A modelling challenge: bridging the gap between molecular and neuronal networks. We will develop innovative frameworks, which unify small-scale molecular activity with electrical signals in branches of brain cells. This research aims to enhance our understanding how molecular scale phenomena influence brain disease, via studying the model dynamics using cutting-edge techniques on a supercomputer. The socio-economic benefits to Australia include: (i) Enhancing Australia's international reputation ....A modelling challenge: bridging the gap between molecular and neuronal networks. We will develop innovative frameworks, which unify small-scale molecular activity with electrical signals in branches of brain cells. This research aims to enhance our understanding how molecular scale phenomena influence brain disease, via studying the model dynamics using cutting-edge techniques on a supercomputer. The socio-economic benefits to Australia include: (i) Enhancing Australia's international reputation for cutting-edge multidisciplinary research; (ii) international collaborations will be strengthened; (iii) outcomes will potentially lead to commercialisation opportunities; (iv) results will ultimately lay the foundations to explore the cellular and molecular origin of brain disorders.Read moreRead less
DNA Dynamics is Shear and Extensional Flows: Simulation and Single Molecule Experiments. The proposal seeks to establish a collaboration between Monash University and Stanford University in order to combine several recent experimental and theoretical advances that have been made by the individual groups in single molecule experimental techniques, extensional rheometry, and molecular rheology, to obtain new insights into the structure and dynamics of biopolymers. The central aim is to make a sign ....DNA Dynamics is Shear and Extensional Flows: Simulation and Single Molecule Experiments. The proposal seeks to establish a collaboration between Monash University and Stanford University in order to combine several recent experimental and theoretical advances that have been made by the individual groups in single molecule experimental techniques, extensional rheometry, and molecular rheology, to obtain new insights into the structure and dynamics of biopolymers. The central aim is to make a significant contribution towards bringing state-of-the-art techniques used for the characterization of polymeric systems to bear on the nature and origin of the elastic properties of biopolymers.Read moreRead less
The flow properties of proteins and other biopolymers. The living cell is an extraordinary organization with a vast variety of biomacromolecules carrying out myriads of functions with great specificity and accuracy. The key issue in cell biology is to unravel the structures of biopolymers and the deep connection that exists between structure and function. This interdisciplinary research program combines recent advances in experimental and theoretical rheology, with advances in protein science, t ....The flow properties of proteins and other biopolymers. The living cell is an extraordinary organization with a vast variety of biomacromolecules carrying out myriads of functions with great specificity and accuracy. The key issue in cell biology is to unravel the structures of biopolymers and the deep connection that exists between structure and function. This interdisciplinary research program combines recent advances in experimental and theoretical rheology, with advances in protein science, to investigate the response of biopolymers to deformation. This approach will lead to insights into the problem of protein folding, the interaction of biopolymers with surfaces, and the physical basis for the mechanical properties of biopolymers.Read moreRead less
Novel RF Controlled Electromechanical Microvalve. The significance of the proposed microvalve is its potential use in exciting biomedical applications such as in drug delivery and fertility control. For human body implantation, it must be batteryless, wireless and be made of a biofriendly-polymer. We propose to meet all three criteria, based on novel use of surface acoustic waves (SAWs) as the actuation mechanism in a polymer material. Energy for actuation will be supplied by a radio frequency ( ....Novel RF Controlled Electromechanical Microvalve. The significance of the proposed microvalve is its potential use in exciting biomedical applications such as in drug delivery and fertility control. For human body implantation, it must be batteryless, wireless and be made of a biofriendly-polymer. We propose to meet all three criteria, based on novel use of surface acoustic waves (SAWs) as the actuation mechanism in a polymer material. Energy for actuation will be supplied by a radio frequency (RF) signal. We propose to model, design and demonstrate the device in laboratory conditions. This will enable development of application specific designs in future programs, such as ARC linkage.Read moreRead less
Wireless microvalve for biomedical applications. This program will investigate and perform an in-laboratory proof-of-concept demonstration of a polymer microvalve that can operate by a remote control radio signal. This will be a wireless microvalve that does not require a battery power source. This advance in the technology and scientific knowledge will have important applications for humankind ranging from drug delivery devices to through to valves in chips that can perform microfluidic chemica ....Wireless microvalve for biomedical applications. This program will investigate and perform an in-laboratory proof-of-concept demonstration of a polymer microvalve that can operate by a remote control radio signal. This will be a wireless microvalve that does not require a battery power source. This advance in the technology and scientific knowledge will have important applications for humankind ranging from drug delivery devices to through to valves in chips that can perform microfluidic chemical analysis. A far reaching long-range vision is its use in electronically reversible male fertility control. The community benefit in terms of novel biomedical devices and the resulting large international commercial market is significant.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775679
