In this fellowship I will develop methods to improve the way drugs are delivered through the use of nanotechnology. Nanoparticles can be used to protect delicate drugs from degrading, and to make sure drugs are delivered where they are required. This helps to lower side effects and improve efficacy of a range of drugs. I lead a multi-disciplinary research team dedicated to understanding of how nanoparticles interact with biological systems, so we can engineer better drug delivery systems.
Improving Therapeutic Delivery By Understanding Nanoparticle Interactions With Cells
Funder
National Health and Medical Research Council
Funding Amount
$553,152.00
Summary
Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate how nanoengineered particles can be used to improve the effectiveness of vaccines. Nanoparticles can protect the delicate vaccine cargo from degradation, and will be targeted specifically to the cells in the body that most effectively induce the maximum theraputic response. This study will improve our understanding of how nanovaccines work and develop new ways of delivering vaccines.
Understanding The Cellular Processing Of Targeted Nanoparticles For Improved Therapeutic Outcomes
Funder
National Health and Medical Research Council
Funding Amount
$625,477.00
Summary
Nanotechnology has the potential to transform the way we treat many diseases. This project will investigate how nanoengineered particles can be used to improve the effectiveness of vaccines. Nanoparticles can protect the delicate vaccine cargo from degradation, and will be targeted specifically to the cells in the body that most effectively induce the maximum theraputic response. This study will improve our understanding of how nanovaccines work and develop new ways of delivering vaccines.
Photonic Crystals For Probing Enzyme Activity: Single Cells Vs Bulk Measurements
Funder
National Health and Medical Research Council
Funding Amount
$320,891.00
Summary
We are all unique and we are unique down to a single cell. Can we understand the behaviour of a single cell? A novel biosensing platform will be developed to detect biological activity of single cells by simple measurement of a colour change. Successful fabrication of this biosensor will aid in the development of diagnostic devices for predictive and preventive medicine.
Using Nanotechnology To Improve The Therapeutic Efficacy Of Iron Chelators
Funder
National Health and Medical Research Council
Funding Amount
$692,769.00
Summary
Iron loading disorders (such as thalassaemia) represent an important class of human disease. As part of the treatment for these diseases, the iron needs to be removed and this is often done using iron-binding drugs known as iron chelators. Current chelators are not ideal due to side effects or onerous delivery methods. The goal of this project is to use nanotechnology to develop more effective ways of delivering chelators to improve their effectiveness and reduce toxicity.
Platform Nanotechnologies For Oral Delivery Of Drugs, Therapeutic Protein And Peptide Delivery
Funder
National Health and Medical Research Council
Funding Amount
$437,034.00
Summary
The development of reliable oral delivery systems for problem drugs and biologics is one of the biggest challenges faced by the pharmaceutical industry in recent times. In order to tackle these challenges, I have developed programmable nanoparticles capable of efficiently deliver wide range of drugs including large peptides and proteins orally.
A Nanomedicine Strategy For Detecting And Modulating Protease Activity In Vivo
Funder
National Health and Medical Research Council
Funding Amount
$455,534.00
Summary
Protease enzymes are vitally important for normal bodily function but can play a deleterious role in many diseases such as cancer, aging diseases and eye diseases. The proposed research will provide a nanomedicine solution to the detection and therapeutic control of protease activity in vivo using nanoporous optical devices that are benign to the body. This general strategy for will be demonstrated in eyes with a view to detection and treating the eye disease uveitis.
Visualisation And Early Prediction Of ROS-mediated Treatment Response In Liver Cancer By A Novel Nanoplatform
Funder
National Health and Medical Research Council
Funding Amount
$334,224.00
Summary
Change of tumour microenvironment has potential to serve as an early predictor of drug efficacy. This proposed project aims to develop a new technology to accurately measure tumour microenvironment during treatment, and to explore the correlation between this potential predicator and tumour growth. This technology would significantly improve the patient prognosis by revealing non-response to chemotherapeutics early and allowing the timely administration of alternative therapies.
Anti-metastasis Therapy Via Nanoparticle Mediated Drug Delivery
Funder
National Health and Medical Research Council
Funding Amount
$835,199.00
Summary
Most cancer deaths are caused by tumours that have spread to other vital organs, a process called metastasis. The common treatment for metastatic disease is chemotherapy, but the amount given is limited by toxicity to the patient. In this project, we are developing a way of delivering the therapies only to tumour cells, thereby sparing normal tissues. We are using nanoparticles that have a molecule on their surface that directs the therapy directly to tumour cells.
Design And Application Of New Nanomaterials Theranostic Platforms For Targeted Treatment Of Cancer
Funder
National Health and Medical Research Council
Funding Amount
$530,626.00
Summary
The project aims to develop intelligent drugs that attract to malignant tumors like magnets. These powerful, next-generation chemotherapy drugs seek out cancerous cells, allowing physicians to see exactly where tumours lie. Nanoparticles inside the drugs then switch on upon contact with X-ray radiation beams. This new method, which can diagnose, deliver targeted therapy and monitor the response to therapy all at the same time, would reduce the amount of radiation needed to kill cancer cells.