Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to r ....Controlling the adhesome to regulate cell fate on biomaterials. Mesenchymal stem cell-based tissue engineering practices are hampered worldwide by the lack of appreciation and understanding of the matrix-mediated cues that must be provided during adhesion and spreading to drive cells to definitive tissue end points. This project will address these knowledge deficiencies by combining high throughput array technologies, a set of tailorable self-assembling biomaterials and real-time biosensors to rapidly, at high resolution, elucidate how mechanotransductive cues determine the fate choice of mesenchymal stem cells, and furthermore, how to manipulate them with smart biomaterial design to achieve desired outcomes for tissue engineering. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100200
Funder
Australian Research Council
Funding Amount
$270,427.00
Summary
AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The o ....AutoStem: a high performance, automated stem cell bioengineering facility. This project aims to establish an automated stem cell bioengineering ("AutoStem") facility that will enable critical insights into the molecular mechanisms that underly the loss in stem cell function and tissue homeostasis as we age. The AutoStem facility expects to lead to the discovery of the key drivers of stem cell ageing and the development of novel technological solutions to maintain tissue function with age. The outcomes produced from the AutoStem facility will have significant economic and social benefits in enabling healthy ageing and increased productivity for an ageing Australia.Read moreRead less
Photoreversible hydrogels to study stem cell memory and fate. This project will develop materials whose stiffness can be reversibly increased and decreased by the simple application of light, and use these to build knowledge of how stem cell fate is regulated. The influence of mechanical cues on the structure and organisation of the nucleus will be determined. Expected outcomes are new synthetic and light-reversible culture materials, and fundamental insights into how forces change the nucleus t ....Photoreversible hydrogels to study stem cell memory and fate. This project will develop materials whose stiffness can be reversibly increased and decreased by the simple application of light, and use these to build knowledge of how stem cell fate is regulated. The influence of mechanical cues on the structure and organisation of the nucleus will be determined. Expected outcomes are new synthetic and light-reversible culture materials, and fundamental insights into how forces change the nucleus to alter stem cell aging and fate. The findings will provide critical information required for the future development of assays to measure cell potency and instructive biomaterials to drive stem cell expansion and tissue-regeneration and will have impact by underpinning future advances in stem cell technologies.Read moreRead less
Micro/nano smart surfaces to unlock the potential of multipotent stem cells. This project aims to determine the interplay of micro/nanostructures on stem cell mechanotransduction and to control the cellular environment. It is expected that this will expand our knowledge on how to control stem cell fate. Expected outcomes are novel scalable technologies for micro/nanostructures and smart surfaces, controlled stem-cell expansion and differentiation, and the creation of a library of protein express ....Micro/nano smart surfaces to unlock the potential of multipotent stem cells. This project aims to determine the interplay of micro/nanostructures on stem cell mechanotransduction and to control the cellular environment. It is expected that this will expand our knowledge on how to control stem cell fate. Expected outcomes are novel scalable technologies for micro/nanostructures and smart surfaces, controlled stem-cell expansion and differentiation, and the creation of a library of protein expression based on the cell interactions. These outcomes will provide critical information required for the future development of instructive biomaterials to drive stem cell expansion and tissue-regeneration. Those materials should benefit the future development of efficient and cost-effective regenerative medicine solutions.Read moreRead less
An anti-senescence nanoplatform and its underlying mechanism. The project will bring together complementary expertise and skills by combining biomaterials, cell and molecular biology, and engineering, to develop a novel nano-biomaterial platform for anti-senescence and gain an in-depth understanding of its underlying mechanisms. The underlying mechanisms of senescence remain elusive and bone substitutes with anti-senescence property have not been explored and becoming a growing field of interest ....An anti-senescence nanoplatform and its underlying mechanism. The project will bring together complementary expertise and skills by combining biomaterials, cell and molecular biology, and engineering, to develop a novel nano-biomaterial platform for anti-senescence and gain an in-depth understanding of its underlying mechanisms. The underlying mechanisms of senescence remain elusive and bone substitutes with anti-senescence property have not been explored and becoming a growing field of interest in bone regeneration. The project will develop a well-defined and efficient nanomaterial platform with optimal combination of nano-surface features and chemistry for cell rejuvenation, and it will give unprecedented depth of interdisciplinary understanding of senescence rejuvenation mechanisms.Read moreRead less
Understanding platinum dissolution in biomedical stimulating electrodes. Platinum is the main material used in electrodes for neurostimulators like the cochlear implant. Platinum electrodes can experience dissolution during implantation, which can impact on their function. The mechanisms governing this dissolution process are complex and still not fully understood. This research aims to understand the chemical, electrical and biological factors that impact on platinum dissolution in electrodes. ....Understanding platinum dissolution in biomedical stimulating electrodes. Platinum is the main material used in electrodes for neurostimulators like the cochlear implant. Platinum electrodes can experience dissolution during implantation, which can impact on their function. The mechanisms governing this dissolution process are complex and still not fully understood. This research aims to understand the chemical, electrical and biological factors that impact on platinum dissolution in electrodes. It will also develop new 3D models to simulate conditions in the human body for more rapid testing of electrodes. The new knowledge generated will improve the accuracy of predictions of platinum dissolution, develop new approaches for minimising dissolution, and contribute to reducing need for animal experimentation.Read moreRead less
Understanding self-organising tissues. This project will discover how an organ can form from a mixture of component cells by 'self-organisation'. Understanding of how this can occur, could potentially be applied to the bioengineering of organs from component cells.
Generating multi-component scaffolding to influence the differentiation of embryonic stem cells. Nervous system diseases are debilitating and will develop in over 50 per cent of people at some time in their life. This project will develop strategies so that stem cells can be utilised to encourage brain repair for the treatment of Parkinson's disease. The technology developed will also be of benefit for the treatment of other nervous system disorders.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100220
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Fluorescence and internal reflection system to develop lab-on-chip devices. Fluorescence and internal reflection system to develop lab-on-chip devices:
The aim of this project is to develop and establish a state-of-the-art fluorescence imaging facility. It aims to establish a total internal reflection fluorescence microscope combined with high speed epifluorescence imaging workstation that will be tailored to specifically investigate the fundamentals of blood cell, and vascular cell function. T ....Fluorescence and internal reflection system to develop lab-on-chip devices. Fluorescence and internal reflection system to develop lab-on-chip devices:
The aim of this project is to develop and establish a state-of-the-art fluorescence imaging facility. It aims to establish a total internal reflection fluorescence microscope combined with high speed epifluorescence imaging workstation that will be tailored to specifically investigate the fundamentals of blood cell, and vascular cell function. The project forms part of a broad bioengineering research program aimed at developing novel lab-on-chip technologies for basic cell biology and haematology. Outcomes from these projects may have significant impact in fundamental research in both bioengineering and biology disciplines.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101458
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Investigation and development of biological anti-adhesive coatings. Lubricin is a biological anti-adhesive protein that is found in mammalian joints. This project will investigate the properties and action of Lubricin and develop novel anti-adhesive coating technologies to eliminate problems associated with non-specific binding of biomolecules in microfluidic and biosensor applications.