A novel precision-engineered microfluidic chip for wear particle research. This project aims to develop 1- novel protocols to generate clinically-relevant wear particles from spinal implants in-vitro and 2- a technological framework for the fabrication of a novel microfluidic 3D spinal implant-on-a-chip with tailored mechanical, material and biological properties. This will provide a cost-effective tool, currently unavailable, that allows investigation into the impact of wear particles on health ....A novel precision-engineered microfluidic chip for wear particle research. This project aims to develop 1- novel protocols to generate clinically-relevant wear particles from spinal implants in-vitro and 2- a technological framework for the fabrication of a novel microfluidic 3D spinal implant-on-a-chip with tailored mechanical, material and biological properties. This will provide a cost-effective tool, currently unavailable, that allows investigation into the impact of wear particles on healthy spinal disc cells. We expect our technological framework to become an invaluable tool for biomedical engineers, biologists, and bio-engineers to work together and generate clinically relevant in-vitro data that supports optimisation for spinal implant design, fabrication, and safety. Read moreRead less
A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To un ....A thermodynamic pathway to intracellular delivery. Cells transmit information through molecules. By delivering foreign molecules into cells, such as DNA and proteins, it is possible to engineer and reprogram cells just like a computer. This proposal aims to develop a novel microfluidic device for intracellular delivery. The device will work by exposing cells to rapid thermal shock to generate transient disruptions in cell membranes and thereby enable influx of foreign molecules into cells. To understand how the method can be optimized, the thermodynamic pathway of membrane disruption will be investigated at a single cell level. The methods and insights arising from this project could eventually lead to novel, patentable and lower-cost health technologies.Read moreRead less