Funder
Australian Research Council
Funding Amount
$700,000.00
Summary
Advanced Microscopy Infrastructure for use in Frontier Technologies. This proposal seeks to establish key microscopy facilities to support the research projects from leading researchers from four major Universities. The new facilities build on the close collaborative links between the partner organisations and the request is for specialised equipment that is complementary to that available at, for example, the Australian Synchrotron. The new facilities will enhance progress in the the important ....Advanced Microscopy Infrastructure for use in Frontier Technologies. This proposal seeks to establish key microscopy facilities to support the research projects from leading researchers from four major Universities. The new facilities build on the close collaborative links between the partner organisations and the request is for specialised equipment that is complementary to that available at, for example, the Australian Synchrotron. The new facilities will enhance progress in the the important areas of nanotechnology, biotechnology and advanced materials to the benefit of the community and will play a crucial role in training the next generation of researchers to drive these critical areas of science and technology.Read moreRead less
TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, t ....TeraHertz Cell Cluster Imaging. With this program, Australia will benefit from the interaction between physics, engineering, biology and medicine to develop a new TeraHertz imaging system. The project will identify the factors that contribute to TeraHertz contrast in soft tissue cell cultures, thereby developing a non-invasive imaging system to show contrast between diseased and healthy cells. This is a fundamental step towards a system for diagnosing disease states of skin cells, for example, the early detection of melanoma. Ultimately, Australia will benefit from a new technology, and new diagnostic biomedical techniques, for rapid, non-invasive and reliable skin cancer diagnosis.Read moreRead less
Computer simulation techniques to reduce the incidence of femoral fracture after hip replacement surgery. Australia's ageing population is driving an increase of 5% to 10% a year in the number of primary total hip replacements. We will move beyond conventional surgical techniques, to deliver the science for an accurate, reliable computer-based system that is significantly more accurate and reliable. Optimising implant selection criteria to better match patients' activity levels and bone physiolo ....Computer simulation techniques to reduce the incidence of femoral fracture after hip replacement surgery. Australia's ageing population is driving an increase of 5% to 10% a year in the number of primary total hip replacements. We will move beyond conventional surgical techniques, to deliver the science for an accurate, reliable computer-based system that is significantly more accurate and reliable. Optimising implant selection criteria to better match patients' activity levels and bone physiology and minimise revision rates; this has major implications for the national health budget and patients' quality of life. Our advances will allow the implementation of improved surgical techniques that minimise the risk of implant related bone failure.Read moreRead less
Theoretical and experimental studies on magnetoelectroelastic bone remodelling process. The project combines biotechnology and material science which will have national economic, social and environment impact. It can benefit industry by providing knowledge that help scientists understand remodeling under coupled fields and is used to develop bone replacement. By better understanding remodeling due to multi-field loading, we can assist scientists in aeronautical industry in developing countermeas ....Theoretical and experimental studies on magnetoelectroelastic bone remodelling process. The project combines biotechnology and material science which will have national economic, social and environment impact. It can benefit industry by providing knowledge that help scientists understand remodeling under coupled fields and is used to develop bone replacement. By better understanding remodeling due to multi-field loading, we can assist scientists in aeronautical industry in developing countermeasures that reduce or eliminate bone loss resulting from long-duration space flight. It can provide knowledge that can be used to explore underlying mechanisms controlling bone remodeling and self-repair in gaining insight into debilitating diseases such as osteoporosis, to develop high-performance prosthetics for medical injury healing.Read moreRead less
Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applic ....Characterization and optimisation of Myomatrix: A novel extracellular matrix hydrogel from muscle. This project would have several sources of benefit for the community. Foremost we will have produced a product that will have a strong commercial application in several fields including basic science and bioengineering. If its full potential were achieved, the development of this innovative new hydrogel would strengthen Australia's standing in the biotechnology field and also enrich specific applications. The knowledge gained from the characterization of this product could also be of benefit to several areas including chemical engineering, tissue engineering, tissue repair, polymer chemistry and food manufacture. The expertise generated and the possibility of collaboration, both academic and with industry would also benefit the community. Read moreRead less