Mitochondrial donation in fertilised eggs is a possible therapy for avoiding mitochondrial DNA disease, but there are major safety concerns, such as mutant mitochondrial carryover. To address these concerns, we will develop two new methods to eliminate carryover risk, then translate our findings to human eggs. Also, we will determine if the mitochondrial donation procedure affects offspring health. Our findings will serve as a guide for adopting the technology.
UNDERSTANDING THE BENEFITS AND LIMITATIONS OF METAPHASE II SPINDLE TRANSFER
Funder
National Health and Medical Research Council
Funding Amount
$1,629,373.00
Summary
Mitochondrial DNA (mtDNA) diseases are transmitted from a mother's eggs to her children. However, the levels of affected mtDNA differ amongst her eggs. Consequently, a carrier would not know if the newborn child were to suffer from these diseases. Mitochondrial Donation offers couples the potential to have an unaffected child. We will undertake the most comprehensive study of mitochondrial donation using one of its associated approaches to determine if it produces healthy embryos and offspring.
Osteoarthritis Compass: Predicting Personalized Disease Onset And Progression With Future Capacity For Clinical Use.
Funder
National Health and Medical Research Council
Funding Amount
$860,231.00
Summary
Knee osteoarthritis (OA) is common, painful, and costly. General guidelines for knee OA management exist but cannot be personalized to the patient. New computer modelling methods enable prediction of knee OA onset and progression on a patient by patient basis but need further testing. Our aims are to 1) apply these new computer modelling methods to legacy datasets acquired from patient groups at risk of, and with, knee OA, and 2) make these models simple and fast enough to be clinically useful.
Improving Cardiac Valve Implant Outcomes With Advanced Computer Simulation
Funder
National Health and Medical Research Council
Funding Amount
$593,367.00
Summary
This project focuses on improving heart valve procedures, specifically focusing on new transcatheter techniques of heart valve implantation. The research uses advanced imaging and computer simulation techniques to predict the outcome and improve minimally invasive heart procedures.