Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan- ....Mimicking the perivascular niche with boronolectin-based biomaterials. This project aims to address roadblocks in perivascular stem cell manufacturing by discovering novel mechanisms and materials that improve cell quality outcomes during extended culture. An innovative, interdisciplinary approach to biomaterials discovery, combining live cell-based screening of cell surface glycans, bio-inspired materials design and synthesis, and niche mimicry, will enable the discovery of cell surface glycan-mediated interactions that support long-term expansion and potency maintenance, and synthetic biomaterials that can mimic them. Significant benefits for stem cell researchers, manufacturers and end users are expected from the project and the application of this scalable biomaterial platform.Read moreRead less
Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisat ....Soft materials containing hierarchy via 3D sacrificial micro-moulding. The project seeks to develop sophisticated new polymeric materials and devices not possible using current manufacturing techniques. Biomaterials based on hydrogels are ideal substrates for synthetic extra-cellular matrices due to their high water content. However, one of the challenges hindering the use of hydrogels is reproducing the transport properties found in natural tissue with hierarchical features such as vascularisation. To address this, the project plans to develop a 3D moulding process for generating soft materials containing precise channels decorated with defined molecules. Intended outcomes include a fundamental understanding of the 3D moulding process, and new polymers and advanced tools for bioengineers for future applications such as tissue transplants, cell guides for treating spinal cord injuries, soft robotics and microfluidic devices to study cancer metastasis. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100057
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
A high-resolution X-ray microtomography system. This project aims to establish a Scanco microCT 50 high resolution X-Ray microtomography system, to non-destructively visualise and quantitatively characterise complex samples, including advanced composites, tissue engineering constructs, biological tissues, minerals and fossils. The non-destructive characterisation of these samples is critical to advance research. The versatile system offers high spatial resolution (down to 500 nm voxel size) and ....A high-resolution X-ray microtomography system. This project aims to establish a Scanco microCT 50 high resolution X-Ray microtomography system, to non-destructively visualise and quantitatively characterise complex samples, including advanced composites, tissue engineering constructs, biological tissues, minerals and fossils. The non-destructive characterisation of these samples is critical to advance research. The versatile system offers high spatial resolution (down to 500 nm voxel size) and large sample size (up to 100 mm diameter). The project will enable progress in advanced composites, additive bio-manufacturing, physiology of biological tissues and palaeontology which will benefit Australian science. Additionally, through commercialisation and the formation of new companies, the project could potentially result in economic and health benefits to the wider Australian population and economy.Read moreRead less
Graded Biomaterial for Articular Cartilage Replacement. Osteoarthritis is a major health and economical burden on the Australian community which can be addressed in part by providing a viable option for effective clinical treatment. 34% of people over the age of 50 suffer from osteoarthritis, predominantly the knee. The development of a biomaterial to enable repair of articular cartilage through minor surgical procedures will release resources at point of care. Current biomaterial options are st ....Graded Biomaterial for Articular Cartilage Replacement. Osteoarthritis is a major health and economical burden on the Australian community which can be addressed in part by providing a viable option for effective clinical treatment. 34% of people over the age of 50 suffer from osteoarthritis, predominantly the knee. The development of a biomaterial to enable repair of articular cartilage through minor surgical procedures will release resources at point of care. Current biomaterial options are still in infancy and an Australian based product would benefit the Australian economy as well as Australia's international standing within the biomaterials community.Read moreRead less
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
Elucidating surface-mediated permissive cues for cellular differentiation. This project will develop a novel biomaterial platform technology that will enable firstly the probing and thereafter the control of the cellular pathways of adult mesenchymal stem cells. These fundamental insights will be translated into novel stem cell culture ware products that will enable clinically relevant, functional tissue repair and regeneration.
Composite biomaterials for modulation of dermal fibroblast function. The successful outcome of this research will revolutionize the way scars are treated for the large number of people who suffer burns and even minor trauma that leads to disfigurement. By using advanced chemical synthesis, biochemical analysis, cell biology and polymer materials science, an intelligent gel sheet will be devised that is able to control the formation of scar tissue and also reduce the effect of existing scars. Thi ....Composite biomaterials for modulation of dermal fibroblast function. The successful outcome of this research will revolutionize the way scars are treated for the large number of people who suffer burns and even minor trauma that leads to disfigurement. By using advanced chemical synthesis, biochemical analysis, cell biology and polymer materials science, an intelligent gel sheet will be devised that is able to control the formation of scar tissue and also reduce the effect of existing scars. This will produce improved quality of life for sufferers of severe scarring and have major economic benefits in reduced health costs. Read moreRead less
Inhomogeneous tissue conductivity influence on the forward and inverse electroencephalogram problems in realistic head models. The brain dysfunction indicators have been extremely difficult to obtain, largely because many disorders of higher brain function reflect abnormalities of brain function rather than apparent brain structure. The neuronal generator localization and identification in this project will provide complementary information about source and timing of neural activities sub-servin ....Inhomogeneous tissue conductivity influence on the forward and inverse electroencephalogram problems in realistic head models. The brain dysfunction indicators have been extremely difficult to obtain, largely because many disorders of higher brain function reflect abnormalities of brain function rather than apparent brain structure. The neuronal generator localization and identification in this project will provide complementary information about source and timing of neural activities sub-serving higher brain function and form sequences of spatial-temporal brain activity image. That will enable the information from MRI, which has a good spatial but poor temporal resolution, and the information from EEG, which has a high temporal resolution on the scalp, to be combined to provide clinical psychologists and brain researchers a more efficient diagnostic tool.Read moreRead less
New open MRI Technology for Kinematic Orthopaedic Imaging. This application intends to significantly enhance Open MRI as applied to dynamic joint imaging by technological and methodological innovation. Expected outcomes include better technology for the imaging of joints under loaded movement and consequently, improved understanding of joint function and disease. This technology will provide unique ability in Australia and brings together highly skilled groups in Biomedical Engineering, medical ....New open MRI Technology for Kinematic Orthopaedic Imaging. This application intends to significantly enhance Open MRI as applied to dynamic joint imaging by technological and methodological innovation. Expected outcomes include better technology for the imaging of joints under loaded movement and consequently, improved understanding of joint function and disease. This technology will provide unique ability in Australia and brings together highly skilled groups in Biomedical Engineering, medical equipment manufacturing and design and musculo-skeletal imaging.Read moreRead less
Cardiac electrographic modelling and analysis. The outcomes of this project will improve the accuracy with which abnormal conduction pathways in the heart are found and will also use chaotic modelling tools to better predict the need and outcomes of patients with life threatening arrhythmias.