Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel ma ....Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel materials that are mechanochemically active, tough, and fatigue resistant, along with design criteria for force-activated molecule immobilisation and release expected to provide significant benefit forbiomedical applications, additive manufacturing, soft robotics and flexible electronics.Read moreRead less
Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals cause ....Bioelectronics: addressing the biointerface challenge. This project aims to develop bioelectronic materials with long operational stability in physiological conditions and enhanced electronic performance that will effectively interface with electroresponsive tissue. These new materials will be integrated into bioadhesives from which simple bioelectronics devices will be fabricated and assessed for their capability to modulate biosignals and to interact with tissue. Disruption in biosignals causes numerous medical conditions such as epilepsy and heart failure and the development of flexible and biocompatible medical electronics devices that interface with tissue is essential for regaining and modulating these signals.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
Switching the light on cartilage repair. Osteoarthritis is a leading cause of pain and disability in adults and affects 15 per cent of the Australian population. This project will develop a revolutionary new approach to treat joint disorders using smart materials and stem cells. The novel materials and techniques developed will help Australia maintain its leading edge in biotechnology.
Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D prin ....Synthetic extracellular matrices for control of cellular reprogramming. This project aims to design materials that control the cellular environment for the fast, efficient, and reproducible production of reprogrammed cells in embryo-like architectures. Regenerative medicine has entered a new era, where reprogramming a patient’s cells is now possible for studying and treating disease. The expected outcomes of this project include mechanistic details of cell reprogramming, design rules for 3D printing of living cells and commercially viable reprogramming materials. The project expects to contribute fundamental knowledge in materials and biomedical sciences, while providing tools that will benefit commercial ventures in cell and tissue manufacturing.Read moreRead less
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