Heartbeats are considered to arise through specialised pacemaker cells establishing rhythmically generated (i.e. pacemaker) action potentials, which then trigger propagating action potentials in heart muscle causing contraction and pumping of blood. This research proposal aims to challenge the physical model that is used to describe this pacemaker process and resultant heart conduction. Our reasons for doing this derive from our discovery of an alternative pacemaker-conduction mechanism, which w ....Heartbeats are considered to arise through specialised pacemaker cells establishing rhythmically generated (i.e. pacemaker) action potentials, which then trigger propagating action potentials in heart muscle causing contraction and pumping of blood. This research proposal aims to challenge the physical model that is used to describe this pacemaker process and resultant heart conduction. Our reasons for doing this derive from our discovery of an alternative pacemaker-conduction mechanism, which we have shown to operate in various smooth muscles. This mechanism, termed store-based pacemaking, is entirely different to the currently held cardiac model but could readily achieve the same outcome. We will investigate the hypothesis that this pacemaker mechanism is also fundamental to heart pacemaking and conduction. Positive support for our hypothesis, as indicated by our pilot findings, may severely challenge the present model for cardiac pacemaking. Such an outcome will have major ramifications on present interpretation of cardiac function in health and disease and will be particularly important to interpretation of disorders associated with cardiac arrhythmias and heart conduction.Read moreRead less
Although the heart contracts spontaneously, the rate and force with which it beats may be modified by the autonomic nervous system. That is, the rate and force of heart muscle contraction may be increased or decreased by the activation of two different sets of nerves. This project will determine how the autonomic nervous system modifies the strength of heart muscle contraction. It will involve the measurement of changes in contractile force, electrical activity and calcium levels within cardiac ....Although the heart contracts spontaneously, the rate and force with which it beats may be modified by the autonomic nervous system. That is, the rate and force of heart muscle contraction may be increased or decreased by the activation of two different sets of nerves. This project will determine how the autonomic nervous system modifies the strength of heart muscle contraction. It will involve the measurement of changes in contractile force, electrical activity and calcium levels within cardiac cells during muscle contraction. The effects of excitatory and inhibitory nerve stimulation on these three parameters will be examined. Results of this study will improve our understanding of how the contraction of heart muscle is controlled and provide an insight into the treatment of heart disease.Read moreRead less
Role Of Calcium Channels And Small-conductance Potassium Channels In Myenteric Neurons
Funder
National Health and Medical Research Council
Funding Amount
$131,717.00
Summary
This proposal will investigate the electrical properties of neurons in the wall of the intestine that control movements of the bowel. These neurons form an extensive network that runs the length of the gastrointestinal tract and control mixing and propulsion of food along the intestine. We will determine the basic electrical properties of these neurons and investigate why some of them transmit signals in a continuous manner while others transmit signals intermittently and how these patterns of a ....This proposal will investigate the electrical properties of neurons in the wall of the intestine that control movements of the bowel. These neurons form an extensive network that runs the length of the gastrointestinal tract and control mixing and propulsion of food along the intestine. We will determine the basic electrical properties of these neurons and investigate why some of them transmit signals in a continuous manner while others transmit signals intermittently and how these patterns of activity fit into the overall activity of the gut. This study will build on a large body of data obtained from our laboratory that has shown that some of these neurons act as sensors of the presence-absence of food in the intestine while others send signals to the muscle in the wall of the intestine to either relax or contract it so that the food can be processed properly. By knowing what makes these neurons different from each other we will be able to understand what goes wrong in functional bowel disorders where motility is affected, resulting in pain and discomfort.Read moreRead less
The applicant aims to improve treatment of digestive disease by identifying and understanding the interactions between the nervous system and the gastrointestinal (GI) tract, with emphasis on sensory systems.