Gender differences in itch and pain-related sensations provoked by histamine, cowhage and capsaicin.

Cowhage, capsaicin and histamine, all applied via spicules, were used to induce itch and pain-related sensations in 15 male and 15 female subjects. Sensory qualities were assessed by questionnaire; intensities and time courses of the "itching" and "burning" sensation were measured alternately, but continuously on a VAS. In addition, axon reflexes were assessed. Only histamine and capsaicin produced a clear axon reflex flare (histamine > capsaicin, male = female). The 3 types of spicules caused mixed burning and itching sensations with different time courses. In the beginning burning prevailed, in the following minutes histamine induced mostly itching, capsaicin predominantly burning, cowhage both sensory components equally. Female subjects experienced more pain-related sensations (questionnaire), and their ratings leaned more toward burning than those of males. These findings indicate that the mixed itching and burning sensations are differentially processed by both genders. No indications were found for gender specific differential processing in the primary afferents as reflected by nearly identical flare responses.

Axon reflex flare and quantitative sudomotor axon reflex contribute in the diagnosis of small fiber neuropathy.

INTRODUCTION: Objective diagnosis of small fiber impairment is difficult. METHODS: We used the quantitative sudomotor axon reflex test (QSART) and axon-reflex-flare-test in the foot and thigh of 46 patients with peripheral neuropathy to assess C-fiber function in addition to conventional neurography and thermal threshold testing. RESULTS: In all patients, small fiber impairment was suspected because of abnormal warmth detection thresholds (76% of all tested) and/or pain in the feet. A total of 83% had reduced axon-reflex flare areas and 17% lower QSART scores. Patients with pure small fiber neuropathy had higher rates of reduced flare areas (87.5%) and sweating rates (25.5%). There was no difference between patients with and without pain regarding thermotesting and axon-reflex testing. CONCLUSIONS: Both axon-reflex tests are helpful to identify objectively patients with small fiber impairment. Afferent and efferent C-fiber classes can be impaired differently. These tests detect small fiber impairment, but they cannot differentiate between painful and nonpainful neuropathy.

Central projection of pain arising from delayed onset muscle soreness (DOMS) in human subjects.

Delayed onset muscle soreness (DOMS) is a subacute pain state arising 24-48 hours after a bout of unaccustomed eccentric muscle contractions. Functional magnetic resonance imaging (fMRI) was used to examine the patterns of cortical activation arising during DOMS-related pain in the quadriceps muscle of healthy volunteers evoked by either voluntary contraction or physical stimulation. The painful movement or physical stimulation of the DOMS-affected thigh disclosed widespread activation in the primary somatosensory and motor (S1, M1) cortices, stretching far beyond the corresponding areas somatotopically related to contraction or physical stimulation of the thigh; activation also included a large area within the cingulate cortex encompassing posteroanterior regions and the cingulate motor area. Pain-related activations were also found in premotor (M2) areas, bilateral in the insular cortex and the thalamic nuclei. In contrast, movement of a DOMS-affected limb led also to activation in the ipsilateral anterior cerebellum, while DOMS-related pain evoked by physical stimulation devoid of limb movement did not.

Separate peripheral pathways for pruritus in man.

Recent findings suggest that itch produced by intradermal insertion of cowhage spicules in human is histamine independent. Neuronal mechanisms underlying nonhistaminergic itch are poorly understood. To investigate which nerve fibers mediate cowhage induced itch in man, action potentials were recorded from cutaneous C-fibers of the peroneal nerve in healthy volunteers using microneurography. Mechano-responsive and -insensitive C-nociceptors were tested for their responsiveness to cowhage spicules, histamine, and capsaicin. Cowhage spicules induced itching and activated all tested mechano-responsive C-units (24/24), but no mechano-insensitive C-fibers (0/17). Histamine also induced itch, but in contrast to cowhage, it caused lasting activation only in mechano-insensitive units (8/12). In mechano-responsive C-units, histamine caused no or only short and weak responses unrelated to the time course of itching. Capsaicin injections activated four of six mechano-responsive fibers and three of four mechano-insensitive C-fibers. Cowhage and histamine activate distinctly different nonoverlapping populations of C-fibers while inducing similar sensations of itch. We hypothesize that cowhage activates a pathway for itch that originates peripherally from superficial mechano-responsive (polymodal) C-fibers and perhaps other afferent units. It is distinct from the pathway for histamine-mediated pruritus and does not involve the histamine-sensitive mechano-insensitive fibers.

