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 hypotheses that this pacemaker mechanism is also fundamental to mammalian heart pacemaking and conduction. Positive support for our hypotheses, as indicated by our findings on amphibian hearts and from 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
Sympathetic Nervous System Activation In Renal Failure. Its Contribution To Pathogenesis And Progression.
Funder
National Health and Medical Research Council
Funding Amount
$490,796.00
Summary
Cardiovascular morbidity and mortality is exceedingly high in patients with chronic renal failure and particularly end stage renal disease. Recent studies suggest that sympathetic activation contributes substantially to the development of hypertension, progression of renal disease and cardiovascular prognosis in these patients. Increased sympathetic nerve firing has been demonstrated in end stage renal disease by the use of clinical microneurography, which has been attributed to uremia-related t ....Cardiovascular morbidity and mortality is exceedingly high in patients with chronic renal failure and particularly end stage renal disease. Recent studies suggest that sympathetic activation contributes substantially to the development of hypertension, progression of renal disease and cardiovascular prognosis in these patients. Increased sympathetic nerve firing has been demonstrated in end stage renal disease by the use of clinical microneurography, which has been attributed to uremia-related toxins. However, renal transplant recipients with excellent graft function and no signs of uremia still exhibit increased sympathetic nerve firing. Most interestingly, bilateral nephrectomized patients have nerve firing rates comparable to that of normal control subjects without renal disease. These data suggest that the diseased kidneys exert excitatory effects on the sympathetic nervous system independent of correction of uremia. The proposed study aims to comprehensively investigate the pattern of sympathetic activation both centrally (microneurography) and regionally (radiotracer dilution methodology) in patients with chronic renal failure and end stage renal disease . The effect of the centrally acting sympatholytic drug rilmenidine on sympathetic activity in the setting of renal disease will be assessed. Patients with ESRD waitlisted for kidney transplantation will be studied before and after transplantation. Some of the transplant recipients will also have undergone uni- or bilateral nephrectomy before transplantation which will enable us to further explore the role of the diseased kidneys in sympathetic activation. The results of this study may prove to have significant implications for treatment and prevention of cardiovascular morbid events frequently associated with renal disease.Read moreRead less
Investigations Of Mechanisms Underlying Autonomic Cardiovascular Regulation In Medial Temporal Lobe Epilepsy.
Funder
National Health and Medical Research Council
Funding Amount
$311,860.00
Summary
People with epilepsy often show disturbed cardiovascular function which may increase mortality risk. This may reflect seizure related disturbances in the autonomic circuitry regulation of the cardiovascular system. We apply advanced brain imaging analysis of altered neural structure, circuit connectivity and function within medial temporal lobe and mid brain, combined with clinical assessment of autonomic function to provide important new insights into cardiac disturbances in epilepsy.
Vasomotor Ganglionic Transmission: The Preganglionic Peptide And The Second Gear
Funder
National Health and Medical Research Council
Funding Amount
$451,896.00
Summary
Blood pressure depends on nerve signals that travel from the central nervous system to blood vessels. In the middle of this pathway is a relay station - the sympathetic ganglion cell. Transmission through this relay station has recently been shown to have not only a fixed but also a variable component - the 'second gear'. The project tests if and how three likely candidate peptide molecules, one in the nerves, two in the bloodstream, control this 'second gear' and hence regulate blood pressure.
FUNCTIONAL IMAGING OF THE BRAINSTEM AND CORTICAL SITES OF BLOOD PRESSURE CONTROL IN HUMAN SUBJECTS IN HEALTH AND DISEASE
Funder
National Health and Medical Research Council
Funding Amount
$398,498.00
Summary
Disturbances in cardiovascular control underpin many diseases yet little is known about how the brain controls the heart and blood vessels. This project uses brain imaging (fMRI) and concurrent nerve recording in awake human subjects to increase our understanding of how normal blood pressure is maintained and how different disease states influence this control.
Reduced Baroreceptor Reflex Control Of Heart Rate In Chronic Renal Failure
Funder
National Health and Medical Research Council
Funding Amount
$490,288.00
Summary
People with kidney disease are more likely to die of heart disease than their ailing kidneys. One reason is because their hearts do not respond properly to changes in blood pressure, as the nerve circuits controlling the heart become dysfunctional. We will examine where and why components of this circuit are unable to respond to changes in blood pressure. This will help guide new treatments to reduce the incidence of heart disease and risk of death associated with kidney disease.
Network Interactions Between Cardiovascular Control Neurons In The Brainstem Underlie Sympathetic Tone
Funder
National Health and Medical Research Council
Funding Amount
$268,328.00
Summary
High blood pressure is a very significant risk factor for many common cardiovascular diseases. Blood pressure is normally tightly regulated by groups of neurons in the brainstem; although we know that this part of the brain becomes dysfunctional in patients with high blood pressure, we do not understand why. We have recently discovered that cardiovascular control neurons can influence each other. The project will determine the effect of such communication in the control of blood pressure.