Improving Cancer Therapy: Nanoparticle Delivery Of SiRNA To Cancer Cells
Funder
National Health and Medical Research Council
Funding Amount
$610,499.00
Summary
Lung cancer accounts for 8000 diagnosis and 1000 deaths in Australia each year. We are using cutting edge nanotechnology and coupling this with potent gene silencing to target solid tumours of the lung. If successful, this approach could increase survival of patients with this difficult to treat malignancy and may prove valuable in the treatment of other lung tumours.
Novel Single-chain Antibody-targeted Nanoparticles For Diagnosis Of Vascular Diseases In Magnetic Resonance Imaging
Funder
National Health and Medical Research Council
Funding Amount
$460,797.00
Summary
The aim of this project is to develop targeted imaging agents that seek out specific markers for various states of cardiovascular disease. These agents would provide a method for detecting the presence and level of atherosclerosis and thrombotic events. The targeted nanoparticles may provide a unique opportunity to detect very early plaques, the vulnerability of existing plaques and difficult to diagnose vessel blockages such as pulmonary embolism.
Optical Vortices For Trapping And Guiding Nanoparticles In Air
Funder
National Health and Medical Research Council
Funding Amount
$500,685.00
Summary
A serious challenge for environmental protection in the fast-growing nanotechnology industry is the development of new methods for effective removal of nanoparticle contamination, which may pose hazards to humans, from air. We will develop new laser-based methods for effective capture and removal of nanoparticulate pollutants from air, which will find wide-spread application in developing ecologically clean and health-safe environments for the Australian and world-wide nanotechnology industry.
Non-viral Vectors For Targeted Delivery Of RNAi Nucleotides To Cervical Cancers
Funder
National Health and Medical Research Council
Funding Amount
$415,738.00
Summary
RNA interference (or gene silencing) is a new technique whereby we are able to turn off the expression of a particular gene either temporarily or permanently. Cancer is basically a genetic disease where certain protective genes are lost or cancer-causing genes expressed. Gene silencing holds great promise in the treatment of genetic disorders, infectious diseases and cancer. Cervical cancer is caused by infection with the human papillomavirus and the expression of two cancer-causing genes. Using ....RNA interference (or gene silencing) is a new technique whereby we are able to turn off the expression of a particular gene either temporarily or permanently. Cancer is basically a genetic disease where certain protective genes are lost or cancer-causing genes expressed. Gene silencing holds great promise in the treatment of genetic disorders, infectious diseases and cancer. Cervical cancer is caused by infection with the human papillomavirus and the expression of two cancer-causing genes. Using RNA interference we can turn off the expression of these two genes which results in the death of the cancer cell. We are also able to cure mice of tumours derived from human cervical cancer. The major issue with gene silencing is how to deliver it effectively to patients. Here we are investigating novel nanoparticulate systems to deliver this new gene-inhibiting drugs preferentially to the tumour site.Read moreRead less
Melanoma Genetics: Clinical Translation Of The Germline-somatic Continuum
Funder
National Health and Medical Research Council
Funding Amount
$2,231,372.00
Summary
While new targeted and immune therapies can improve prognosis from metastatic melanoma, long-term survival for most patients remains elusive due to drug resistance or failure of the immune system to kill the tumour. There thus remains a significant need to improve early detection, monitoring of relapse, and treatment strategies, to increase survival and provide cures. My research vision addresses these three pillars of cancer research using innovative and cutting edge genetic approaches.
Translation Of Genomic Findings To Improve Outcomes In Patients With Myeloid Blood Cancers
Funder
National Health and Medical Research Council
Funding Amount
$1,913,403.00
Summary
Changes within the DNA of blood cancer cells are responsible for causing cancer, but also control the progression through various stages of blood cancers and regulate the response of patients to treatment. It is fundamentally important to not only understand these genetic changes at the molecular level, but also to use these findings to rationally design clinical treatments that target these genetic changes to improve outcomes for patients with blood cancers.
Therapeutic Induction Of Tertiary Lymph Nodes In Cancer
Funder
National Health and Medical Research Council
Funding Amount
$995,010.00
Summary
Immunotherapy has been an important recent advance in cancer treatment by using the body's own immune cells to fight cancer. Although there have been unprecedented dramatic results, not all patients benefit, and most benefits are temporary. The cellular environment in which cancers are embedded is crucial for controlling treatment success. We aim to apply novel 'precision' therapies to this environment to expose the cancer and enable attack by immune cells for improved immunotherapy.
There is a need to improve early detection, monitoring of relapse, and treatments for melanoma, to increase long-term survival. My research vision is to use innovative and cutting edge approaches to conduct a range of complementary studies under three broad but inter-related themes: Theme 1 – Genetic predisposition to melanoma in the general population; Theme 2 – Genetic predisposition to melanoma in high-density families; Theme 3 – Somatic aberrations underlying melanoma development.
Developing Smart Nanomedicine To Enable Advanced Diagnosis And Stimuli-responsive Treatment For Atherosclerosis And Thrombosis
Funder
National Health and Medical Research Council
Funding Amount
$523,342.00
Summary
The early detection and accurate characterization of life-threatening diseases such as cardiovascular diseases are critical to the design of treatment. A therapeutic approach that provides an efficient treatment with minimal side-effects is highly desired by both patients and healthcare systems. This project aims to develop smart nanomedicine with incorporated diagnostic sensor and external stimuli-responsive treatment mechanisms for cardiovascular diseases.