A novel ionic current contributing to spasm of small blood vessels [ 2005 - 2007 ]

Research Grant

Researchers: Dr Harold Coleman (Principal investigator) ,  Dr Marianne Tare ,  Prof Barry Mcgrath ,  Prof Helena Parkington

Brief description Vascular smooth muscle can produce strong constrictions or spasms that can severely limit blood flow. Disorders arising from such spasms include sudden death, neurological deficits, visual and hearing loss or impairment, Raynaud's phenomenon (painful episodic contraction of the fingers and toes) and intestinal necrosis. Common mechanisms are likely to underlie the spasms associated with these disparate disorders. In a recent electrophysiological study of vascular smooth muscle, we discovered a novel membrane current which we refer to as the plateau current. This current has a strong depolarizing influence that is likely to make a major contribution to the spasms, particularly in arterioles and small arteries which are more dependent on depolarization for contraction. Block of this current is expected to minimize the depolarization and therefore prevent or ameliorate spasm of the vessels. Thus the plateau current represents a new field of therapeutic potential for addressing vascular problems that have significant health implications. However, therapeutic manipulation of the current requires knowledge of its properties. In this project we will determine the biophysical and pharmacological properties of this current using voltage-clamp techniques. We will then use this information to assess its functional significance by recording membrane potential with intracellular microelectrodes simultaneously with contractile activity. We will also compare small vessels obtained from volunteers with or without the vasospastic disorder of Raynaud's phenomenon. Our previous work using these techniques was described in J Physiol as a microelectrode, patch clamp and myograph study of the highest quality and of supreme technical difficulty and scored a Top-Ten hit rate. Since we are the only ones to record the plateau current, we are in a unique position to make significant progress to our understanding of contraction, including spasm, in small blood vessels.

Funding Amount $AUD 287,500.00

Funding Scheme NHMRC Project Grants

Notes Standard Project Grant