Small RNAs control sodium channel expression, nociceptor excitability, and pain thresholds.

To examine the role of small RNAs in peripheral pain pathways, we deleted the enzyme Dicer in mouse postmitotic damage-sensing neurons. We used a Nav1.8-Cre mouse to target those nociceptors important for inflammatory pain. The conditional null mice were healthy with a normal number of sensory neurons and normal acute pain thresholds. Behavioral studies showed that inflammatory pain was attenuated or abolished. Inflammatory mediators failed to enhance excitability of Nav1.8+ sensory neurons from null mutant mice. Acute noxious input into the dorsal horn of the spinal cord was apparently normal, but the increased input associated with inflammatory pain measured using c-Fos staining was diminished. Microarray and quantitative real-time reverse-transcription PCR (qRT-PCR) analysis showed that Dicer deletion lead to the upregulation of many broadly expressed mRNA transcripts in dorsal root ganglia. By contrast, nociceptor-associated mRNA transcripts (e.g., Nav1.8, P2xr3, and Runx-1) were downregulated, resulting in lower levels of protein and functional expression. qRT-PCR analysis also showed lowered levels of expression of nociceptor-specific pre-mRNA transcripts. MicroRNA microarray and deep sequencing identified known and novel nociceptor microRNAs in mouse Nav1.8+ sensory neurons that may regulate nociceptor gene expression.

Preclinical and early clinical investigations related to monoaminergic pain modulation.

The balance between descending controls, both excitatory and inhibitory, can be altered in various pain states. There is good evidence for a prominent alpha(2)-adrenoceptor-mediated inhibitory system and 5-HT(3) (and likely also 5-HT(2)) serotonin receptor-mediated excitatory controls originating from brainstem and midbrain areas. The ability of cortical controls to influence spinal function allows for top-down processing through these monoamines. The links between pain and the comorbidities of sleep problems, anxiety, and depression may be due to the dual roles of noradrenaline and of 5-HT in these functions and also in pain. These controls appear, in the cases of peripheral neuropathy, spinal injury, and cancer-induced bone pain to be driven by altered peripheral and spinal neuronal processes; in opioid-induced hyperalgesia, however, the same changes occur without any pathophysiological peripheral process. Thus, in generalized pain states in which fatigue, mood changes, and diffuse pain occur, such as fibromyalgia and irritable bowel syndrome, one could suggest an abnormal engagement of descending facilitations with or without reduced inhibitions but with central origins. This would be an endogenous central malfunction of top-down processing, with the altered monoamine systems underlying the observed symptoms. A number of analgesic drugs can either interact with or have their actions modulated by these descending systems, reinforcing their importance in the establishment of pain but also in its control.

Effects of lacosamide, a novel sodium channel modulator, on dorsal horn neuronal responses in a rat model of neuropathy.

Various mechanisms underlie the complexity of neuropathic pain (pain due to disease of the somatosensory system), with each mechanism bearing a different order of relevance from one person and pain state to the next. Successful treatment is contingent on sound knowledge of underlying mechanisms that may occur at peripheral, spinal and/or supraspinal sites. In particular, ion channels throughout the nervous system are known to play an intimate part in neuropathic pain, and thus stand as good targets for analgesic drugs. Agents that modulate voltage-gated sodium channel function can reduce action potential propagation along sensory neurones to reduce the transmission and perception of nociceptive signals. Lacosamide is a functionalised amino acid that affects voltage-gated sodium channels in a novel way by enhancing the slow inactivating 'braking' state of these channels. To validate lacosamide's inhibitory efficacy in vivo, we unilaterally ligated spinal nerves L5 and L6 in rats to induce a state of neuropathy, and on post-operative days 14-17 recorded evoked-responses of deep dorsal horn neurones before and after spinal or systemic lacosamide delivery. Lacosamide's effects on various measures in spinal nerve-ligated rats were compared to rats that underwent sham surgery. Our results show that neuropathy induced novel inhibitory effects of lacosamide on mechanical and electrical responses, and enhanced inhibitory effects on thermal responses after systemic or spinal administration, suggesting state-preference actions of lacosamide.

Efficacy of chronic morphine in a rat model of cancer-induced bone pain: behavior and in dorsal horn pathophysiology.

UNLABELLED: Morphine is one of the main analgesics in cancer-induced bone pain (CIBP). To investigate the efficacy of morphine in CIBP and alteration in dorsal horn pathophysiology, systemic morphine was administered (3 mg/kg) bi-daily between days 11 and 15 after MRMT-1 carcinoma cell injections (compared with a single injection (3 mg/kg) of morphine on day 15, and acute spinal morphine (0.1, 1, 10 microg/50 microL). The chronic systemic morphine schedule significantly attenuated pain behavior (von Frey 15 g; P < .01) to a greater extent than acute systemic morphine (von Frey 15 g; P < .05). In vivo electrophysiology (day 15 chronic systemic morphine) showed an attenuation of hyperexcitable wide dynamic range (WDR) neurons, but the abnormal raised WDR to nociceptive specific neuronal ratio remained. Acute spinal morphine attenuated electrical and natural WDR neuronal response in shams at a lower dose (1 microg) compared with cancer (10 microg). Chronic morphine is more effective at attenuating pain-related behaviors than single doses, although the dorsal horn retains a pathophysiologic characterization. PERSPECTIVE: This study confirms the resemblance of the rat model to human CIBP with respect to the efficacy of morphine and further suggests that adjuvant therapy is required to reverse the dorsal horn pathophysiology.