Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the dev ....Novel manufacturing methods for tissue engineering scaffolds. Novel methods of manufacturing biodegradable polymer scaffolds around which new tissue can be grown within the human body will be developed. Surfactant - polymer assemblies will be used to produce highly porous scaffolds of tunable pore size and connectivity, shape and strength. The results will create a new avenue for systematic investigations into the effects of scaffold structure on tissue growth. This research will lead to the development of reliable, well-controlled manufacturing techniques for tissue engineering scaffolds, revolutionising current scaffold manufacturing practices. It will enhance existing collaborations between the University of Melbourne and the Bernard O'Brien Institute of Microsurgery.Read moreRead less
Modelling of neural plasticity for enhanced performance of brain-machine interfaces. Plasticity of the brain is one of the great scientific challenges of neuroscience. The aim of this project is to model the synaptic changes that occur with reward-modulated spike-timing-dependent plasticity and apply the model to developing plasticity targeted brain-machine interfaces. The significance of this approach is that such plasticity targeted techniques provide the prospect of taking advantage of the un ....Modelling of neural plasticity for enhanced performance of brain-machine interfaces. Plasticity of the brain is one of the great scientific challenges of neuroscience. The aim of this project is to model the synaptic changes that occur with reward-modulated spike-timing-dependent plasticity and apply the model to developing plasticity targeted brain-machine interfaces. The significance of this approach is that such plasticity targeted techniques provide the prospect of taking advantage of the underlying neural plasticity to optimise the form of the neural recording and electrical stimulation. The outcomes will be to greatly improve the performance of brain-machine interface in terms of measures such as the number and sensitivity of channels, as well as robustness and reliability.Read moreRead less
Optimised distributed stimulation of muscle. The project aims to extend to humans, a method of producing a non-fatiguing, smooth, submaximal muscle contraction. The method using multiple electrodes, stimulated at different times, with those times being adjusted for optimum smoothness at low stimulation rates. This will enable the gathering of information about the mechanics of muscle undergoing near physiological contractions, which will be of interest to researchers in Biomechanics. It will ....Optimised distributed stimulation of muscle. The project aims to extend to humans, a method of producing a non-fatiguing, smooth, submaximal muscle contraction. The method using multiple electrodes, stimulated at different times, with those times being adjusted for optimum smoothness at low stimulation rates. This will enable the gathering of information about the mechanics of muscle undergoing near physiological contractions, which will be of interest to researchers in Biomechanics. It will also be a step towards the restoration of function to spinal cord injured patients.Read moreRead less