Specific thalamic nuclei function as novel 'nociceptive discriminators' in the endogenous control of nociception in rats.

Recently, we hypothesized that supraspinal structures may have important functions in discriminating between noxious mechanically and heat mediated nociception through distinct functions: facilitation and inhibition. In this study, conducted in conscious rats, we explored the role of different thalamic nuclei: the mediodorsal (MD) nucleus, the central medial (CM) nucleus, the submedius (SM) nucleus, the ventralmedial (VM) nucleus and the ventral posterolateral (VPL) nucleus, in the descending control of secondary and contralateral mechanical hyperalgesia and heat hypoalgesia occurring in intramuscularly hypertonic (HT, 5.8%) saline-induced muscle nociception. We found that the MD nuclei participated in the descending facilitation of mechanical hyperalgesia, and that the VM nuclei were specifically involved in the descending inhibition of heat hypoalgesia. Neither descending facilitation nor descending inhibition was affected after electrolytic lesion of the thalamic CM, SM, and VPL nuclei. This descending facilitatory and inhibitory modulation of nociception was strengthened by glutamate, and weakened by GABA, microinjected into the thalamic MD and VM nuclei. It is suggested that (1) thalamic MD nucleus and VM nucleus form two distinct endogenous systems in the control of noxious mechanically and heat evoked responses, and (2) the strengthening of descending inhibition and the weakening of descending facilitation by means of up regulation and down regulation of appropriate receptor expression in the VM and MD nuclei may provide a new strategic policy in treating pathological pain.

Stability of long term facilitation and expression of zif268 and Arc in the spinal cord dorsal horn is modulated by conditioning stimulation within the physiological frequency range of primary afferent fibers.

Long term facilitation (LTF) of C-fiber-evoked firing of wide dynamic range neurons in the spinal dorsal horn in response to conditioning stimulation (CS) of afferent fibers is a widely studied cellular model of spinal nociceptive sensitization. Although 100 Hz CS of primary afferent fibers is commonly used to induce spinal cord LTF, this frequency exceeds the physiological firing range. Here, we examined the effects of electrical stimulation of the sciatic nerve within the physiological frequency range on the magnitude and stability of the C-fiber-evoked responses of wide dynamic range neurons and the expression of immediate early genes (c-fos, zif268, and Arc) in anesthetized rats. Stimulation frequencies of 3, 30 and 100 Hz all induced facilitation of similar magnitude as recorded at 1 h post-CS. Strikingly, however, 3 Hz-induced potentiation of the C-fiber responses was decremental, whereas both 30 and 100 Hz stimulation resulted in stable, non-decremental facilitation over 3 h of recording. The number of dorsal horn neurons expressing c-fos, but not zif268 or Arc, was significantly elevated after 3 Hz CS and increased proportionally with stimulation rate. In contrast, a stable LTF of C-fiber responses was obtained at 30 and 100 Hz CS, and at these frequencies there was a sharp increase in zif268 expression and appearance of Arc-positive neurons. The results show that response facilitation can be induced by stimulation frequencies in the physiological range (3 and 30 Hz). Three hertz stimulation induced the early phase of LTF, but the responses were decremental. Arc and zif268, two genes previously coupled to LTP of synaptic transmission in the adult brain, are upregulated at the same frequencies that give stable LTF (30 and 100 Hz). This frequency-dependence is important for understanding how the afferent firing pattern affects neuronal plasticity and nociception in the spinal dorsal horn.

Ketamine blocks enhancement of spinal long-term potentiation in chronic opioid treated rats.

BACKGROUND: Long-term opioid treatment is associated with the development of hyperalgesia. In a rat model we wanted to study if chronic opioid treatment changed the induction and maintenance of spinal long-term potentiation (LTP), a form of hyperexcitability in the spinal cord. We also wanted to investigate if the clinically available NMDA receptor antagonist ketamine inhibited the effect of chronic opioid treatment on LTP. METHODS: The animals were randomized into four groups (saline, morphine 20 mg/kg/day, ketamine 20 mg/kg/day, morphine 20 mg/kg/day and ketamine 20 mg/kg/day). Drugs were given as continuous subcutaneous infusions by means of osmotic minipumps. After 7 days of treatment and during ongoing treatment single unit extracellular recordings were made from the lumbar deep dorsal horn under urethane anesthesia. Single electrical stimuli were applied to the sciatic nerve, and the C-fiber evoked responses of WDR neurons were recorded before and during 3 h following low frequency (3 Hz) electrical conditioning stimulation. RESULTS: The potentiation of C-fiber evoked responses by conditioning stimulation was significantly increased in the morphine-treated group compared to the saline group, while there was no significant difference between the saline, the ketamine and the morphine/ketamine groups. The potentiated responses in the morphine/ketamine group were significantly reduced compared to the morphine group (P=0.01). CONCLUSION: Our results indicate that animals treated with long-term opioid show amplification of stimulus-induced central sensitisation compared to opioid naïve animals. Ketamine inhibited the morphine-induced enhancement of LTP, supporting the role of ketamine in prevention of opioid induced hyperalgesia.

Activation of spinal serotonin(2A/2C) receptors augments nociceptive responses in the rat.

The role of spinal 5-HT(2A/2C) receptors in the regulation of spinal nociceptive transmission was studied. The 5-HT(2A/2C) agonist (+/-)-1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane (DOI) and the antagonist ketanserin tartrate were administered intrathecally immediately before the formalin test. Activation of spinal 5-HT(2A/2C) receptors increased the pain-like behavioural response in both the early and late phases. The findings support the hypothesis that spinal 5-HT(2A/2C) receptors augment the spinal afferent nociceptive impulses induced by peripheral inflammation.

