Role Of Microvascular Flowmotion In Skeletal Muscle Glucose Metabolism
Funder
National Health and Medical Research Council
Funding Amount
$596,971.00
Summary
Obesity and type 2 diabetes are nationally and globally reaching epidemic rates. This project investigates the regulation of blood flow within muscle and its impact on metabolism. Outcomes from the study may lead to diagnostic tools and treatments for cardiovascular disease associated with obesity, hypertension and type 2 diabetes.
Performance And Safety Testing Of The BioQ Cardiac Assist System In A Chronic Ovine Heart Failure Animal Model
Funder
National Health and Medical Research Council
Funding Amount
$142,800.00
Summary
This proposal will test a novel cardiac assist system in safety and performance studies using a chronic sheep heart failure model. This device has been tested in cardiovascular simulators and in an acute animal model showing attractive proof-of-concept data. Specifically, the device increased left coronary artery blood flow and reduced aortic pulse and mean pressures using our novel self-powered fully implantable stand alone device, a potential therapy treatment for heart failure.
Rhythmicity, Synchronicity And Spasm In Smooth Muscle
Funder
National Health and Medical Research Council
Funding Amount
$614,520.00
Summary
Many cellular systems undergo rhythmical spontaneous chemical and-or electrical activity . This activity, often referred to as pacemaking, is prevalent in many organs underlying brain waves or causing heart beats or rhythmic contractions of smooth muscle. Our studies on pacemaker rhythmicities in smooth muscle have revealed a novel mechanism, one which is entirely different to that responsible for heart pacemaking, the generally held model for electrical pacemakers. We aim to study the mechanism ....Many cellular systems undergo rhythmical spontaneous chemical and-or electrical activity . This activity, often referred to as pacemaking, is prevalent in many organs underlying brain waves or causing heart beats or rhythmic contractions of smooth muscle. Our studies on pacemaker rhythmicities in smooth muscle have revealed a novel mechanism, one which is entirely different to that responsible for heart pacemaking, the generally held model for electrical pacemakers. We aim to study the mechanism in depth so that we can fully describe its operation. This knowledge will provide insight into phenomena such as spontaneous contractions in blood vessels, lymphatic vessels and in the gastrointestinal tract, activities which are the norm and which are likely to have major influence on blood pressure, the propulsion of lymph and gut peristalsis. The knowledge will in the longer term lead to a better understanding of rhythmicities generally as far ranging as uterine contractions during childbirth to brain waves. An understanding of the pacemaker mechanism may also provide a key to understanding debilitating conditions such as vasospasm which can lead to death or serious disability.Read moreRead less