Referred muscle pain: Clinical and pathophysiologic aspects

Referred pain, that is, pain perceived in an area other than that in which the noxious stimulation takes place, is very frequent in the clinical setting. There are various forms of referred muscle pain from viscera and from somatic structures. Examples of the latter are referred pain from one muscle to another muscle (as in myofascial pain syndromes) and referred pain from joints (as in osteoarthritis of the knee). Whatever the origin of the symptom, a condition of secondary hyperalgesia very often takes place in the referred zones, together with trophic tissue changes. Referred muscle pain from viscera without hyperalgesia is explained on the basis of the convergence of visceral and somatic afferent fibers on the same central neurons. Referred muscle pain from viscera with hyperalgesia is not completely understood; it is hypothesized that it is due to both central (sensitization process) and peripheral (intervention of reflex arcs) mechanisms. Referred muscle pain from other muscles or from joints is not easily explained by the mechanism of “central convergence” in its original form, because in dorsal horn neurons there is little convergence from deep tissues. It has been proposed that convergent connections from deep tissues to dorsal horn neurons are not present from the beginning but are opened by nociceptive input from skeletal muscle, and referral to myotomes outside the lesion is due to a spread of central sensitization to adjacent spinal segments.     

Secondary hyperalgesia and presynaptic inhibition: an update.

One of the most prominent features of secondary hyperalgesia is touch-evoked pain, i.e., pain evoked by dynamic tactile stimuli applied to areas adjacent or remote from the originating injury. It is generally accepted that the neurobiological mechanism of this sensory alteration involves the central nervous system (CNS) so that incoming impulses in low-threshold mechanoreceptors from the area of secondary hyperalgesia can evoke painful sensations instead of touch. Some years ago we proposed a mechanistic model for this form of pain based on presynaptic interactions in the spinal dorsal horn between the terminals of low-threshold mechanoreceptors and of nociceptors. Here we review the evidence gathered in support of this model in the intervening years with special reference to experimental studies of antidromic activity (Dorsal Root Reflexes--DRRs) in nociceptive afferents and on the acquisition of low-threshold inputs by nociceptor-specific neurons in the spinal dorsal horn. We also discuss and identify potential molecular mechanisms that may underlie the presynaptic interaction model and therefore that could be responsible for the development of secondary hyperalgesia.     

Pannexin 1: A novel participant in neuropathic pain signaling in the rat spinal cord

Pannexin 1 (panx1) is a large-pore membrane channel expressed in many tissues of mammals, including neurons and glial cells. Panx1 channels are highly permeable to calcium and adenosine triphosphatase (ATP); on the other hand, they can be opened by ATP and glutamate, two crucial molecules for acute and chronic pain signaling in the spinal cord dorsal horn, thus suggesting that panx1 could be a key component for the generation of central sensitization during persistent pain. In this study, we examined the effect of three panx1 blockers, namely, 10panx peptide, carbenoxolone, and probenecid, on C-reflex wind-up activity and mechanical nociceptive behavior in a spared nerve injury neuropathic rat model involving sural nerve transection. In addition, the expression of panx1 protein in the dorsal horn of the ipsilateral lumbar spinal cord was measured in sural nerve–transected and sham-operated control rats. Sural nerve transection resulted in a lower threshold for C-reflex activation by electric stimulation of the injured hindpaw, together with persistent mechanical hypersensitivity to pressure stimuli applied to the paw. Intrathecal administration of the panx1 blockers significantly depressed the spinal C-reflex wind-up activity in both neuropathic and sham control rats, and decreased mechanical hyperalgesia in neuropathic rats without affecting the nociceptive threshold in sham animals. Western blotting showed that panx1 was similarly expressed in the dorsal horn of lumbar spinal cord from neuropathic and sham rats. The present results constitute the first evidence that panx1 channels play a significant role in the mechanisms underlying central sensitization in neuropathic pain.     

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.     

