In-vivo functional imaging of cone photoreceptors and ganglion cell axons. Can we project a movie on a human retina, and measure the response of photoreceptor cells and connected nerve tissue? This project aims to investigate a new method for visualization of the quickest responses in human cone photoreceptors and nerve cells after a visible stimulus. Expected outcomes of this project include a better understanding of the origins of responses to a stimulus and how cells in the retina communicate ....In-vivo functional imaging of cone photoreceptors and ganglion cell axons. Can we project a movie on a human retina, and measure the response of photoreceptor cells and connected nerve tissue? This project aims to investigate a new method for visualization of the quickest responses in human cone photoreceptors and nerve cells after a visible stimulus. Expected outcomes of this project include a better understanding of the origins of responses to a stimulus and how cells in the retina communicate. The scientific results will be helpful in a better understanding of the development of vision in the infant eye, to study peripheral vision in elite athletes and to quantify performance of virtual reality equipment for the military. The IP on the technology can be licensed or used for start-up company.Read moreRead less
An Economical, Robust Alternative Braille Transcription Device. The Curtin University Brailler (CUB). Braille is an important language used by the blind to read and write and Braillers are needed for everyday communication. This justifies the development of a light weight, transportable unit that is accessible at all times. This project proposes a relatively inexpensive, light weight, reliable and easily maintained Braille transcription system. The significant aspects of the proposed brailler in ....An Economical, Robust Alternative Braille Transcription Device. The Curtin University Brailler (CUB). Braille is an important language used by the blind to read and write and Braillers are needed for everyday communication. This justifies the development of a light weight, transportable unit that is accessible at all times. This project proposes a relatively inexpensive, light weight, reliable and easily maintained Braille transcription system. The significant aspects of the proposed brailler include;
- An Electromagnetically compatable (EMC)12 Volt Power Supply allowing the common car battery as a backup power source.
- Use of modern plastics (PTFE) to reduce weight, maintenance and EMC standards.
- An embedded system for Forward and Back translation of literary Braille
- Protocol development and specification for USB keyboard and (standard) printer.Read moreRead less
Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential ....Magnetic Nanoparticles for Biomedical Applications. This project will develop biocompatible magnetic nanoparticles for future generations of therapeutic and diagnostic applications. Applications include the reduction in overall toxicity of chemo- and radio- therapy by magnetic target drug delivery, enhanced ability to detect and diagnose diseases using magnetic binding/sorting techniques and an enhanced ability to repair detached retinas. The development of these products provides the potential for the development of new commercial opportunities in biotechnology and biomedical science in which Australia has an excellent track record. The project will also enhance Australia's capabilities in both nanotechnologiocal and biotechnological sciences.Read moreRead less
Neuroimage as biomechanical model: new real-time computational biomechanics of the brain. This project is to extend to medicine the success computational mechanics has enjoyed in traditional engineering. The project will create enabling modelling and computing technologies for Computer-Integrated Surgery Systems that could help to improve clinical outcomes and the efficiency of health care delivery.