The influence of simultaneous ratings on cortical BOLD effects during painful and non-painful stimulation.

This fMRI study investigates the influence of a rating procedure on BOLD signals in common pain-activated cortical brain regions. Painful and non-painful mechanical impact stimuli were applied to the left hand of healthy volunteers. Subjects performed ratings of the perceived intensity during every second stimulation period by operating a visual analogue scale with the right hand. During every other stimulus period the subjects rested passively. Pain and touch stimuli were found to activate the same cortical areas previously defined as the "cortical pain matrix". General Linear Models were used to calculate contrasts between cortical activations during the "rating" and "non-rating" paradigm. In most brain regions activation following pain and touch was stronger during "rating" compared to "non-rating" conditions. Only the responses in the S1 projection field of the stimulated hand following pain were not influenced by the rating procedure. Furthermore, activations in the right and left posterior insular cortex and in the left superior frontal gyrus showed an opposite pattern, namely a stronger BOLD signal during "non-rating". We concluded: (1) Cortical areas regularly activated by painful stimuli may also be activated by touch stimulation. (2) Enhancement of the BOLD contrast by a rating procedure is probably an effect of closer stimulus evaluation and attention focussing. (3) In contrast to most other cortical regions, the posterior insular cortex, which is crucial for the integration of interoceptive afferent input, shows stronger responses in the absence of ratings, which points to a unique role of this region in the processing of somato-visceral information.

Itch induced by a novel method leads to limbic deactivations a functional MRI study.

Functional brain imaging studies on itch usually use histamine as a stimulus and, in consequence, have to cope with the highly variable time course of this particular itch sensation. In this study, we describe a novel method of histamine application. To provoke itch, a mixture of histamine and codeine was applied through intradermally positioned microdialysis fiber. The itch was terminated by lidocaine application through the same fiber. During one fMRI session, this procedure was repeated four times in four different microdialysis fibers, including one placebo control. Itch ratings of the subjects were correlated with blood-oxygen-level-dependent (BOLD) effects. In a subsequent experiment performed in the same fMRI session, heat pain was provoked in the right forearm with a Peltier thermode. During both experiments, activation clusters were found in brain areas that have been described previously to be frequently activated in response to painful stimuli. This includes prefrontal areas, supplementary motor areas (SMA), premotor cortex, anterior insula, anterior midcingulate cortex, S1, S2, thalamus, basal ganglia, and cerebellum. In general, itch stimulation entailed more activation clusters, in particular on the contralateral brain side. Only on itch, but not on heat pain, negative BOLD signals were found in the subgenual anterior cingulate cortex and the amygdala. The latter results may be associated with the itch induced urge to scratch. Amygdala deactivation may be related to the preparation of scratching by aiming to dissolve the otherwise aversive effects of the noxious scratch stimuli. These negative BOLD effects may also be attributed to the stressful character of itch stimulation.

The motor system shows adaptive changes in complex regional pain syndrome.

The complex regional pain syndrome (CRPS) is a disabling neuropathic pain condition that may develop following injuries of the extremities. In the present study we sought to characterize motor dysfunction in CRPS patients using kinematic analysis and functional imaging investigations on the cerebral representation of finger movements. Firstly, 10 patients and 12 healthy control subjects were investigated in a kinematic analysis assessing possible changes of movement patterns during target reaching and grasping. Compared to controls, CRPS patients particularly showed a significant prolongation of the target phase in this paradigm. The pattern of motor impairment was consistent with a disturbed integration of visual and proprioceptive inputs in the posterior parietal cortex. Secondly, we used functional MRI (fMRI) and investigated cortical activations during tapping movements of the CRPS-affected hand in 12 patients compared to healthy controls (n = 12). During finger tapping of the affected extremity, CRPS patients showed a significant reorganization of central motor circuits, with an increased activation of primary motor and supplementary motor cortices (SMA). Furthermore, the ipsilateral motor cortex showed a markedly increased activation. When the individual amount of motor impairment was introduced as regressor in the fMRI analysis, we were able to demonstrate that activations of the posterior parietal cortices (i.e. areas within the intraparietal sulcus), SMA and primary motor cortex were correlated with the extent of motor dysfunction. In summary, the results of this study suggest that substantial adaptive changes within the central nervous system may contribute to motor symptoms in CRPS.

