity of dorsal horn neurones. The background activity of dorsal horn neurones is generally assumed to be responsible for the presence of paraesthesia or spontaneous pain in patients depending on the functional type of neurones that are active. However, nothing is known about a possible selective action of NO - or a lack of NO - on a particular functional class of neurone. In the present study the background activity of lumbar dorsal horn neurones was examined in anaesthetized rats before and during spinal superfusion with L-NAME, an unspecific blocker of NO synthesis. The neurones were divided into five classes: (1) low-threshold mechanosensitive (LTM) cells with deep receptive fields (LTM deep units); (2) LTM cells with cutaneous receptive fields (LTM cutaneous units) (these two classes were considered to be non-nociceptive); (3) high-threshold mechanosensitive (HTM) deep cells; (4) HTM cutaneous cells; and (5) multireceptive (MR) cutaneous cells (the last three classes were assumed to be nociceptive). HTM neurones increased the frequency of their background activity significantly during L-NAME superfusion and 80% of the initially silent neurones became active after administration of the NOS blocker. MR neurones likewise increased their background activity. In contrast, the background activity of non-nociceptive (LTM) neurones was not significantly affected. The results support previous studies showing that NO has a tonic depressing effect on the background activity of dorsal horn neurones and demonstrate for the first time that this effect is largely restricted to nociceptive neurones. Therefore, a reduction in spinal NO synthesis which often occurs during a long-lasting peripheral lesion is likely to cause increased background activity in nociceptive neurones and thus might contribute to spontaneous pain in patients.     

The possible role of the NO-cGMP pathway in nociception: different spinal and supraspinal action of enzyme blockers on rat dorsal horn neurones

In the literature, the pro- or antinociceptive effects of nitric oxide (NO) and cyclic guanosine monophosphate (cGMP) are discussed controversially. Our laboratory and others have reported that in the spinal cord a local lack of NO has an excitatory action on the ongoing (background) activity of dorsal horn neurones. Here, we tested the hypothesis that this effect of NO is mediated by cGMP and that part of the controversy is due to differences in the spinal and supraspinal actions of both compounds. In anaesthetised rats, impulse activity of lumbar dorsal horn neurones was recorded, and blockers of NO- and cGMP-synthesis, as well as the phosphodiesterase 5 (PDE5) inhibitor sildenafil (which increases the cGMP level), or 8-Bromo-cGMP (a membrane permeable cGMP analogue) were administered spinally or supraspinally. Topical superfusion of the spinal cord with a blocker of the guanylyl cyclase (ODQ) to reduce the cGMP level led to an increase in background activity of nociceptive lumbar dorsal horn neurones similar to that caused by l-NAME, a blocker of the NO synthase. Spinal superfusion with sildenafil or 8-Bromo-cGMP had no excitatory effect. In contrast, injections of sildenafil or 8-Bromo-cGMP into the third cerebral ventricle caused an increased background activity in lumbar dorsal horn neurones, while l-NAME and ODQ were ineffective. The results show that at the spinal level, a lack of cGMP and NO has an excitatory action on dorsal horn neurones, whereas supraspinally an elevated level of cGMP is excitatory.     

Noxious thermal input from the rat tail: modulation by descending inhibitory influences

In anaesthetized rats, single fibres have been dissected from the tail nerves. Fibres were found which became excited when the temperature of water surrounding the tail was raised above 40 degrees C. Firing rate increased with stepwise increases in temperature, showing first a transient outburst followed by adaptation to a static level. Corresponding neurones were also found in the dorsal horn at the entry zone of the roots coming from the tail. The cord neurones had a higher threshold temperature of 42.5--45 degrees C. When the spinal cord was reversibly blocked by cooling in the thoracic region, then the threshold of the dorsal horn neurones was reduced to that of the afferent fibres. In addition, at suprathreshold temperatures dorsal horn activity was greater during cord blockade. We conclude that dorsal horn neurones responding to noxious heating are subject to a tonic descending inhibitory control.     

