Magnetic Resonance Imaging in Inhomogeneous Magnetic Fields-Part A: The Development of Imaging Methods Using Even Order Zonal Fields. Part B: Slice Correction Due to Non-linear Gradient Fields. The primary aims of this project are to contribute to the new generation of MRI methodologies through technical innovation, with particular emphasis on NMR imaging under inhomogeneous magnetic fields. The new techniques will be of enormous benefit for superconducting magnet design, reducing material usage ....Magnetic Resonance Imaging in Inhomogeneous Magnetic Fields-Part A: The Development of Imaging Methods Using Even Order Zonal Fields. Part B: Slice Correction Due to Non-linear Gradient Fields. The primary aims of this project are to contribute to the new generation of MRI methodologies through technical innovation, with particular emphasis on NMR imaging under inhomogeneous magnetic fields. The new techniques will be of enormous benefit for superconducting magnet design, reducing material usage, and eliminating the need for the expensive post-production shimming process. The entailed project is extremely challenging, while preliminary calculations presented in this application show some progress towards demonstration of feasibility. The program is an ambitious one with a full R&D program over 3 years, which will provide leadership, and to both foster and focus research interest in Australian engineering and scientific endeavors in the field of Magnetic Resonance technology.Read moreRead less
High Field Magnetic Resonance Engineering. The use of high resolution MRI is increasingly important in the quest for molecular imaging and the development of a range of gene therapies, stem cell research and the trialling of new drugs. This research will add momentum to Australia's health technology research community with positive impact on its international research and development profile. Successful outcomes will improve both the applicability and cost-effectiveness of numerous current and ....High Field Magnetic Resonance Engineering. The use of high resolution MRI is increasingly important in the quest for molecular imaging and the development of a range of gene therapies, stem cell research and the trialling of new drugs. This research will add momentum to Australia's health technology research community with positive impact on its international research and development profile. Successful outcomes will improve both the applicability and cost-effectiveness of numerous current and potential medical and non-medical imaging systems with subsequent potential for improved diagnosis in the biotech and health sectors in Australia and overseas. Successful outcomes will provide economic returns through licensing payments from the generated intellectual property.Read moreRead less
Transceive Phased Arrays for Parallel Imaging in High Field Magnetic Resonance Microscopy. This project will contribute to the development of a new generation of Magnetic Resonance Imaging systems that provide new and innovative features capable of significantly increasing the resolution and /or speed of imaging. The economic benefit of being a developer of this technology is clear and significant. These new systems will enhance the efficiency and power of clinical diagnostic testing. Specifica ....Transceive Phased Arrays for Parallel Imaging in High Field Magnetic Resonance Microscopy. This project will contribute to the development of a new generation of Magnetic Resonance Imaging systems that provide new and innovative features capable of significantly increasing the resolution and /or speed of imaging. The economic benefit of being a developer of this technology is clear and significant. These new systems will enhance the efficiency and power of clinical diagnostic testing. Specifically, the enabling of molecular imaging will enhance the study of many more disease states and rapid assessment of new in vivo therapeutic agents. The side-stream benefit to biomedical research and development in Australia is therefore substantial. Read moreRead less
Advanced MRI Engineering. Magnetic Resonance Imaging is rapidly becoming the medical imaging modality of choice for soft tissue injuries. The technology development of MRI, however, is relatively young with only 20 years or so of commercial development. The major aim of this project is to contribute to this and the next generation of MRI scanners through technical innovation. New engineering design methods will be developed and used to generate novel superconducting magnet systems and associated ....Advanced MRI Engineering. Magnetic Resonance Imaging is rapidly becoming the medical imaging modality of choice for soft tissue injuries. The technology development of MRI, however, is relatively young with only 20 years or so of commercial development. The major aim of this project is to contribute to this and the next generation of MRI scanners through technical innovation. New engineering design methods will be developed and used to generate novel superconducting magnet systems and associated equipment. A strong focus of the design work will be to include electromagnetic models of the patient in the equipment design. This will not only ensure improved accuracy and speed of MRI scans, but also better patient safety, comfort and clinician access.Read moreRead less
Solutions for reducing magnetic resonance image degradations and tissue heating at high frequencies. This project will contribute to the development of the high-end Magnetic Resonance Imaging (MRI) systems that can substantially improve the image quality, speed of imaging and patient safety in MRI. The project will develop innovative high radio frequency hardware and control methods for imaging. Successful outcomes of this project will, facilitate higher patient throughput in hospitals, provisi ....Solutions for reducing magnetic resonance image degradations and tissue heating at high frequencies. This project will contribute to the development of the high-end Magnetic Resonance Imaging (MRI) systems that can substantially improve the image quality, speed of imaging and patient safety in MRI. The project will develop innovative high radio frequency hardware and control methods for imaging. Successful outcomes of this project will, facilitate higher patient throughput in hospitals, provision of more powerful clinical imaging tools to aid early diagnosis and various research modalities ranging from molecular to real-time imaging during interventional procedures.Read moreRead less
