Development And Pre-clinical Evaluation Of G-DSF Inhibitors For Inflammatory Joint Disease
Funder
National Health and Medical Research Council
Funding Amount
$88,329.00
Summary
G-CSF was originally identified as a cytokine regulating the production of neutrophils and haemopoietic stem cells from the bone marrow and it is currently used clinically for these properties in bone marrow transplant patients around the world. Anti-cytokine therapy with TNF blockade has recently been introduced for the treatment of rheumatoid arthritis. However, not all patients respond to TNF inhibition. We have gathered extensive data which shows that G-CSF also promotes inflammation in expe ....G-CSF was originally identified as a cytokine regulating the production of neutrophils and haemopoietic stem cells from the bone marrow and it is currently used clinically for these properties in bone marrow transplant patients around the world. Anti-cytokine therapy with TNF blockade has recently been introduced for the treatment of rheumatoid arthritis. However, not all patients respond to TNF inhibition. We have gathered extensive data which shows that G-CSF also promotes inflammation in experimental models of inflammatory joint disease. We propose to develop inhibitors of G-CSF as a novel form of anti-cytokine therapy for inflammatory joint disorders, such as rheumatoid arthritis.Read moreRead less
Development Of A Humanised Antibody For Treatment Of Cancer And Stroke
Funder
National Health and Medical Research Council
Funding Amount
$400,142.00
Summary
The protein PDGF-CC has a critical role in blood vessel development, and is implicated in the development of cancer, and the debilitating consequences of acute stroke. Researchers in the Ludwig Institute for Cancer Research have developed novel anti-PDGF-CC antibodies. The research program proposed will generate data and clinical reagents that will enable a lead candidate anti-PDGF-CC antibody to be commercialised, and ultimately evaluated clinically in cancer and stroke patients.
Development Of Novel Anti-epileptic Drugs Targeting Vesicular Endocytosis
Funder
National Health and Medical Research Council
Funding Amount
$202,950.00
Summary
Our team developed a drug program targeting a novel mechanism for epilepsy treatment, neuronal synaptic vesicle endocytosis. This project will develop the most promising series of drugs. Preclinical development is advanced, lacking only efficacy data across models predictive of the spectrum of human epilepsies to enable candidate selection for clinical trials. The program will advance a totally new concept for the treatment of epilepsy.
Novel System For Non-Invasive Delivery Of Drugs To The Interior Of The Eye
Funder
National Health and Medical Research Council
Funding Amount
$200,213.00
Summary
Age-related macular degeneration (AMD) is the leading cause of visual loss for adults in the developed world. Treatment is now by needle injection into the back of the eye, which is painful for the patient and is costly for the health-care system. Seagull Technology Pty Ltd has developed a non-invasive device for treating the back of the eye without the need for a needle injection. This project will test the new device in animals and then move to a first safety study for human AMD patients.
Production Of Chimeric Monoclonal Antibodies To Pim1, A Novel Therapeutic Target For Cancer Treatment
Funder
National Health and Medical Research Council
Funding Amount
$188,850.00
Summary
Almost one in six men will develop prostate cancer during his lifetime. Every year, around 10,000 Australian men are diagnosed and more than 2,500 die of the disease, making prostate cancer the second largest cause of male cancer deaths after lung cancer. The research progress made on prostate cancer over the past 10 years has been encouraging. However the five-year survival rate remains low. There is a vital need to develop new methods to treat this disease. An exciting principle has emerged re ....Almost one in six men will develop prostate cancer during his lifetime. Every year, around 10,000 Australian men are diagnosed and more than 2,500 die of the disease, making prostate cancer the second largest cause of male cancer deaths after lung cancer. The research progress made on prostate cancer over the past 10 years has been encouraging. However the five-year survival rate remains low. There is a vital need to develop new methods to treat this disease. An exciting principle has emerged recently with the use of monoclonal antibodies (Mabs) such as Herceptin (a humanised anti-HER2 Mab), which is now being widely used to treat breast cancer. We produced 2 Mabs to Pim1, which significantly inhibited prostate cancer cell growth in mouse prostate cancer model. Pim1 is a novel oncoprotein, a biomarker for the treatment of prostate cancer as it overexpresses in more than 90% of prostate cancer, but not or less expressed in normal prostate, demonstrated by genearrays and immunohistochemical staining. Pim1 plays an important role in cell survival, proliferation and metastasis. Pim1 is a novel target, and the anti-Pim1 Mabs may be of value for the cancer therapy in humans. However, the murine Mab can not be repeatedly used in human because human would produce anti-mouse antibody response, and the murine Mab would be rapidly removed from circulation, which will greatly limit the therapeutic potential of the Mabs. Fortunately, the problem can be overcome by the use of hybrid chimeric antibodies. In this study, we are going to use chimeric technology to humanise the anti-Pim1 Mab and test them in vitro and in mouse model for the preclinical studies. We have had patent to protect our finding, and we are confident to produce mouse-human chimeric Mab for the future clinical trial as we have proper knowledge, techniques. We are also optimic for the future clinical trial as we have the experiences on commercialisation.Read moreRead less
Commercial Testing Of A Physiologically Based Theory Of Oscillatory Brain Electrical Activity In Anaesthesia Monitoring
Funder
National Health and Medical Research Council
Funding Amount
$191,165.00
Summary
While the mechanisms of local anaesthesia are comparatively well known, the mechanisms whereby anaesthetics impair consciousness remain unresolved. This lack of understanding has implications in our ability to monitor the level of anaesthesia while anaesthetic consumption and side effects are minimized. Despite this a number of devices have been developed that attempt to monitor the depth of anaesthesia by quantifying the brains electrical activity. All monitors analyse the activity using a set ....While the mechanisms of local anaesthesia are comparatively well known, the mechanisms whereby anaesthetics impair consciousness remain unresolved. This lack of understanding has implications in our ability to monitor the level of anaesthesia while anaesthetic consumption and side effects are minimized. Despite this a number of devices have been developed that attempt to monitor the depth of anaesthesia by quantifying the brains electrical activity. All monitors analyse the activity using a set of criteria that have been developed by trial and error. The research of Dr David Liley and his team, at Swinburne University of Technology, has resulted in a detailed understanding of the physiological mechanisms that generate brain electrical activity. The outcome is a practical means to carry out a System Based Analysis of Brain Electrical Response (SABER). In 2004, Dr Liley began working with Cortical Dynamics, a company involved in the commercialisation of medical devices. This collaboration incorporated the SABER system into a new prototype device called the Brain Anaesthesia Response (BAR) monitor. In 2004 Dr Liley and Associate Professor Kate Leslie collaborated in a trial, at the Royal Melbourne Hospital to test the sensitivity of the SABER system in quantifying the effect that various levels of nitrous oxide have on measures of anaesthetic depth. The Australian and New Zealand College of Anaesthetists supported this study. Initial results obtained with sevoflurane and 3 levels of nitrous oxide showed the ability to differentiate between conscious and unconscious states of patients based on two physiological characterizations of higher brain dynamic state. The next step requires commercial product validation (ie scale up) and further clinical efficacy in testing beta stage depth of anaesthesia BAR units. Completion of this will help the technology move away from a low volume prototype system into a commercially applicable device.Read moreRead less
Preterm birth is a major cause of neonatal death and cerebral palsy. This grant will provide proof-of-concept that a computer program can be developed to predict a pregnant woman�s risk of preterm birth. There is a large market (4M US and 8M Europe), there are no competing technologies. This is a unique collaboration between Biomedical Engineering and an Australian centre with an international reputation in preterm birth, assisted by a pathology company.