A real-time biomechanical study of Neanderthal anterior dentition. This project aims to advance understanding of the evolution of human dentition using an innovative approach that integrates sophisticated 3D digital modelling with engineering tools. Neanderthals are our closest extinct human relatives that inhabited Eurasia from about 230,000 to 28,000 years ago. However, their protruding faces, large noses and big anterior teeth, raise questions about why these people look so different from us. ....A real-time biomechanical study of Neanderthal anterior dentition. This project aims to advance understanding of the evolution of human dentition using an innovative approach that integrates sophisticated 3D digital modelling with engineering tools. Neanderthals are our closest extinct human relatives that inhabited Eurasia from about 230,000 to 28,000 years ago. However, their protruding faces, large noses and big anterior teeth, raise questions about why these people look so different from us. This project aims to fill this gap in human knowledge about our evolutionary history, and to enhance the international visibility of Australian research in palaeoanthropology and dental biomechanics.Read moreRead less
Nano-mechanical and nano-structural investigation of dentine: unravelling a novel nano-scale regulator of high durability of mineralised tissues. This project proposes that proteoglycans (PG) are key regulators of the high durability of dentine. PGs are primarily responsible for the structural organization of collagen in all vertebrates, however virtually nothing is known about their role on the biomechanics of mineralized tissues. This study aims to thoroughly address this question.
Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, ....Continuous tooth replacement in mammals: revealing the fundamental processes in tooth generation and movement. This project will investigate how molar teeth are made in mammals by examining the nabarlek, or little rock-wallaby, which is one of a handful of mammals that is able to regenerate new molars throughout its life. These new teeth migrate through the bone in order to move into the correct position in the mouth. By investigating two well-studied organisms, the mouse and the tammar wallaby, as well as the nabarlek itself, the developmental processes and genes involved in molar generation and movement will be revealed. This project will integrate findings in regenerative medicine, evolutionary biology, materials engineering and palaeontology to reveal the mechanisms and origins of this astounding capability.Read moreRead less
Multiscale Study on Biomechanical Roles of Soft Tissue on Bone Remodelling. The project aims to increase our knowledge of the processes of bone remodelling and the role of soft tissue in this process. Mechanical force is a key stimulus for regulating bone remodelling. A significant question in biomechanics is why orthodontics only use very small forces (1 Newton) to generate significant oral bone remodelling, whereas prosthodontics that apply three orders of magnitude higher forces (~1000 Newton ....Multiscale Study on Biomechanical Roles of Soft Tissue on Bone Remodelling. The project aims to increase our knowledge of the processes of bone remodelling and the role of soft tissue in this process. Mechanical force is a key stimulus for regulating bone remodelling. A significant question in biomechanics is why orthodontics only use very small forces (1 Newton) to generate significant oral bone remodelling, whereas prosthodontics that apply three orders of magnitude higher forces (~1000 Newton) do not move dental implants. This project aims to develop new multiscale modelling and remodelling techniques in computational mechanics to explore the roles played by connective soft tissue in bone adaptation. Expected project outcomes would increase our understanding in biomechanics and affect health care disciplines such as orthodontics, prosthodontics and orthopaedics.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101666
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Endogenous bone regenerative technique to repair hard tissue defects in congenital craniofacial clefts. This project aims to develop an endogenous bone regenerative technique to repair the bony defects in congenital craniofacial clefts, through stimulating patients' latent self-repair mechanisms and reviving their innate capacity for regeneration. The novel technique would replace the existing and controversial surgical bone grafting method.