Chronic secondary hypersensitivity of dorsal horn neurones following inflammation of the knee joint

Intra-articular injection of Freund's complete adjuvant (FCA) into the rat knee joint produces a swelling of the joint and long lasting hypersensitivity. In this study we have used this model and in vivo electrophysiology to investigate the time course of spinal changes underlying chronic secondary hypersensitivity, by stimulating the ankle joint (an area outside the site of primary hypersensitivity), and have compared the results with behavioural data from the same population of animals at 4-8, 13-17 and 55-59 days following FCA injection. The magnitude of responses and the proportion of dorsal horn neurones receiving inputs from A beta- A delta- and C-fibre afferents were monitored. At all time points, there was a significant increase in the ongoing activity of deep dorsal horn neurones when compared to nai ve rats, correlating well with the behavioural hypersensitivity. Both the magnitude of neuronal responses, and the proportion of neurones responding to electrical or mechanical stimulation in an area of secondary hypersensitivity, were significantly increased 4-8 and 13-17 days following FCA injection. However, while there was still behavioural hypersensitivity at 55-59 days there was a substantial decline in the responses to mechanical stimulation and A-fibre responses to electrical stimulation, although the proportion of neurones responding in the C-fibre latency remained elevated. These results suggest that the behavioural hypersensitivity is due to hyperexcitability at the level of the dorsal horn reflected as an increase of both C-fibre responses and spontaneous activity.     

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

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

Effects of midazolam in the spinal nerve ligation model of neuropathic pain in rats

Potential changes in the spinal GABAergic activity after nerve injury were studied by comparing the effects of systemic administration of the benzodiazepine midazolam on the noxious evoked responses of dorsal horn in rats with spinal nerve ligation of neuropathy and control animals. The tight ligation of the L(5) and L6 spinal nerves was performed in adult male Sprague-Dawley rats and resulting mechanical and cold allodynia were assessed with von Frey hairs and the acetone drop test. Single unit extracellular recordings of dorsal horn neurones were performed 15-18 days after the surgery under halothane anaesthesia using transcutaneous electrical stimulation of the receptive field at three times the C-fibre threshold. The rats in the spinal nerve ligation group, but not in the sham-operated control group developed mechanical and cold allodynia. Subcutaneous administration of midazolam 0.1-3.0 mg/kg reduced the Adelta-fibre evoked activity in a dose-related manner in all study groups, but the C-fibre evoked activity was significantly reduced only in the spinal nerve ligation group. The inhibitory effects of s.c. midazolam were significantly reversed by i.t. administration of flumazenil, suggesting a spinal site of action. Midazolam reduced C-fibre evoked firing significantly more in the spinal nerve ligation model than in the non-operated or sham controls. These results indicate changes in the spinal GABAergic system in the neuropathic animals and could be of importance in the development of new treatments for neuropathic pain.     

A spinal mechanism of action is involved in the antinociception produced by the capsaicin analogue NE 19550 (olvanil)

We have studied the effect of NE 19550 (olvanil, N-(4-hydroxy-3-methoxyphenyl) methyl-9Z-octadecenamide), a capsaicin analogue with approximately equipotent antinociceptive activity in vivo compared with capsaicin, on nociceptive responses recorded from spinal dorsal horn neurones in vivo and from a spinal ventral root in vitro. In adult rats anaesthetized with halothane, antinociceptive doses of olvanil (20-40 mumol/kg, s.c.) reduced C-fibre responses evoked in wide dynamic range, lumbar dorsal horn neurones, by peripheral transcutaneous electrical stimulation. Intradermal injection of olvanil, localized to a discrete region of the peripheral receptive field, did not activate C-fibres nor change C-fibre evoked activation of dorsal horn neurones. Spinal intrathecal administration of olvanil attenuated C-fibre evoked responses and, at the highest concentration, significantly reduced A beta-fibre evoked activity. In the neonatal rat spinal cord/tail preparation maintained in vitro, superfusion of the cord with olvanil (500 nM-5 microM) did not evoke a depolarization but responses to peripheral noxious stimulation were attenuated. In a similar in vitro preparation of the neonatal rat spinal cord, the release of calcitonin gene-related peptide-like immunoreactivity (CGRP-LI) was measured in spinal cord superfusates. Capsaicin (2-10 microM) evoked a large release of CGRP-LI but olvanil (2-10 microM) produced only a small or undetectable release. Following the administration of each substance, however, the release of CGRP-LI evoked by a depolarizing potassium stimulus was significantly attenuated. These data indicate that C-fibre input to the dorsal horn was attenuated by acute systemic doses of olvanil that were antinociceptive in behavioural tests. This effect was unlikely to be due to impairment of C-fibre function by a peripheral locus of action but was more consistent with an action in the spinal cord in which the reduced release of a neurotransmitter substance from afferent nerve terminals may play a prominent role.     

