Improved electrophysiological mapping techniques have enhanced understanding of arrhythmia mechanisms and the development of curative ablation strategies. Advanced mapping systems utilize online visualization of catheters, 3D geometry, and annotation of ablation sites. To date, all commercially available systems rely on proprietary equipment to locate catheter positions and reconstruct chamber shape from multiple site recordings. Thus, cost is prohibitive, limiting widespread availability. An al ....Improved electrophysiological mapping techniques have enhanced understanding of arrhythmia mechanisms and the development of curative ablation strategies. Advanced mapping systems utilize online visualization of catheters, 3D geometry, and annotation of ablation sites. To date, all commercially available systems rely on proprietary equipment to locate catheter positions and reconstruct chamber shape from multiple site recordings. Thus, cost is prohibitive, limiting widespread availability. An alternative approach has emerged with the use of CT-MRI imaging and analysis. Novel techniques extract images of the endocardial surface from CT-MRI for use in electrophysiological mapping. This surface can be used as the chamber geometry instead of reconstruction based on expensive technology measuring spatial coordinates of the catheter tip inside heart. The proposed Anatomical Template Mapping System (ATMS) will generate maps of electrophysiological parameters derived from catheter recordings without the need for proprietary equipment. The physician will direct the virtual catheter position onto the 3D model of the chamber, obviating the need for equipment to map the spatial distribution of the catheters. The major advantage is that, without the need for specialized equipment, this method of mapping is substantially cheaper and can be used with any conventional electrophysiological mapping systems. Furthermore, it will provide the most important feature of the advanced mapping systems - an understanding of the arrhythmia mechanism.Read moreRead less
A Single Digital Handheld Imaging Device For Use In Both Ophthalmology And Dentistry
Funder
National Health and Medical Research Council
Funding Amount
$431,221.00
Summary
Our aim is to produce and validate a single digital imaging device which can be used in ophthalmology (both for retinal and anterior segment imaging) and dentistry. This device will be low-cost, easy-to-operate and portable. Our planned development of the novel screening tool should help in bringing high quality, lower cost health care to those without easy access to it, firstly to residents of rural areas in Australia and then in developing countries in our region. This can be achieved by more ....Our aim is to produce and validate a single digital imaging device which can be used in ophthalmology (both for retinal and anterior segment imaging) and dentistry. This device will be low-cost, easy-to-operate and portable. Our planned development of the novel screening tool should help in bringing high quality, lower cost health care to those without easy access to it, firstly to residents of rural areas in Australia and then in developing countries in our region. This can be achieved by more efficient screening methods and redirecting resources to target those with treatable eye disease only. The detection process can be progressively transferred to less expensive health workers while ophthalmologist input can be redirected to monitoring the screening results and performing surgery. The dentists travel infrequently to rural and remote WA. If the dentist can pre plan their treatment then it will be more efficient and possible to treat more people at each visit to remote and rural WA. With the help of the proposed imaging device for dentistry, the nurses and other allied personnel should be able to send the digital images in advance to dentist over Internet and therefore help dentist pre-plan their treatment. As a result, improved dental care for rural, remote and underserved communities will occur.Read moreRead less
Development Of A New Surgical-guidance Tool For Intra-operative Tumour Margin Assessment In Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$557,982.00
Summary
One third of breast cancer patients undergoing breast conserving surgery have insufficient tissue removed, resulting in an increased risk of recurrence. We have developed a high resolution optical imaging probe with the potential to detect small areas of cancer. It could be used to help guide the surgeon to remove all cancerous tissue from the patient. This grant will allow us to develop the probe to a stage that it can be used during surgery, and perform the world’s first clinical scans.
Development Of Microscope-in-a-needle Devices For Improved Clinical Diagnostics
Funder
National Health and Medical Research Council
Funding Amount
$327,746.00
Summary
We have developed a new high-resolution optical imaging technology. The unique aspect of our research has been to redesign the imaging probe, miniaturising it to a few hundred microns in diameter, and encase it in a hypodermic needle – a ‘microscope-in-a-needle’. We are developing specific imaging probes to aid in the assessment of lung disease; the diagnosis of liver disease; and integrated into a brain biopsy needle to enable safer brain biopsies.
Advances in positron emission tomography now allow specific pathological features of many brain diseases such as Alzheimer's disease to be measured with a brain scan during life. This Fellowship will assist Professor Rowe and his team in their world leading work on new PET scanning techniques to improve diagnosis and assist the development of treatment for Alzheimer's and other degenerative diseases of the brain.
Regulation Of Nuclear Calcium Concentration In The Life Or Death Of Cells
Funder
National Health and Medical Research Council
Funding Amount
$195,047.00
Summary
The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell ....The nucleus is the most prominent of all cell organelles and contains the primary genetic material for cellular development and growth. It performs some of the most important functions in the life and death of all living cells. However, little is known about many of the regulatory signals and events that control nuclear function. We will use new genetically-encoded sensor molecules that a living cell can be instructed to produce at various internal locations to explore important features of cell control. This study will look specifically at how changes in the concentration of ionised Ca2+ in the nucleus control the switching on of genes and the initiation of programmed cell death pathways. This information is of significance to our understanding of normal cell growth and development, as well as abnormal growth (e.g. cancer).Read moreRead less
Improving Human FMRI Through Modeling And Imaging Microvascular Dynamics
Funder
National Health and Medical Research Council
Funding Amount
$486,144.00
Summary
In this project we aim to establish a reliable vascular baseline to improve mapping of both small-scale functional architecture and large-scale brain networks in functional human brain mapping using MRI. By mapping the grey matter vasculature with high detail in both humans and animals, and by computing and matching of these atlases across species we will be able to validate this approach in vivo to confirm the better spatial specificity of the newly developed approach.
Non-invasive Near-infrared Optical Imaging Of Neurodegeneration
Funder
National Health and Medical Research Council
Funding Amount
$312,033.00
Summary
Dementia currently affects over 240,000 Australians with an increasing health cost. A common cause of dementia occurs when proteins in the brain form deposits and brain cells degenerate and die. This project will develop a novel medical imaging method that will facilitate the detection of dying brain cells. This will enable a better understanding of the causes of cell death and the opportunity to identify the best time for meaningful therapeutic intervention.