Neurobiologische Mechanismen der Übertragung von Muskelschmerz

In contrast to pain from the skin, muscle pain is often referred to regions remote from the lesion. For instance, trigger points in neck muscles can elicit pain in the head. The convergence-projection theory of Ruch is still the central concept for the explanation of pain referral. The basis of the theory is that a dorsal horn neuron has convergent input from two different body regions. Because of the convergence, thalamic neurons cannot localize the origin of the dorsal horn activation. Basically, the referral of pain is a mislocalization of pain. Some aspects of muscle pain referral in patients cannot be explained by the convergence-projection theory. Therefore, the present paper presents another mechanism, which consists in acute changes in dorsal horn synaptic connections following nociceptive input from muscle. Results from animal experiments indicate that dorsal horn neurons possess ineffective synaptic connections with the body periphery, which become effective under the influence of a painful stimulus and lead to a mislocalization of pain. The neuropeptide substance P is probably involved in the changes in functional organization that occur in the dorsal horn during muscle pain and its referral.     

Activation of cyclin-dependent kinase 5 (Cdk5) in primary sensory and dorsal horn neurons by peripheral inflammation contributes to heat hyperalgesia

Cyclin-dependent kinase 5 (Cdk5) is a unique member of the CDK family. It is predominantly expressed in postmitotic neurons and has been implicated in neuronal plasticity. The present study showed that Cdk5 and p35 were expressed in primary sensory and dorsal horn neurons, while p25, an N-terminal truncated derivative of p35, could only be detected in the dorsal horn neurons. Importantly, in the case of control rats, the p35 protein level was much higher in small- and medium-diameter DRG neurons than it was in large neurons. Following CFA injection, Cdk5 activity was upregulated in both primary sensory and dorsal horn neurons. Cdk5 activation in DRG neurons required p35, whereas p25 was required in the dorsal horn. Intrathecal pretreatment with Roscovitine, a specific inhibitor of Cdk5 activity, and intrathecal delivery of the DN-Cdk5(N144) gene both alleviated CFA-induced heat hyperalgesia but not mechanical allodynia. In contrast, overexpression of Cdk5, p35 or p25 in primary sensory and dorsal horn neurons significantly enhanced heat hyperalgesia. We conclude that Cdk5/p35 and Cdk5/p25 complexes in primary sensory and dorsal horn neurons may potentially be involved in nociceptive transmission after inflammation and may be employed in synaptic plasticity underlying pain hypersensitization.     

Peripheral and central contributions to hyperalgesia in irritable bowel syndrome.

Irritable bowel syndrome (IBS) is a common gastrointestinal disorder seen by gastroenterologists. We discuss some recent evidence for potential neural mechanisms that could contribute to somatic and visceral hyperalgesia in IBS patients. The combination of research studies of human IBS patients and studies of rats with delayed rectal hypersensitivity after recovery from experimentally induced neonatal colitis strongly suggests a mechanism wherein both primary visceral hyperalgesia and secondary widespread cutaneous hyperalgesia are dynamically maintained by tonic impulse input from the noninflamed colon and/or rectum. The secondary hyperalgesia is likely to be at least partly related to sensitization of spinal cord dorsal horn neurons and in this respect might be similar to other persistent pain conditions such as fibromyalgia and complex regional pain syndrome. PERSPECTIVE: Pain in irritable bowel syndrome is likely to be at least partly maintained by peripheral impulse input from the colon/rectum and central sensitization, yet it is also highly modifiable by psychological factors such as nocebo and placebo effects. A synergistic interaction might occur between psychological factors and abnormal afferent processing.     

Tonic and phasic descending dopaminergic controls of nociceptive transmission in the medullary dorsal horn

The transfer of nociceptive information at the level of dorsal horn is subject to extensive processing by both local segmental and supraspinal mechanisms, including descending dopaminergic controls, originating from the hypothalamic A11 nucleus. The inhibitory role of dopamine on evoked pain via activation of D2-like receptors at the level of the dorsal horn is well established. Here, by use of behavioral, electrophysiological, and anatomical techniques, we examined within the trigeminal sensory complex, first, whether descending dopaminergic controls also modulate pain behavior after an inflammatory insult, and second, under which physiological conditions these descending dopaminergic controls are actually recruited. We show that D2 receptors are mostly located within superficial medullary dorsal horn where trigeminal nociceptive fibers abut. Activating these D2-like receptors inhibits, whereas blocking them enhances, both formalin- and capsaicin-evoked pain behavior and C-fiber-evoked action potential firing of trigeminal wide dynamic range (WDR) neurons. Moreover, windup and diffuse noxious inhibitory controls (DNIC), 2 dynamic properties of C-fiber-evoked firing of WDR neurons, are inhibited by activating and blocking, respectively, these D2-like receptors. Altogether, our results are consistent with a tonic inhibition of the trigeminal nociceptive input by descending dopaminergic controls via activation of D2-like receptors at the level of superficial medullary dorsal horn. Such dopamine-dependent tonic inhibition of nociceptive information can be dynamically modulated by pain. This suggests that dysregulation of descending dopaminergic controls should translate in patients into diffuse, cephalic, and extracephalic pain symptoms—spontaneous pain, decreased pain thresholds, deficient DNIC, or some combination of these.     

