New Therapies Requiring Ultra Large Scale Monoclonal Ab Production In Microalgae
Funder
National Health and Medical Research Council
Funding Amount
$630,089.00
Summary
Monoclonal antibodies target pathogens and molecules with exquisite specificity, and are essential for therapeutics and diagnostics. They are currently made using high-tech/limited-capacity mammalian cell cultures which limit them to low-dose applications. We aim to enable new, high-dose antibody therapies (e.g. antiviral treatments, passive immunisation) via rapid, low-cost, dramatically larger-scale production of valuable medicinal antibodies in a photosynthetic-driven, green algae system.
Exploiting Anti-capsid Humoral Immunity Induced In Infants Receiving Gene Therapy For Spinal Muscular Atrophy To Engineer The Next Generation Of Gene Transfer Vectors
Funder
National Health and Medical Research Council
Funding Amount
$1,105,993.00
Summary
After 25 years of incremental progress the possibility of treating genetic disease by gene therapy has become a therapeutic reality. This has been achieved by harnessing the gene transfer power of viruses made harmless by genetic engineering. A major limitation is that up to 50% of patients are currently excluded by pre-existing immunity to these powerful tools. Using 'evolution in a dish', we will engineer a new generation of these tools capable of bypassing pre-existing immunity by stealth.
Developing New Immunotherapeutics Through Studying Immune Effectors In Situ
Funder
National Health and Medical Research Council
Funding Amount
$1,369,054.00
Summary
The immune system deploys pore forming proteins to clear viral and bacterial infections and to eliminate cancerous cells. The unwanted activities of these molecules, however, results in chronic disease and in transplant rejection. We aim to understand how pore forming immune weapons interact with our own cells, with the goal of using this information to develop new approaches to treat immune driven disease and to improve the success of transplantation therapy.
Developing Improved Therapies For Cytomegalovirus Infections By Overcoming Viral Strain Diversity.
Funder
National Health and Medical Research Council
Funding Amount
$1,126,820.00
Summary
Cytomegalovirus infection is the most common cause of infection-related disease in newborns and is one of the most common complications in transplant patients. Current treatments are not always successful and are associated with significant side-effects. We have therefore developed world first systems that can be used to develop safer, more effective treatments for this life-threatening infection. Our findings are likely to be applicable to other difficult to manage viral infections.
Manipulating Antibody Production To Maximise Memory In Vaccine Responses
Funder
National Health and Medical Research Council
Funding Amount
$1,084,424.00
Summary
Our immune system provides protection from germs. The secretion of germ-specific proteins (antibodies) is an integral component of this defence and the basis of virtually all vaccines. Pandemics of Influenza and SARS-CoV-2 and failure to develop vaccines against HIV and Malaria remind us that our strategies need urgent improvement. Increasing our understanding of how our body defends us by specifically targeting foreign structures will reveal avenues for successful, rational vaccine development.
The Ins And Outs Of Endocytosis Inhibition: Providing Diverse Opportunities For Treatment Of Incurable Cancers
Funder
National Health and Medical Research Council
Funding Amount
$912,353.00
Summary
The best new immune system anti-cancer drugs only work in ~30% of patients. We found a way to move the drug targets around in people's tumours temporarily to reverse resistance and have tested this in clinical trials. Here we propose to use immunology and the world's frontier electron microscope techniques to work out exactly what is happens to the tumours, immune cells and anti-cancer drugs when they interact in real clinical situations. The aim is to reach at least 60% patient response rate.
Biosensor Based Clinical-decision Support For Patients With Heart Failure
Funder
National Health and Medical Research Council
Funding Amount
$691,933.00
Summary
Heart Failure (HF) is a progressive disease and a major global public health concern. HF accounts for a substantial number of hospitalisations, major healthcare resource utilisation and costs. We aim to engineer biosensor platform to stratify the risk in HF patients will revolutionise current management of HF by providing the cardiologist information to risk stratify patients based on protein signature. This will lead to a substantial paradigm shift in clinical practice.
Improving Clinical Outcomes Of Antimicrobial Resistant Infections With A Drug-free Intervention
Funder
National Health and Medical Research Council
Funding Amount
$999,581.00
Summary
Superbugs, or antimicrobial-resistant pathogens, cause recurring infections and non-healing wounds after surgery as existing therapies fail to effectively kill them. We will develop a medical device to fight superbugs with UV light that is effective against bacteria and fungi without causing harm to human cells. This could eradicate superbugs at infection sites, aid wound healing and actively improve health outcomes after surgery.
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.
A Suture-less Cannula For Rapid, Off-bypass Implantation Of Left Ventricular Assist Devices
Funder
National Health and Medical Research Council
Funding Amount
$816,491.00
Summary
Heart transplantation is the ideal treatment for 300,000 Australians living with chronic heart failure. The lack of donor hearts necessitates the use of implantable mechanical hearts; however, bleeding and blood clots are common due to outdated surgical tools, poor body-device integration and unnatural device blood flow. This project will address these limitations through the development of a rapid and safe implantation tool that integrates with the body and produces natural blood flow dynamics.