Induction of long-term potentiation of single wide dynamic range neurones in the dorsal horn is inhibited by descending pathways

Previous studies have shown that long-term potentiation (LTP) in the dorsal horn may be induced by noxious stimuli. In this study it is investigated whether induction of LTP in the dorsal horn may be affected by the descending pathways. Extracellular recordings of wide dynamic range (WDR) neurones in the lumbar dorsal horn in intact urethane-anaesthetized Sprague--Dawley rats were performed, and the electrically evoked neuronal responses in these neurones were defined as A-fibre and C-fibre responses according to latencies. Using a short-term cold block of the thoracic spinal cord, which produced a completely reversible increase of the A-fibre and C-fibre responses, the influence of the descending inhibitory system on the induction of LTP by electrical high-frequency conditioning applied to the sciatic nerve was examined. As previously shown the A-fibre responses were almost unchanged following the conditioning. In contrast, the C-fibre responses following the same conditioning were strongly increased. Thus, a clear LTP of the nociceptive transmission in the dorsal horn was observed following electrical high-frequency conditioning. Interestingly, we found that the LTP was more powerful when the effects of the descending pathways were temporarily eliminated during conditioning. It is concluded that induction of LTP by electrical high-frequency conditioning stimulation, which may be part of the wider term central sensitization, is inhibited by descending pathways.     

Spread of excitation across modality borders in spinal dorsal horn of neuropathic rats

Under physiological conditions, nociceptive information is mainly processed in superficial laminae of the spinal dorsal horn, whereas non-nociceptive information is processed in deeper laminae. Neuropathic pain patients often suffer from touch-evoked pain (allodynia), suggesting that modality borders are disrupted in their nervous system. We studied whether excitation evoked in deep dorsal horn neurons either via stimulation of primary afferent Abeta-fibres, by direct electrical stimulation or via glutamate microinjection leads to activation of neurons in the superficial dorsal horn. We used Ca(2+)-imaging in transversal spinal cord slices of neuropathic and control animals to monitor spread of excitation from the deep to the superficial spinal dorsal horn. In neuropathic but not control animals, a spread of excitation occurred from the deep to the superficial dorsal horn. The spread of excitation was synaptically mediated as it was blocked by the AMPA receptor antagonist CNQX. In contrast, block of NMDA receptors was ineffective. In control animals, the violation of modality borders could be reproduced by bath application of GABA(A) and glycine receptor antagonists. Furthermore, we could show that neuropathic animals were more prone to synchronous network activity than control animals. Thus, following peripheral nerve injury, excitation generated in dorsal horn areas which process non-nociceptive information can invade superficial dorsal horn areas which normally receive nociceptive input. This may be a spinal mechanism of touch-evoked pain.     