Advancing our understanding of the mechanisms and mediators underlying pain and inflammation.

The inflammation process underlying rheumatic diseases is a complex cascade of events that involves several mediators, leading to a chronic condition of pain and correlated symptoms that affect the quality of life. As opposed to physiological pain, inflammatory pain arises from tissue damage via the sensitization of pain receptors (nociceptors). Sensitization leads to a lowering of the threshold for activation of nociceptors and an increase in the pain response to a given stimulus, and can occur at both a peripheral and central level. Following peripheral trauma or injury, inflammatory mediators such as phospholipase A(2) are upregulated, inducing the release of arachidonic acid, which is then converted to prostanoids such as prostaglandin E(2) (PGE(2)) via the action of the enzyme cyclo-oxygenase (COX)-2. PGE(2), the most abundant prostanoid found in injured tissue, is believed to be the principal mediator of hypersensitivity and is implicated in the processes of primary and secondary hyperalgesia. At a peripheral level, PGE(2) interacts with other inflammatory mediators to sensitize the peripheral terminals of the primary afferent nociceptors (primary hyperalgesia). In addition to its effect on peripheral pain, at a central level PGE(2) enhances excitatory glutaminergic transmission and downregulates inhibitory glycinergic transmission through the blockade of a glycine receptor subtype (GlyR α-3). These central mechanisms play an important role in the increase of pain sensitivity following inflammation and are responsible for the development of secondary hyperalgesia to regions beyond the injured tissue. Understanding the physiological mechanisms of inflammatory pain as well as preventing peripheral and central prostanoids production are important steps forward when considering the symptomatic treatment of patients with rheumatic conditions.

Mislocalization of tactile stimulation in patients with complex regional pain syndrome.

Complex-Regional-Pain-Syndromes (CRPS) are characterized by sensory,motor and autonomic dysfunctions. Patterns of sensory symptoms suggest changes within the central nervous system (CNS). Recently, we could show substantial reorganization of somatotopic maps within the central nervous system of patients with CRPS using functional imaging techniques (Maihofner et al. Neurology, 2003). These changes were predicted by CRPS pain and mechanical hyperalgesia. In the present study we looked for potential psychophysical correlates of cortical reorganization in CRPS. Sequential pneumatic non-noxious tactile stimulation was performed at digits 1 and 5 in 24 patients with CRPS of the upper extremities. Both the unaffected and affected side were examined. Patients were interviewed for tactile induced sensations. The occurrence of mislocalizations was correlated with a detailed psychophysical examination in which sensory, motor and autonomic symptoms were assessed. Eight patients (30 %) reported tactile mislocalizations, which were felt in the affected hand. In four cases the referred sensations spread into other nerve territories (ulnar/median nerve). Presence of mechanical hyperalgesia significantly predicted the occurrence of mislocalizations. In contrast, in a healthy control group, no mislocalizations were found. Thus, our results further support the concept of pain-induced reorganization in the somatosensory system of CRPS patients.

Functional imaging of allodynia in complex regional pain syndrome.

OBJECTIVE: To investigate cerebral activations underlying touch-evoked pain (dynamic-mechanical allodynia) in patients with neuropathic pain. METHODS: fMRI was used in 12 patients with complex regional pain syndromes (CRPSs). Allodynia was elicited by gently brushing the affected CRPS hand. Elicited pain ratings were recorded online to obtain pain-weighted predictors. Both activations and deactivations of blood oxygenation level-dependent signals were investigated. RESULTS: Nonpainful stimulation on the nonaffected hand activated contralateral primary somatosensory cortex (S1), bilateral insula, and secondary somatosensory cortices (S2). In contrast, allodynia led to widespread cerebral activations, including contralateral S1 and motor cortex (M1), parietal association cortices (PA), bilateral S2, insula, frontal cortices, and both anterior and posterior parts of the cingulate cortex (aACC and pACC). Deactivations were detected in the visual, vestibular, and temporal cortices. When rating-weighted predictors were implemented, only few activations remained (S1/PA cortex, bilateral S2/insular cortices, pACC). CONCLUSIONS: Allodynic stimulation recruits a complex cortical network. Activations include not only nociceptive but also motor and cognitive processing. Using a covariance approach (i.e., implementation of rating-weighted predictors) facilitates the detection of a neuronal matrix involved in the encoding of allodynia. The pattern of cortical deactivation during allodynia may hint at a shift of activation from tonically active sensory systems, like visual and vestibular cortices, into somatosensory-related brain areas.