Different brain areas activated during imagery of painful and non-painful 'finger movements' in a subject with an amputated arm.

The purpose of the present study was to investigate differences in brain activation with functional magnetic resonance imaging (fMRI) during imagery of painful and non-painful 'finger movements' and 'hand positioning' in a subject with an amputated arm. The subject was a right-handed man in his mid-thirties who lost his right arm just above the elbow in a car-train accident. MRI was performed with a 1.5 T Siemens Vision Plus scanner. The basic design involved four conditions: imagining 'painful finger movements', 'non-painful finger movements', 'painful hand positioning', 'non-painful hand positioning'. Imagery of finger movements uniquely activated the contralateral primary motor cortex which contains the classic 'hand area'. The lateral part of the anterior cerebellar lobe was also activated during imagery of finger movements. Imagery of pain uniquely activated the somatosensory area, and areas in the left insula and bilaterally in the ventral posterior lateral nucleus of the thalamus. It is suggested that the insula and thalamus may involve neuronal pathways that are critical for mental processing of pain-related experiences, which may relate to a better understanding of the neurobiology of phantom limb pain.

Inhibition of spinal nociceptive responses after intramuscular injection of capsaicin involves activation of noradrenergic and opioid systems.

Extracellular recordings of wide dynamic range neurones in the dorsal horn driven by electrical stimulation of the sciatic nerve were performed in intact urethane-anaesthetized Sprague-Dawley rats. The electrically evoked neuronal responses were defined as A- and C-fibres responses according to latencies, and the effect of a deep nociceptive conditioning stimulus induced by 200 microg capsaicin (8-methyl-N-vanillyl-6-noneamide) injected into the contralateral gastrocnemius-soleus muscle was studied for at least 30 min. Independent of the size and location of the receptive field of the neurone under study, a clear inhibition of the neuronal responses was observed. The electrically evoked C-fibre responses were inhibited to 53% of baseline 15-30 min after injection of capsaicin. This inhibition was only slightly attenuated by 125 nmol of the alpha-adrenoceptor antagonist phentolamine or 250 nmol of the opioid receptor antagonist naloxone applied directly onto the spinal cord when the two compounds were administered separately 5 min before capsaicin. In contrast, when a mixture of the two compounds was given 5 min before capsaicin, the effect of capsaicin was completely abolished. These results indicate that activation of the capsaicin-sensitive afferents in the gastrocnemius-soleus muscle inhibits the electrically evoked C-fibre responses in the dorsal horn by activating noradrenergic and opioidergic inhibitory systems. Moreover, our data indicate that the activation of these two systems following injection of capsaicin has a sub-additive inhibitory effect on the wide dynamic range neurones in the spinal cord. We conclude that only one of these systems is sufficient for the inhibition to occur.

Effect of spinal morphine after long-term potentiation of wide dynamic range neurones in the rat.

BACKGROUND: Studies have shown that long-term increase in the excitability of single wide dynamic range neurones in the spinal dorsal horn of rats may be induced after tetanic stimulation to the sciatic nerve. This sensory event is possibly an in vivo counterpart of long-term potentiation, described in the brain. This study investigated whether this phenomenon occurs in the halothane-anesthetized rat and whether the antinociceptive effects of spinally administered morphine are altered when tested on the enhanced activity. METHODS: Single unit extracellular recordings were made in three different groups of halothane-anesthetized rats (n = 6 in each group). In group 1, the evoked neuronal responses of wide dynamic range neurones by a single electrical stimulus to the peripheral nerve were recorded every 4 min, for 1 h before (baseline) and for 3 h after brief high-frequency conditioning stimulation of the sciatic nerve. In group 2, morphine was applied onto the spinal cord after long-term potentiation had been established. Increasing concentrations of morphine were added until the C fiber-evoked responses were abolished; this was followed by naloxone reversal. In group 3, the same protocol as in group 2 was used except a waiting period substituted for the electrical conditioning. RESULTS: The C fiber-evoked responses were significantly increased (P < 0.001) after conditioning compared with baseline and those in control animals. Further, significantly higher concentrations of morphine (P = 0.008) were needed to abolish the C fiber-evoked responses in tetanized animals than in control animals. Naloxone reversed the effects of morphine to the predrug potentiated baseline in group 2, showing that opioids do not block the maintenance of spinal long-term potentiation. CONCLUSIONS: Long-term potentiation of C fiber-evoked responses also can be induced in halothane-anesthetized rats, and morphine seems to have less potency during such conditions. These data suggest that long-term potentiation-like mechanisms may underlie some forms of hyperalgesia associated with a reduced effect of morphine.

Recording of long-term potentiation in single dorsal horn neurons in vivo in the rat.

We have published several reports on long-term potentiation (LTP) in single spinal wide dynamic range (WDR) neurons (responding to both innocuous and noxious stimuli) in urethane-anaesthetised rats. The protocol presented here, with single unit recordings of dorsal horn neurons before and after a nociceptive conditioning stimulation, may be useful in many electrophysiological studies of plastic changes in the spinal cord, such as LTP. We invite others to use this protocol for the study of spinal plasticity. Findings using this technique may be relevant for the understanding of changes in nociceptive transmission, induction of central sensitisation and maybe even in mechanisms of pathological pain and chronic pain states. We describe modified and alternative protocols for the study of LTP mechanisms under different conditions in intact and in spinalised animals, and after natural noxious stimuli. We present a novel method minimising peripheral influence of afferent input induced by antidromic neurogenic inflammation or inflammatory changes following a natural noxious stimulation. This is made possible by dissection of the sciatic nerve at two separate locations and local anaesthetic block distal to the stimulation site.