Detection of Exhaled Hydrogen Sulphide Gas in Healthy Human Volunteers During Intravenous Administration of Sodium Sulphide

Overview

Journal Br J Clin Pharmacol

Specialty Pharmacology

Date 2010 Jun 23

PMID 20565454

Citations 45

Authors

Christopher F Toombs

Michael A Insko

Edward A Wintner

Thomas L Deckwerth

Helen Usansky

Khurram Jamil

Brahm Goldstein

Michael Cooreman

Csaba Szabo

Affiliations

Soon will be listed here.

Abstract

Introduction: Hydrogen sulphide (H(2)S) is an endogenous gaseous signaling molecule and potential therapeutic agent. Emerging studies indicate its therapeutic potential in a variety of cardiovascular diseases and in critical illness. Augmentation of endogenous sulphide concentrations by intravenous administration of sodium sulphide can be used for the delivery of H(2)S to the tissues. In the current study, we have measured H(2)S concentrations in the exhaled breath of healthy human volunteers subjected to increasing doses sodium sulphide in a human phase I safety and tolerability study.

Methods: We have measured reactive sulphide in the blood via ex vivo derivatization of sulphide with monobromobimane to form sulphide-dibimane and blood concentrations of thiosulfate (major oxidative metabolite of sulphide) via ion chromatography. We have measured exhaled H(2)S concentrations using a custom-made device based on a sulphide gas detector (Interscan).

Results: Administration of IK-1001, a parenteral formulation of Na(2)S (0.005-0.20 mg kg(-1), i.v., infused over 1 min) induced an elevation of blood sulphide and thiosulfate concentrations over baseline, which was observed within the first 1-5 min following administration of IK-1001 at 0.10 mg kg(-1) dose and higher. In all subjects, basal exhaled H(2)S was observed to be higher than the ambient concentration of H(2)S gas in room air, indicative of on-going endogenous H(2)S production in human subjects. Upon intravenous administration of Na(2)S, a rapid elevation of exhaled H(2)S concentrations was observed. The amount of exhaled H(2)S rapidly decreased after discontinuation of the infusion of Na(2)S.

Conclusion: Exhaled H(2)S represents a detectable route of elimination after parenteral administration of Na(2)S.

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