Optimizing Implanted Cell Survival Using A Tissue Engineering Model
Funder
National Health and Medical Research Council
Funding Amount
$589,175.00
Summary
Cell therapy and tissue engineering involve the insertion of specific cells into damaged tissues or into a bioraector in a patient's body to generate new replacement tissues. This project seeks to improve two factors associated with inserting cells : 1. The innate survival characteristics of the cells being inserted, and 2. The blood vessel supply at the site of insertion. These techniques will greatly improve the survival of inserted cells.
Role Of Sensory Neurons In Obstruction-induced Bladder Overactivity
Funder
National Health and Medical Research Council
Funding Amount
$340,986.00
Summary
About 20% of people over the age of 40 have the clinical syndrome of an “overactive bladder”, which causes symptoms of urgency, frequency and incontinence. The mechanisms causing bladder overactivity are not known. This project will identify sensory neurons, which become overexcited, and determine which mediators and ionic channels are responsible for this. Our new data will identify selective pharmacological targets for new therapies and diagnostic tools for these distressing bladder disorders.
The Neurovascular Territories Of The Human Body: Anatomic Study And Clinical Applications
Funder
National Health and Medical Research Council
Funding Amount
$186,650.00
Summary
A Melways Roadmap of the anatomy of the large and small nerves, arteries and veins of the human body is underway and will take a further three years to complete. The aim is to evolve or modify Reconstructive Plastic Surgery techniques taking tissue from a hidden site and, where possible, include a nerve supply with the transplant so that feeling can be restored to skin flaps and function to transferred muscle. The fundamental objective is to improve the quality of the patients life. We have alre ....A Melways Roadmap of the anatomy of the large and small nerves, arteries and veins of the human body is underway and will take a further three years to complete. The aim is to evolve or modify Reconstructive Plastic Surgery techniques taking tissue from a hidden site and, where possible, include a nerve supply with the transplant so that feeling can be restored to skin flaps and function to transferred muscle. The fundamental objective is to improve the quality of the patients life. We have already completed a thorough examination of the following regions: (i) head and neck (ii) forearm (iii) leg These have received international acclaim and awards. We are currently examining: (i) hand and foot (ii) thigh and buttock. Still to be commenced: (i) arm and shoulder (ii) torso (iii) back. Reconstructive surgery involves the treatment and the reconstruction of defects throughout the whole human body. These defects may arise in any member of the family. With modern reconstructive techniques a problem can often be solved in one operation thus avoiding multiple operations and long periods of hospitalisation which can be devastating to both patient and family. These new techniques nevertheless have demanded a reappraisal of the basic sciences, especially the anatomy of the blood and nerve supply to the potential transplant. This is essential so that they can be designed with not only precision and safety but in such a way that there is minimal disability at the donor site. As well as restoring shape and form, the patient can have tremendous improvement in quality of life and independence if function is also restored. In order to provide function (feeling and movement) a working nerve supply must be included in the reconstruction. Therefore our research must continue to investigate the complex patterns of nerve supply to tissues of the body and correlate this information with the blood supply which is needed to keep the tissue alive.Read moreRead less
Improved Ex-vivo Culture Of Keratinocytes For Clinical Applications
Funder
National Health and Medical Research Council
Funding Amount
$275,203.00
Summary
Skin cells grown for clinical applications currently require animal-derived cells and-or non-defined products for their expansion in the laboratory; these reagents can potentially infect patients who receive these therapies. This project will identify the essential components provided by these reagents and develop a fully synthetic and defined culture system. This improvement will provide safer, cost-effective grafts and cell-based therapies that will benefit patients suffering burns and wounds.
Periodontal Mesenchymal Stem Cells For Periodontal Regeneration
Funder
National Health and Medical Research Council
Funding Amount
$358,000.00
Summary
Dental diseases affecting the gums (periodontal disease) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised masticatory function. If left untreated, the associated pain and loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characteriz ....Dental diseases affecting the gums (periodontal disease) are extremely prevalent in our society. The effects of periodontal disease can be particularly severe as loss of support for the teeth leads to loose teeth and severely compromised masticatory function. If left untreated, the associated pain and loss of function may necessitate extraction of the teeth. We have recently identified cells residing in the periodontal ligament which may be adult stem cells. This project will further characterize these cells and explore whether they can be used to restore periodontal tissues damaged by periodontal disease.Read moreRead less
Optimising Efficacy Of A Peptide Derived Against The Alpha-interacting Domain Of The L-type Calcium Channel In Reduction Of Ischemia-reperfusion Injury
Funder
National Health and Medical Research Council
Funding Amount
$405,063.00
Summary
A heart attack is associated with an increase in free radicals and calcium in heart muscle cells. The function of the L-type calcium channel, a protein responsible for calcium entry into cells, is altered by free radicals and this contributes to the development of heart disease. We now have considerable proof of concept that a peptide derived against the L-type calcium channel can decrease heart injury. We will optimise efficacy and delivery of the peptide to prevent heart failure.