Breakthrough technologies in implantable bionics. This project aims to introduce revolutionary changes in implantable bionics via miniaturisation, automation and improved reliability and generating new knowledge by leveraging recent advances in laser processes. Expected outcomes include innovative hybrid thin-film/thick-film electrode arrays with more channels and charge-carrying capacity for neuromodulation; novel glass interfaces that facilitate deeply-miniaturised hermetic packages; and failu ....Breakthrough technologies in implantable bionics. This project aims to introduce revolutionary changes in implantable bionics via miniaturisation, automation and improved reliability and generating new knowledge by leveraging recent advances in laser processes. Expected outcomes include innovative hybrid thin-film/thick-film electrode arrays with more channels and charge-carrying capacity for neuromodulation; novel glass interfaces that facilitate deeply-miniaturised hermetic packages; and failure analysis to ensure study aims result in new processes that are as or more reliable than the current state-of-the-art. This work will create new and novel manufacturing processes, and trains the next generation of innovators equipped with the tools to advance implantable bionics into the future.Read moreRead less
Characterization, modelling and control for robotic thermal ablation. This project aims to study the fundamental issues in robotic-assisted minimally invasive thermal ablation, an important therapy for patients with cancer. It aims to establish advanced characterisation and modelling methodologies for thermomechanical behaviours of soft tissues, together with automatic planning and precise manipulation control techniques for robotic thermal ablation therapies. The project will establish new know ....Characterization, modelling and control for robotic thermal ablation. This project aims to study the fundamental issues in robotic-assisted minimally invasive thermal ablation, an important therapy for patients with cancer. It aims to establish advanced characterisation and modelling methodologies for thermomechanical behaviours of soft tissues, together with automatic planning and precise manipulation control techniques for robotic thermal ablation therapies. The project will establish new knowledge and instrumentation for robotic-assisted thermal ablation and minimally invasive surgery. The outcomes of this project will produce important benefits to medicine, healthcare and medical technology industry, and further consolidate Australia’s position in innovative technologies and research and development of advanced healthcare systems and instruments.Read moreRead less
Robotic microsurgery: intra-operative measurement, modelling and micromanipulation control. This research will significantly improve microsurgery and minimally invasive surgery techniques, and further produce important benefits to medicine and healthcare. The project will also open new domains in the capabilities of modelling and control of complex systems with significant impact and benefits to numerous science and engineering practices.
Discovery Early Career Researcher Award - Grant ID: DE180100688
Funder
Australian Research Council
Funding Amount
$336,446.00
Summary
Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected t ....Nanosensors in artificial cochlea for natural hearing. This project aims to develop a miniaturised and implantable cochlear that closely mimics the human auditory system by utilising advanced microfabrication techniques. This project expects to generate new knowledge in engineering hearing and vestibular hair cells and also on tonotopic organisation of cochlear. Expected outcomes include study of auditory hair cells and development of implantable ear-on-a-chip devices. This project is expected to enable low-cost production of highly engineered implant cochlear with great potential for commercialisation.Read moreRead less
Mechanics of innovative high precision rolling technology in micromanufacturing. This project will focus on the establishment of high precision rolling technology for manufacturing microparts in Australia by using a unique profile and flexible rolling method. A successful outcome will provide an important breakthrough in the microrolling area and new knowledge for advanced micromanufacturing technology and its applications.
Scaling manufacture of three-dimensional microstructures for the medical devices industry. Scaling manufacture of three-dimensional microstructures for the medical devices industry. This project aims to transform microscale three-dimensional prototyping into a cheap high volume manufacturing process through a novel soft embossing process. Although three-dimensional printing has been hailed as a disruptive technology, because it can print complex shapes directly from drawings, it is too slow at m ....Scaling manufacture of three-dimensional microstructures for the medical devices industry. Scaling manufacture of three-dimensional microstructures for the medical devices industry. This project aims to transform microscale three-dimensional prototyping into a cheap high volume manufacturing process through a novel soft embossing process. Although three-dimensional printing has been hailed as a disruptive technology, because it can print complex shapes directly from drawings, it is too slow at microscale for high volume manufacture. This research will develop microdevices for painless collection of blood, its analysis, and drug delivery. Cost-effective manufacture of these microdevices is expected to tap into the large medical devices industry, leading to establishing new businesses in the point-of-care and drug delivery markets.Read moreRead less
Mechanical advantage: biomimetic artificial muscles for micro-machines. This project will develop better ways to operate miniature machines by copying the way that muscle operates in Nature. The outcome will be important for portable devices like digital cameras that need small, efficient motors. The artificial muscles developed in this project may also be used in medical prosthetics and more agile robots.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100036
Funder
Australian Research Council
Funding Amount
$310,000.00
Summary
Super high speed grinding facility for difficult-to-machine materials and structures. This unique system will enable the manufacture of difficult-to-machine materials and structures with high quality and high productivity. It will support ground-breaking research activities across the country and help promote the strategic collaborations within Australian manufacturing society.