Mechanical allodynia following contusion injury of the rat spinal cord is associated with loss of GABAergic inhibition in the dorsal horn

The present study investigated whether mechanical allodynia following contusive spinal cord injury (SCI) of the thoracic segments 12 and 13 of the rat was associated with a reduction in gamma-aminobutyric acid (GABA)ergic inhibition adjacent to the site of injury. Five to 7 days following SCI, extracellular recordings were obtained from dorsal horn neurones located 1-2 segments caudal to the injury, in non-allodynic and allodynic halothane anaesthetised rats and from comparable neurones in normal rats. To assess spinal GABAergic inhibition in the three groups of animals, spontaneous and evoked cell firing rates were recorded before, during and after microiontophoretic application of the GABA(A) receptor antagonist bicuculline. Administration of bicuculline to normal animals resulted in significant and reversible increases in the receptive field size, spontaneous firing rate, response to brushing and pinching the skin and afterdischarge activity of dorsal horn neurones, as well as decreasing paired-pulse depression of responses evoked by transcutaneous electrical stimulation. In non-allodynic SCI animals, bicuculline ejection led to significant changes in receptive field size, paired-pulse depression and responses to brush and pinch stimulation that were comparable to those observed in normal animals. By contrast, in allodynic SCI animals, bicuculline ejection had little or no effect on dorsal horn neurone responses to mechanical skin stimuli and paired-pulse depression despite reliably blocking the inhibition of cell firing produced by similarly applied GABA. The demonstration of reduced GABAergic inhibition predominantly in the allodynic SCI rats suggests that such a deficiency contributed to this pain-related behaviour acutely following SCI.     

Alterations in dorsal horn neurones in a rat model of cancer-induced bone pain

Cancer-induced bone pain is a major clinical problem. A rat model based on intra-tibial injection of MRMT-1 mammary tumour cells was used to mimic progressive cancer-induced bone pain. At the time of stable behavioural changes (decreased thresholds to mechanical and cold stimuli) and bone destruction, in vivo electrophysiology was used to characterize natural (mechanical, thermal, and cold) and electrical-evoked responses of superficial and deep dorsal horn neurones in halothane-anaesthetized rats. Receptive field size was significantly enlarged for superficial neurones in the MRMT-1 animals. Superficial cells were characterised as either nociceptive specific (NS) or wide dynamic range (WDR). The ratio of WDR to NS cells was substantially different between sham operated (growth media alone) (26:74%) and MRMT-1 injected rats (47:53%). NS cells showed no significant difference in their neuronal responses in MRMT-1-injected compared to sham rats. However, superficial WDR neurones in MRMT-1-injected rats had significantly increased responses to mechanical, thermal and electrical (A beta-, C fibre-, and post-discharge evoked response) stimuli. Deep WDR neurones showed less pronounced changes to the superficial dorsal horn, however, the response to thermal and electrical stimuli, but not mechanical, were significantly increased in the MRMT-1-injected rats. In conclusion, the spinal cord is significantly hyperexcitable with previously superficial NS cells becoming responsive to wide-dynamic range stimuli possibly driving this plasticity via ascending and descending facilitatory pathways. The alterations in superficial dorsal horn neurones have not been reported in neuropathy or inflammation adding to the evidence for cancer-induced bone pain reflecting a unique pain state.     

Dorsal horn neurons having input from low back structures in rats

The mechanisms of nociception in the low back are poorly understood, partly because systematic recordings from dorsal horn neurons with input from the low back are largely missing. The purpose of this investigation was to (1) identify spinal segments and dorsal horn neurons receiving input from the low back, (2) test the effect of nerve growth factor (NGF) injected into the multifidus muscle (MF) on the neurons’ responsiveness, and (3) study the influence of a chronic MF inflammation on the responses. In rats, microelectrode recordings were made in the segments L2, L3, and L5 to find dorsal horn neurons having input from the low back (LB neurons). In control animals, the proportion of LB neurons in L2 was larger than in L3 and L5. Most LB neurons had a convergent input from several tissues. Injections of NGF into MF increased the proportion of LB neurons significantly. A chronic MF inflammation likewise increased the proportion of LB neurons and the input convergence. The centers of the neurons’ receptive fields (RFs) were consistently located 2–3 segments caudally relative to their recording site. The results show that (1) input convergence from various tissues is common for LB neurons, (2) the input from structures of the low back is processed 2–3 segments cranially relative to the vertebral level of the RFs, and (3) the responsiveness of LB neurons is increased during a pathologic alteration of the MF. The above findings may be relevant for some cases of chronic low back pain in patients.