The gap junction blocker carbenoxolone attenuates nociceptive behavior and medullary dorsal horn central sensitization induced by partial infraorbital nerve transection in rats

Glial cells are being increasingly implicated in mechanisms underlying pathological pain, and recent studies suggest glial gap junctions involving astrocytes may contribute. The aim of this study was to examine the effect of a gap junction blocker, carbenoxolone (CBX), on medullary dorsal horn (MDH) nociceptive neuronal properties and facial mechanical nociceptive behavior in a rat trigeminal neuropathic pain model involving partial transection of the infraorbital nerve (p-IONX). p-IONX produced facial mechanical hypersensitivity reflected in significantly reduced head withdrawal thresholds that lasted for more than 3 weeks. p-IONX also produced central sensitization in MDH nociceptive neurons that was reflected in significantly increased receptive field size, reduction of mechanical activation threshold, and increases in noxious stimulation-evoked responses. Intrathecal CBX treatment significantly attenuated the p-IONX–induced mechanical hypersensitivity and the MDH central sensitization parameters, compared to intrathecal vehicle treatment. These results provide the first documentation that gap junctions may be critically involved in orofacial neuropathic pain mechanisms.     

NSAR bei postoperativen Schmerzen?

Postoperative pain arises largely from distension and sectioning of nerve fibers, which generate a short-lasting but enormous afferent impulse barrage. This causes a long-lasting enlargement of receptive fields and an increase in excitability of dorsal horn neurons sending their axons up to the brain. The central process set up by extreme afferent excitation can be prevented by local anesthetics that will block afferent impulse conduction, or by premedication with opioid analgesics that will reduce the massive synaptic activation of dorsal horn neurons. Several mechanisms cause hyperactivity in these nociceptive neurons, one being an abundant formation of prostaglandins. Prostaglandins in the spinal cord facilitate the synaptic transmission from nociceptive afferents. Nonsteroidal anti-inflammatory drugs (NSAIDs) produce relief from postoperative pain by blocking the formation of prostaglandins in the spinal cord, thus abolishing the facilitatory effect of these compounds.     

Epileptiform activity in rat spinal dorsal horn in vitro has common features with neuropathic pain

Neuropathic pain and epileptic seizures bear several similarities, among them is the response to anticonvulsant drugs. It has therefore been hypothesized that epileptiform activity of nociceptive spinal dorsal horn neurons may contribute to paroxysmal forms of neuropathic pain. We used patch-clamp and field potential recordings from young rat spinal cord slices to test if nociceptive dorsal horn structures are indeed able to sustain epileptiform activity. Application of the convulsant 4-aminopyridine (100 microM) evoked epileptiform activity that was most pronounced in superficial dorsal horn and involved nociceptive lamina I neurons with a projection to the brain. The epileptiform activity was dependent on fast excitatory and inhibitory synaptic transmission through ionotropic glutamate receptors and GABA(A) receptors. During epileptiform activity, previously silent polysynaptic pathways from primary afferent C-fibers to superficial dorsal horn neurons were opened. Stimulation of primary afferents at Adelta- and C-fiber intensity interfered with the epileptiform rhythm, suggesting that both affect the same dorsal horn structures. Similar to neuropathic pain, spinal dorsal horn epileptiform activity was much less reduced by classical analgesics than by anticonvulsant agents.     