Biomechanical model-based algorithms for computational radiology of the brain. The proposed research will develop computational framework, which will allow matching high quality pre-operative brain images with lower resolution images taken during neurosurgery. The success of this work will greatly improve effectiveness of brain tumour removal, and therefore improve clinical outcomes. The proposed work will provide enabling technology for other areas of computer aided medicine, such as virtual re ....Biomechanical model-based algorithms for computational radiology of the brain. The proposed research will develop computational framework, which will allow matching high quality pre-operative brain images with lower resolution images taken during neurosurgery. The success of this work will greatly improve effectiveness of brain tumour removal, and therefore improve clinical outcomes. The proposed work will provide enabling technology for other areas of computer aided medicine, such as virtual reality operation planning systems with realistic force and tactile feedback, control systems of neurosurgical robots with tissue deformation prediction module, etc.Read moreRead less
Towards Consistent Meshless Computational Framework for Soft Tissue Damage Modelling for Traumatic Injury Prevention and Surgery Simulation. Deaths and injuries due to car crashes cost our society $18 billion per annum. This project will provide enabling computer simulation technology for reducing this cost by improving car crash safety through more accurate evaluation of injury risk as well as by reducing the risk of adverse effects in surgical procedures through better surgical training and su ....Towards Consistent Meshless Computational Framework for Soft Tissue Damage Modelling for Traumatic Injury Prevention and Surgery Simulation. Deaths and injuries due to car crashes cost our society $18 billion per annum. This project will provide enabling computer simulation technology for reducing this cost by improving car crash safety through more accurate evaluation of injury risk as well as by reducing the risk of adverse effects in surgical procedures through better surgical training and surgery planning. We will deliver this technology by creating a computational framework for modelling of soft tissue damage due to traumatic rupture and surgical dissection. This framework will enable building accurate computer models of the human body injury responses for safe car design as well as models for assisting surgeons by predicting forces and deformations in tissue dissection.Read moreRead less
Biomechanics of Needle Insertion. Needle insertion is one of the most common neurosurgical procedures. However, the biomechanics of this process is poorly understood. The unknown factors include brain tissue deformation under load imposed by the needle and needle deflection when penetrating brain tissue. We will develop computational models of needle insertion. They will include non-linear material properties of the brain tissue, large deformations, and needle-tissue contact model including fric ....Biomechanics of Needle Insertion. Needle insertion is one of the most common neurosurgical procedures. However, the biomechanics of this process is poorly understood. The unknown factors include brain tissue deformation under load imposed by the needle and needle deflection when penetrating brain tissue. We will develop computational models of needle insertion. They will include non-linear material properties of the brain tissue, large deformations, and needle-tissue contact model including friction. The Japanese group will develop testing methods to validate mathematical models. Experimental set-up includes bi-axial x-ray to measure deformation within the tissue and needle deflection, and a sensor measuring reaction force on needle tip and friction force on needle sides.Read moreRead less
Soft carbon nanotube materials. There is no doubt that the realisation of new bionic materials will dramatically improve quality of life for many individuals. The new soft conducting materials proposed will impact on several areas of bionics, including the development of the next generation Bionic Ear, conduits for spinal cord regeneration as well as muscle regeneration and other applications. This project will further enhance the international profile of the ARC Centre of Excellence for Electro ....Soft carbon nanotube materials. There is no doubt that the realisation of new bionic materials will dramatically improve quality of life for many individuals. The new soft conducting materials proposed will impact on several areas of bionics, including the development of the next generation Bionic Ear, conduits for spinal cord regeneration as well as muscle regeneration and other applications. This project will further enhance the international profile of the ARC Centre of Excellence for Electromaterials Science in the field of Bionics. The end-user network already in place will ensure all opportunities are fully exploited.Read moreRead less
Real Time Computer Simulation of Human Soft Organ Deformation for Computer Assisted Surgery. The proposed research will develop computational framework, which will allow calculation of soft organ (brain, liver, kidney, prostate, etc.) deformation during surgical operations in real time. Fully non-linear material models and geometrically non-linear finite element formulation will be used. The fundamental technology developed within this project: physically (or mechanically) realistic modelling an ....Real Time Computer Simulation of Human Soft Organ Deformation for Computer Assisted Surgery. The proposed research will develop computational framework, which will allow calculation of soft organ (brain, liver, kidney, prostate, etc.) deformation during surgical operations in real time. Fully non-linear material models and geometrically non-linear finite element formulation will be used. The fundamental technology developed within this project: physically (or mechanically) realistic modelling and real time computer simulation of soft organ deformation, will have applications in many areas of computer assisted surgery, such as intra-operative, real time non-rigid registration and virtual reality surgeon training and operation planning systems with force and tactile feedback.Read moreRead less