A novel slow-inactivation-specific ion channel modulator attenuates neuropathic pain.

Abstract	Voltage-gated ion channels are implicated in pain sensation and transmission signaling mechanisms within both peripheral nociceptors and the spinal cord. Genetic knockdown and knockout experiments have shown that specific channel isoforms, including Na(V)1.7 and Na(V)1.8 sodium channels and Ca(V)3.2 T-type calcium channels, play distinct pronociceptive roles. We have rationally designed and synthesized a novel small organic compound (Z123212) that modulates both recombinant and native sodium and calcium channel currents by selectively stabilizing channels in their slow-inactivated state. Slow inactivation of voltage-gated channels can function as a brake during periods of neuronal hyperexcitability, and Z123212 was found to reduce the excitability of both peripheral nociceptors and lamina I/II spinal cord neurons in a state-dependent manner. In vivo experiments demonstrate that oral administration of Z123212 is efficacious in reversing thermal hyperalgesia and tactile allodynia in the rat spinal nerve ligation model of neuropathic pain and also produces acute antinociception in the hot-plate test. At therapeutically relevant concentrations, Z123212 did not cause significant motor or cardiovascular adverse effects. Taken together, the state-dependent inhibition of sodium and calcium channels in both the peripheral and central pain signaling pathways may provide a synergistic mechanism toward the development of a novel class of pain therapeutics.
Authors	Michael E Hildebrand, Paula L Smith, Chris Bladen, Cyrus Eduljee, Jennifer Y Xie, Lina Chen, Molly Fee-Maki, Clint J Doering, Janette Mezeyova, Yongbao Zhu, Francesco Belardetti, Hassan Pajouhesh, David Parker, Stephen P Arneric, Manjeet Parmar, Frank Porreca, Elizabeth Tringham, Gerald W Zamponi, Terrance P Snutch
Journal	Pain (Pain) Vol. 152 Issue 4 Pg. 833-843 (Apr 2011) ISSN: 1872-6623 [Electronic] United States
PMID	21349638 (Publication Type: Journal Article, Research Support, Non-U.S. Gov't)
Copyright	Copyright © 2011 International Association for the Study of Pain. Published by Elsevier B.V. All rights reserved.
Chemical References	Acetanilides Acrylates Cacna1h protein, rat Calcium Channels, T-Type Ion Channels Membrane Transport Modulators NAV1.7 Voltage-Gated Sodium Channel NAV1.8 Voltage-Gated Sodium Channel Piperazines SCN10A protein, human Scn10a protein, rat Scn9a protein, rat Sodium Channel Blockers Sodium Channels Z 123212 Tetrodotoxin ethylacetylacrylate
Topics	Acetanilides (chemical synthesis, chemistry, pharmacokinetics, therapeutic use) Acrylates (chemical synthesis, chemistry, pharmacokinetics, therapeutic use) Analysis of Variance Animals Animals, Newborn Biophysics Calcium Channels, T-Type (genetics, metabolism) Cell Line, Transformed Disease Models, Animal Electric Stimulation Ganglia, Spinal (pathology) Heart (drug effects, physiopathology) Humans Hyperalgesia (drug therapy, pathology, physiopathology) In Vitro Techniques Ion Channels (genetics, metabolism) Male Membrane Transport Modulators (chemical synthesis, chemistry, pharmacokinetics, therapeutic use) NAV1.7 Voltage-Gated Sodium Channel NAV1.8 Voltage-Gated Sodium Channel Neural Inhibition (drug effects) Neuralgia (drug therapy, metabolism, pathology) Pain Measurement (methods) Patch-Clamp Techniques Piperazines (chemical synthesis, chemistry, pharmacokinetics, therapeutic use) Rabbits Rats Rats, Wistar Sensory Receptor Cells (drug effects, physiology) Sodium Channel Blockers (pharmacology) Sodium Channels (genetics, metabolism) Spinal Cord (pathology) Spinal Nerves (pathology) Tetrodotoxin (pharmacology) Transfection (methods)

Join CureHunter, for free Research Interface BASIC access!

Take advantage of free CureHunter research engine access to explore the best drug and treatment options for any disease. Find out why thousands of doctors, pharma researchers and patient activists around the world use CureHunter every day.

Realize the full power of the drug-disease research graph!