Körpereigene Schmerzabwehr: Neue Konzepte aus der funktionellen Neuroanatomie,Neurophysiologie, Neurobiologie und Chaosforschung

Modern concepts of pain therapy involve neuronal mechanisms of endogenous analgesia. Recent animal experiments have provided new insights into the anatomy, physiology and neurobiology of endogenous antinociception. We have shown that antinociception can be maximally activated by disinhibition-and not by direct electrical or chemical excitation-in the midbrain periaqueductal grey matter. This disinhibition is a likely mechanism of opioid analgesia. 'Purely analgesic' stimulation produces a very distinct pattern of activated neurons within the periaqueductal grey matter and other areas of the brain stem, as revealed by the expression of the nuclear c-FOS protein as a cellular marker of activated neurons. In addition to the classic segmental and supraspinal, descending inhibition, a third principle of endogenous antinociception exists: the propriospinal, intersegmental inhibition of nociceptive spinal dorsal horn neurons. Propriospinal antinociception partly mediates the descending inhibition from the brain stem and can be activated by conditioning heterosegmental noxious stimuli, thus possibly contributing to analgesia by counterirritation. In addition to the fast synaptic transmission mediated by classic neurotransmitters, the extrasynaptic transmission of chemical signals such as neuropeptides may play an important role for long-term effects following intense noxious stimulation. The controlled superfusion of the dorsal cord with neuropeptides produces a similar distribution in the spinal cord to that of endogenously released neuropeptide. We have shown that extrasynaptic neuropeptides such as substance P may increase the excitability of nociceptive spinal dorsal horn neurons and may induce the expression of 'immediate-early genes' in dorsal horn neurons in vivo. Changes in gene expression following extrasynpatic spread of neuropeptides in the spinal cord may be involved in chronic pain syndromes after massive peripheral trauma. This hypothesis has led to the concept of pre-emptive analgesia. The available evidence suggests that the known systems of endogenous antinociception do not affect the endogenous release of neuropeptides in the spinal cord. All previous concepts of endogenous antinociception are based on changes in dischargerates of nociceptive neurons. Background activity in the absence of noxious stimulation was considered to be purely stochastic 'noise'. By the use of modern tools for the analysis of nonlinear dynamics in point processes we have, however, shown that background activity of most nociceptive spinal dorsal horn neurons is highly deterministic with a low degree of freedom. The high order in the discharges of these neurons is maintained, at least in part, by tonically active descending systems. Thus, the spinal shock syndrome seen in some species after acute spinalisation may result from the loss of order in spinal neuronal discharges normally provided by the brain. The use of modern methods in studies of the functional neuroanatomy, neurophysiology and neurobiology of endogenous antinociception may help in the achievement of better application of results from basic sciences to clinically relevant pain problems.     

Neurobiologie viszeraler Schmerzen

Visceral pain is diffusely localized, referred into other tissues, frequently not correlated with visceral traumata, preferentially accompanied by autonomic and somatomotor reflexes, and associated with strong negative affective feelings. It belongs together with the somatic pain sensations and non-painful body sensations to the interoception of the body. (1) Visceral pain is correlated with the excitation of spinal (thoracolumbar, sacral) visceral afferents and (with a few exceptions) not with the excitation of vagal afferents. Spinal visceral afferents are polymodal and activated by adequate mechanical and chemical stimuli. All groups of spinal visceral afferents can be sensitized (e.g., by inflammation). Silent mechanoinsensitive spinal visceral afferents are recruited by inflammation. (2) Spinal visceral afferent neurons project into the laminae I, II (outer part IIo) and V of the spinal dorsal horn over several segments, medio-lateral over the whole width of the dorsal horn and contralateral. Their activity is synaptically transmitted in laminae I, IIo and deeper laminae to viscero-somatic convergent neurons that receive additionally afferent synaptic (mostly nociceptive) input from the skin and from deep somatic tissues of the corresponding dermatomes, myotomes and sclerotomes. (3) The second-order neurons consist of excitatory and inhibitory interneurons (about 90?% of all dorsal horn neurons) and tract neurons activated monosynaptically in lamina I by visceral afferent neurons and di- or polysynaptically in deeper laminae. (4) The sensitization of viscero-somatic convergent neurons (central sensitization) is dependent on the sensitization of spinal visceral afferent neurons, local spinal excitatory and inhibitory interneurons and supraspinal endogenous control systems. The mechanisms of this central sensitization have been little explored. (5) Viscero-somatic tract neurons project through the contralateral ventrolateral tract and presumably other tracts to the lower and upper brain stem, the hypothalamus and via the thalamus to various cortical areas. (6) Visceral pain is presumably (together with other visceral sensations and nociceptive as well as non-nociceptive somatic body sensations) primarily represented in the posterior dorsal insular cortex (primary interoceptive cortex). This cortex receives in primates its spinal synaptic inputs mainly from lamina I tract neurons via the ventromedial posterior nucleus of the thalamus. (7) The transmission of activity from visceral afferents to second-order neurons in spinal cord is modulated in an excitatory and inhibitory way by endogenous anti- and pronociceptive control systems in the lower and upper brain stem. These control systems are under cortical control. (8) Visceral pain is referred to deep somatic tissues, to the skin and to other visceral organs. This referred pain consists of spontaneous pain and mechanical hyperalgesia. The mechanisms underlying referred pain and the accompanying tissue changes have been little explored.     

