2021 - Characterization of Vixotrigine, a Broad-Spectrum Voltage-Gated Sodium Channel Blocker
SyncroPatch 384PE (a predecessor model of the SyncroPatch 384 instrument) Publication in Molecular Pharmacology (2021)
A. Hinckley C., Kuryshev Y., Sers A., Barre A., Buisson B., Naik H., Hajos M.
Molecular Pharmacology (2021) 99 (1) 49-59; DOI: https://doi.org/10.1124/molpharm.120.000079
Voltage-gated sodium channels (Navs) are promising targets for analgesic and antiepileptic therapies. Although specificity between Nav subtypes may be desirable to target specific neural types, such as nociceptors in pain, many broadly acting Nav inhibitors are clinically beneficial in neuropathic pain and epilepsy. Here, we present the first systematic characterization of vixotrigine, a Nav blocker. Using recombinant systems, we find that vixotrigine potency is enhanced in a voltage- and use-dependent manner, consistent with a state-dependent block of Navs. Furthermore, we find that vixotrigine potently inhibits sodium currents produced by both peripheral and central nervous system Nav subtypes, with use-dependent IC50 values between 1.76 and 5.12 μM. Compared with carbamazepine, vixotrigine shows higher potency and more profound state-dependent inhibition but a similar broad spectrum of action distinct from Nav1.7- and Nav1.8-specific blockers. We find that vixotrigine rapidly inhibits Navs and prolongs recovery from the fast-inactivated state. In native rodent dorsal root ganglion sodium channels, we find that vixotrigine shifts steady-state inactivation curves. Based on these results, we conclude that vixotrigine is a broad-spectrum, state-dependent Nav blocker.