Association of respiratory failure with inhibition of NaV1.6 in the phrenic nerve.

As part of a drug discovery effort to identify potent inhibitors of NaV1.7 for the treatment of pain, we observed that inhibitors produced unexpected cardiovascular and respiratory effects in vivo. Specifically, inhibitors administered to rodents produced changes in cardiovascular parameters and respiratory cessation.

Identification, Synthesis, and Characterization of a Major Circulating Human Metabolite of TRPV4 Antagonist GSK2798745.

GSK2798745, an antagonist of the transient receptor potential vanilloid 4 (TRPV4) ion channel, was recently investigated in clinical trials for the treatment of cardiac and respiratory diseases. Human plasma and urine samples collected from healthy volunteers following oral administration were analyzed to identify circulating and excreted metabolites of the parent drug. One major circulating metabolite () was found in pooled human plasma samples, accounting for approximately half of the observed drug-related material.

Discovery of Arylsulfonamide Na1.7 Inhibitors: IVIVC, MPO Methods, and Optimization of Selectivity Profile.

The voltage-gated sodium channel Na1.7 continues to be a high-profile target for the treatment of various pain afflictions due to its strong human genetic validation. While isoform selective molecules have been discovered and advanced into the clinic, to date, this target has yet to bear fruit in the form of marketed therapeutics for the treatment of pain.

Discovery of GSK3527497: A Candidate for the Inhibition of Transient Receptor Potential Vanilloid-4 (TRPV4).

GSK3527497, a preclinical candidate for the inhibition of TRPV4, was identified starting from the previously reported pyrrolidine sulfonamide TRPV4 inhibitors and . Optimization of projected human dose was accomplished by specifically focusing on in vivo pharmacokinetic parameters CL, Vdss, and MRT. We highlight the use of conformational changes as a novel approach to modulate Vdss and present results that suggest that molecular-shape-dependent binding to tissue components governs Vdss in addition to bulk physicochemical properties.