Differential influence of naloxone on the responses of nociceptive neurons in the superficial versus the deeper dorsal horn of the medulla in the rat.

Naloxone (200 micrograms/kg, i.v.) reduced the noxious thermal stimuli-evoked responses of 16/25 nociceptive neurons in the superficial laminae whereas it enhanced the responses of 6/10 nociceptive neurons in the deeper dorsal horn. However, a different picture emerged when selectivity of neuronal responsivity (nocireceptive or multireceptive) was considered. In the superficial dorsal horn, naloxone reduced the responses of the majority of (15/18) selectively nocireceptive neurons. The reduction in responses became apparent within 60 sec following naloxone administration and returned to control level within 48 min. In contrast, the responses of the majority of multireceptive neurons in the superficial (6/7), or the deeper (6/10) dorsal horn, were enhanced. The excitatory action in the superficial dorsal horn persisted for only 6-15 min, whereas it persisted for 40-70 min in the deeper dorsal horn. The firing of the majority of cold-receptive neurons (6/8) in the superficial dorsal horn was not altered. These effects were stereoselective since (+)-naloxone, the inactive isomer of naloxone, did not affect the responses of 14/16 nociceptive neurons. It is concluded that naloxone differentially, and selectively, affects the firing of nociceptive neurons in the superficial versus the deeper dorsal horn, and the firing of selectively nocireceptive versus multireceptive neurons. The relevance of these findings to the behavioral effects of naloxone, hyperalgesia and analgesia, is discussed.     

Pathophysiologic mechanisms of neuropathic pain

New animal models of peripheral nerve injury have facilitated our understanding of neuropathic pain mechanisms. Nerve injury increases expression and redistribution of newly discovered sodium channels from sensory neuron somata to the injury site; accumulation at both loci contributes to spontaneous ectopic discharge. Large myelinated neurons begin to express nociceptive substances, and their central terminals sprout into nociceptive regions of the dorsal horn. Descending facilitation from the brain stem to the dorsal horn also increases in the setting of nerve injury. These and other mechanisms drive various pathologic states of central sensitization associated with distinct clinical symptoms, such as touch-evoked pain.     

Neuropathische Schmerzsyndrome und Neuroplastizität in der funktionellen Bildgebung

Neuropathic pain syndromes are characterised by the occurrence of spontaneous ongoing and stimulus-induced pain. Stimulus-induced pain (hyperalgesia and allodynia) may result from sensitisation processes in the peripheral (primary hyperalgesia) or central (secondary hyperalgesia) nervous system. The underlying pathophysiological mechanisms at the nociceptor itself and at spinal synapses have become better understood. However, the cerebral processing of hyperalgesia and allodynia is still controversially discussed. In recent years, neuroimaging methods (functional magnetic resonance imaging, fMRI; magnetoencephalography, MEG; positron emission tomography, PET) have provided new insights into the aberrant cerebral processing of neuropathic pain. The present paper reviews different cerebral mechanisms contributing to chronicity processes in neuropathic pain syndromes. These mechanisms include reorganisation of cortical somatotopic maps in sensory or motor areas (highly relevant for phantom limb pain and CRPS), increased activity in primary nociceptive areas, recruitment of new cortical areas usually not activated by nociceptive stimuli and aberrant activity in brain areas normally involved in descending inhibitory pain networks. Moreover, there is evidence from PET studies for changes of excitatory and inhibitory transmitter systems. Finally, advanced methods of structural brain imaging (voxel-based morphometry, VBM) show significant structural changes suggesting that chronic pain syndromes may be associated with neurodegeneration.     

