Hydraphiles: a Rigorously Studied Class of Synthetic Channel Compounds with in Vivo Activity

Overview

Journal Int J Biomed Imaging

Publisher Wiley

Specialty Radiology

Date 2013 Feb 13

PMID 23401675

Citations 3

Authors

Saeedeh Negin

Bryan A Smith

Alexandra Unger

W Matthew Leevy

George W Gokel

Affiliations

Soon will be listed here.

Abstract

Hydraphiles are a class of synthetic ion channels that now have a twenty-year history of analysis and success. In early studies, these compounds were rigorously validated in a wide range of in vitro assays including liposomal ion flow detected by NMR or ion-selective electrodes, as well as biophysical experiments in planar bilayers. During the past decade, biological activity was observed for these compounds including toxicity to bacteria, yeast, and mammalian cells due to stress caused by the disruption of ion homeostasis. The channel mechanism was verified in cells using membrane polarity sensitive dyes, as well as patch clamping studies. This body of work has provided a solid foundation with which hydraphiles have recently demonstrated acute biological toxicity in the muscle tissue of living mice, as measured by whole animal fluorescence imaging and histological studies. Here we review the critical structure-activity relationships in the hydraphile family of compounds and the in vitro and in cellulo experiments that have validated their channel behavior. This report culminates with a description of recently reported efforts in which these molecules have demonstrated activity in living mice.

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