A biophotonics-based approach to the study of cell-mechanics. This study will help to promote and maintain good health. There is a connection between diseases such as arthritis and osteoporosis and cell mechanics. Our study will provide insight into cell mechanics, thereby helping to understand the pathophysiology of these diseases. The study is relevant to tissue engineering. There is ongoing research on mechanical conditioning of tissue substitutes. Understanding cell mechanics will help to op ....A biophotonics-based approach to the study of cell-mechanics. This study will help to promote and maintain good health. There is a connection between diseases such as arthritis and osteoporosis and cell mechanics. Our study will provide insight into cell mechanics, thereby helping to understand the pathophysiology of these diseases. The study is relevant to tissue engineering. There is ongoing research on mechanical conditioning of tissue substitutes. Understanding cell mechanics will help to optimise conditioning protocols, thereby improving the properties of engineered tissue.
During this study we will develop optical tools that have applications in the life sciences, in the development of advanced materials and in nanotechnology. Our project will promote Australian research in these fields.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989726
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Nanophotonic and Microfluidic Integration Facility: a Platform for Optofluidics. Emerging 'lab on a chip' technology promises to provide low-cost, mass produced platforms for monitoring and processing of environmental and biological samples (eg. water quality and early cancer detection). These essentially fluidic platforms will require integrated photonic components to provide the vast array of optical interrogation options that are used in all modern laboratories. The proposed facility will e ....Nanophotonic and Microfluidic Integration Facility: a Platform for Optofluidics. Emerging 'lab on a chip' technology promises to provide low-cost, mass produced platforms for monitoring and processing of environmental and biological samples (eg. water quality and early cancer detection). These essentially fluidic platforms will require integrated photonic components to provide the vast array of optical interrogation options that are used in all modern laboratories. The proposed facility will enable Australian researchers to effectively integrate nano-photonic structures with engineered micro-fluidics into a single optofluidic chip. This will bring researchers in photonics and microfluidics together and will provide platforms supporting support biomedical and environmental and even fundamental physics projects.Read moreRead less
Protein self-assembly on surfaces, interfaces and nanoparticles. Surfaces such as those presented by an air-liquid interface or air-borne nanoparticles exert significant effects on protein aggregation in biological environments. We will develop a comprehensive theoretical and experimental approach to study the effects of such surfaces on the self assembly of proteins leading to disease causing amyloid fibrils. This will provide a molecular level understanding of protein self-association and a ....Protein self-assembly on surfaces, interfaces and nanoparticles. Surfaces such as those presented by an air-liquid interface or air-borne nanoparticles exert significant effects on protein aggregation in biological environments. We will develop a comprehensive theoretical and experimental approach to study the effects of such surfaces on the self assembly of proteins leading to disease causing amyloid fibrils. This will provide a molecular level understanding of protein self-association and a rational basis for the design of inhibitors to stop protein aggregation. The work will also establish design principles for new nanomaterials via the controlled self assembly of proteins on surfaces.Read moreRead less