Selective loss of spinal GABAergic or glycinergic neurons is not necessary for development of thermal hyperalgesia in the chronic constriction injury model of neuropathic pain

GABA and glycine are inhibitory neurotransmitters used by many neurons in the spinal dorsal horn, and intrathecal administration of GABA(A) and glycine receptor antagonists produces behavioural signs of allodynia, suggesting that these transmitters have an important role in spinal pain mechanisms. Several studies have described a substantial loss of GABA-immunoreactive neurons from the dorsal horn in nerve injury models, and it has been suggested that this may be associated with a loss of inhibition, which contributes to the behavioural signs of neuropathic pain. We have carried out a quantitative stereological analysis of the proportions of neurons in laminae I, II and III of the rat dorsal horn that show GABA- and/or glycine-immunoreactivity 2 weeks after nerve ligation in the chronic constriction injury (CCI) model, as well as in sham-operated and nai;ve animals. At this time, rats that had undergone CCI showed a significant reduction in the latency of withdrawal of the ipsilateral hindpaw to a radiant heat stimulus, suggesting that thermal hyperalgesia had developed. However, we did not observe any change in the proportion of neurons in laminae I-III of the ipsilateral dorsal horn that showed GABA- or glycine-immunoreactivity compared to the contralateral side in these animals, and these proportions did not differ significantly from those seen in sham-operated or nai;ve animals. In addition, we did not see any evidence for alterations of GABA- or glycine-immunostaining in the neuropil of laminae I-III in the animals that had undergone CCI. Our results suggest that significant loss of GABAergic or glycinergic neurons is not necessary for the development of thermal hyperalgesia in the CCI model of neuropathic pain.     

Distinct roles of group III metabotropic glutamate receptors in control of nociception and dorsal horn neurons in normal and nerve-injured Rats

Increased glutamatergic input to spinal dorsal horn neurons constitutes an important mechanism for neuropathic pain. However, the role of group III metabotropic glutamate receptors (mGluRs) in regulation of nociception and dorsal horn neurons in normal and neuropathic pain conditions is not fully known. In this study, we determined the effect of the group III mGluR specific agonist L(+)-2-amino-4-phosphonobutyric acid (L-AP4) on nociception and dorsal horn projection neurons in normal rats and a rat model of neuropathic pain. Tactile allodynia was induced by ligation of L5/L6 left spinal nerves in rats. Allodynia was determined by von Frey filaments in nerve-injured rats. The nociceptive threshold was tested using a radiant heat and a Randall-Selitto pressure device in normal rats. Single-unit activity of ascending dorsal horn neurons was recorded from the lumbar spinal cord in anesthetized rats. An intrathecal (5-30 microg) L-AP4 dose-dependently attenuated allodynia in nerve-injured rats but had no antinociceptive effect in normal rats. Topical spinal application of 5 to 50 microM L-AP4 also significantly inhibited the evoked responses of ascending dorsal horn neurons in nerve-ligated but not normal rats. Furthermore, blockade of spinal group III mGluRs significantly decreased the withdrawal threshold and increased the evoked responses of dorsal horn neurons in normal but not nerve-injured rats. These data suggest that group III mGluRs play distinct roles in regulation of nociception and dorsal horn neurons in normal and neuropathic pain states. Activation of spinal group III mGluRs suppresses allodynia and inhibits the hypersensitivity of dorsal horn projection neurons associated with neuropathic pain.     

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.     

Paraventricular oxytocinergic hypothalamic prevention or interruption of long-term potentiation in dorsal horn nociceptive neurons: Electrophysiological and behavioral evidence

Spinal long-term potentiation (LTP) elicited by noxious stimulation enhances the responsiveness of dorsal horn nociceptive neurons to their normal input, and may represent a key mechanism of central sensitization by which acute pain could turn into a chronic pain state. This study investigated the electrophysiological and behavioral consequences of the interactions between LTP and descending oxytocinergic antinociceptive mechanisms mediated by the hypothalamic paraventricular nucleus (PVN). PVN stimulation or intrathecal oxytocin (OT) reduced or prevented the ability of spinal LTP to facilitate selectively nociceptive-evoked responses of spinal wide dynamic range (WDR) neurons recorded in anesthetized rats. In a behavioral model developed to study the effects of spinal LTP on mechanical withdrawal thresholds in freely moving rats, the long-lasting LTP-mediated mechanical hyperalgesia was transiently interrupted or prevented by either PVN stimulation or intrathecal OT. LTP mediates long-lasting pain hypersensitivity that is strongly modulated by endogenous hypothalamic oxytocinergic descending controls.