Differential coding of hyperalgesia in the human brain: a functional MRI study.

Neuropathic pain can be both ongoing or stimulus-induced. Stimulus-induced pain, also known as hyperalgesia, can be differentiated into primary and secondary hyperalgesia. The former results from sensitization of peripheral nociceptive structures, the latter involves sensitization processes within the central nervous system (CNS). Hypersensitivity towards heat stimuli, i.e. thermal hyperalgesia, is a key feature of primary hyperalgesia, whereas secondary hyperalgesia is characterized by hypersensitivity towards mechanical (e.g. pin-prick) stimulation. Using functional magnetic resonance imaging (fMRI), we investigated if brain activation patterns associated with primary and secondary hyperalgesia might differ. Thermal and pin-prick hyperalgesia were induced on the left forearm in 12 healthy subjects by topical capsaicin (2.5%, 30 min) application. Equal pain intensities of both hyperalgesia types were applied during fMRI experiments, based on previous quantitative sensory testing. Simultaneously, subjects had to rate the unpleasantness of stimulus-related pain. Pin-prick hyperalgesia (i.e. subtraction of brain activations during pin-prick stimulation before and after capsaicin exposure) led to activations of primary and secondary somatosensory cortices (S1 and S2), associative-somatosensory cortices, insula and superior and inferior frontal cortices (SFC, IFC). Brain areas activated during thermal hyperalgesia (i.e. subtraction of brain activations during thermal stimulation before and after capsaicin exposure) were S1 and S2, insula, associative-somatosensory cortices, cingulate cortex (GC), SFC, middle frontal cortex (MFC) and IFC. When compared to pin-prick hyperalgesia, thermal hyperalgesia led to an increased activation of bilateral anterior insular cortices, MFC, GC (Brodmann area 24' and 32') and contralateral SFC and IFC, despite equal pain intensities. Interestingly, stronger activations of GC, contralateral MFC and anterior insula significantly correlated to higher ratings of the stimulus-related unpleasantness. We conclude that thermal and mechanical hyperalgesia produce substantially different brain activation patterns. This is linked to different psychophysical properties.

Mechanical hyperalgesia in complex regional pain syndrome: a role for TNF-alpha?

Plasma concentrations of soluble tumor necrosis factor alpha (TNF-alpha) receptor type I (sTNF-RI) were assessed in two complex regional pain syndrome (CRPS) patient groups (n = 30 and n = 16) and healthy controls (n = 25). Patients with CRPS and mechanical hyperalgesia had higher levels of sTNF-RI (1,661.8 +/- 146.8 pg/mL) compared with those with CRPS with identical clinical appearance but without hyperalgesia (1,155.9 +/- 56.3 pg/mL) and controls (1,239.5 +/- 42.9 pg/mL). This study suggests involvement of TNF-alpha in mechanical hyperalgesia of CRPS.

Brain processing during mechanical hyperalgesia in complex regional pain syndrome: a functional MRI study.

Complex Regional Pain Syndromes (CRPS) are characterized by a triad of sensory, motor and autonomic dysfunctions of still unknown origin. Pain and mechanical hyperalgesia are hallmarks of CRPS. There are several lines of evidence that central nervous system (CNS) changes are crucial for the development and maintenance of mechanical hyperalgesia. However, little is known about the cortical structures associated with the processing of hyperalgesia in pain patients. This study describes the use of functional magnetic resonance imaging (fMRI) to delineate brain activations during pin-prick hyperalgesia in CRPS. Twelve patients, in whom previous quantitative sensory testing revealed the presence of hyperalgesia to punctuate mechanical stimuli (i.e. pin-prick hyperalgesia), were included in the study. Pin-prick-hyperalgesia was elicited by von-Frey filaments at the affected limb. For control, the identical stimulation was performed on the unaffected limb. fMRI was used to explore the corresponding cortical activations. Mechanical stimulation at the unaffected limb was non-painful and mainly led to an activation of the contralateral primary somatosensory cortex (S1), insula and bilateral secondary somatosensory cortices (S2). The stimulation of the affected limb was painful (mechanical hyperalgesia) and led to a significantly increased activation of the S1 cortex (contralateral), S2 (bilateral), insula (bilateral), associative-somatosensory cortices (contralateral), frontal cortices and parts of the anterior cingulate cortex. The results of our study indicate a complex cortical network activated during pin-prick hyperalgesia in CRPS. The underlying neuronal matrix comprises areas not only involved in nociceptive, but also in cognitive and motor processing.

Cortical reorganization during recovery from complex regional pain syndrome.

OBJECTIVE: To characterize reorganization of the primary somatosensory cortex (S1) during healing process in complex regional pain syndrome (CRPS). BACKGROUND: Recently, the authors showed extensive reorganization of the S1 cortex contralateral to the CRPS affected side. Predictors for these plastic changes were CRPS pain and the extent of mechanical hyperalgesia. It is unclear how these S1 changes develop following successful therapy. METHODS: The authors used magnetic source imaging to explore changes in the cortical representation of digits (D) 1 and 5 in relation to the lower lip on the unaffected and affected CRPS side in 10 patients during a year or more of follow-up. RESULTS: Cortical reorganization reversed coincident with clinical improvement. A reduction of CRPS pain correlated with recovery from cortical reorganization. CONCLUSIONS: Changes of the somatotopic map within the S1 cortex may depend on CRPS pain and its recovery.

Neural activation during experimental allodynia: a functional magnetic resonance imaging study.

Abstract Pain induced by gentle stroking, i.e. dynamic-mechanical allodynia, is one of the most distressing symptoms of neuropathic pain. The underlying neuronal pathways are still a matter of debate. Here, we investigated the cortical activations associated with dynamic-mechanical allodynia in an experimental human pain model by functional magnetic resonance imaging (fMRI). Large and stable areas of brush-evoked allodynia were induced in 11 healthy subjects by topical capsaicin (2.5%, 30 min) application following local heating (45 degrees C for 5 min), thus combining both physical and chemical sensitization. During the fMRI experiments, allodynia was rekindled by local heat application (40 degrees C for 5 min) immediately before the allodynia testing. Brushing the untreated forearm (control condition) led to activations of the contralateral primary somatosensory cortex (S1), contralateral parietal association cortex (PA), bilateral secondary somatosensory cortices (S2) and insula (contralateral). Brushing the allodynic skin was painful and the cortical responses were partially overlapping with those induced by the nonpainful brush stimulation. Additionally, the contralateral inferior frontal cortex (IFC) and the ipsilateral insula were activated. Direct comparison between nonpainful brushing and brush-evoked allodynia revealed significant increases in blood oxygenation level-dependent (BOLD) signals in contralateral S1, PA, IFC and bilateral S2/insula during allodynia. This study highlights the importance of a cortical network comprising S1, PA, S2/insula and IFC in the processing of dynamic-mechanical allodynia in the human brain. Furthermore, it demonstrates that the combined heat/capsaicin model can be used successfully in the exploration of brain processes underlying stimulus-evoked pain.

Patterns of cortical reorganization in complex regional pain syndrome.

OBJECTIVE: To use magnetoencephalography to assess possible cortical reorganization in the primary somatosensory cortex (S1) of patients with complex regional pain syndrome (CRPS). BACKGROUND: Patterns of pain and sensory symptoms in CRPS may indicate plastic changes of the CNS. METHODS: Magnetic source imaging was used to explore changes in the cortical representation of digits (D) 1 and 5 in relation to the lower lip on the unaffected and affected CRPS side in 12 patients. RESULTS: The authors found a significant shrinkage of the extension of the cortical hand representation for the CRPS affected side. The center of the hand was shifted toward the cortical representation of the lip. The cortical reorganization correlated with the amount of CRPS pain (r = 0.792), as measured by the McGill questionnaire, and the extent of mechanical hyperalgesia (r = 0.860). Using multiple regression analysis, the best predictor for the plastic changes was found to be mechanical hyperalgesia. Additionally, S1 sources following tactile stimulation were significantly increased on the CRPS side compared to the unaffected limb. CONCLUSIONS: This study showed reorganization of the S1 cortex contralateral to the CRPS affected side. The reorganization appeared to be linked to complaints of neuropathic pain.