The Burden Of Late Preterm Birth On Brain Development And 2 Year Outcomes – A Prospective, Longitudinal Cohort Study
Funder
National Health and Medical Research Council
Funding Amount
$838,690.00
Summary
80% of preterm babies are born from 32-36 weeks’ gestation, and are late preterm (LPT). LPT children have more learning problems, but why this occurs is unknown. This study aims to understand the effect of LPT birth on brain development. We will do brain scans at term and assess development at 2 years of age of 200 LPT and 200 full-term children. We expect LPT babies will have subtle alterations in brain development compared with term controls which will be associated with delayed development.
Motor problems, ranging from clumsiness to cerebral palsy, are one of the most common adverse outcomes in children born early. This study will investigate the motor development of children born <30 weeks’ gestation compared with peers born at term from birth to 5 years. We will determine whether early clinical evaluations or neuroimaging in the newborn period can predict later motor impairment at 5 years to be able to identify those who will benefit most from early intervention.
A Study Of The Impact Of Treating Electrographic Seizures In Term Or Near-term Infants With Neonatal Encephalopathy
Funder
National Health and Medical Research Council
Funding Amount
$1,365,184.00
Summary
Seizures in the newborn infant are common and may be harmful to the developing brain. They are not always recognised. This study investigates whether or not treating all seizures detected using a bedside brain activity monitor improves developmental outcome, compared to just treating seizures that doctors recognise.
Novel Antimicrobial Biomaterials. There is a clear need for new materials that repel bacteria. Infections associated with biomaterials incur a high cost in terms of human health and well being, but such infections also increase the burden on the health care system by extending hospital stays and significantly elevating costs. The cost of a catheter-related blood stream infection is around $50,000 for patients in intensive care units. If all medical devices are considered, the cost of related inf ....Novel Antimicrobial Biomaterials. There is a clear need for new materials that repel bacteria. Infections associated with biomaterials incur a high cost in terms of human health and well being, but such infections also increase the burden on the health care system by extending hospital stays and significantly elevating costs. The cost of a catheter-related blood stream infection is around $50,000 for patients in intensive care units. If all medical devices are considered, the cost of related infections is then approximately $20 billion. The technology proposed here has the potential to reduce biomaterial related infection rates, improve health care and reduce health care costs. Read moreRead less
Rheological and Electrical Properties of Biological Soft Tissues. Research on coupling rheological and electrical properties of biological soft tissues and their composites is fundamental to medical and sport sciences, as well as the optimal design and management of smart biomedical devices and bio-microtransducers. This project aims to develop an effective rheological and electrical constitutive law and finite element implementation together with supporting experiments to reveal the novel coupl ....Rheological and Electrical Properties of Biological Soft Tissues. Research on coupling rheological and electrical properties of biological soft tissues and their composites is fundamental to medical and sport sciences, as well as the optimal design and management of smart biomedical devices and bio-microtransducers. This project aims to develop an effective rheological and electrical constitutive law and finite element implementation together with supporting experiments to reveal the novel coupling behaviour of viscoelastic and electric fields of the innovative smart biological soft tissue. These results will provide a guideline for future research in tissue engineering and help Australian biomedical science and industries improve the modern biotransducers and smart biomicro-devices.Read moreRead less
Advanced nanoparticles as biocompatible antioxidant agents with targeting functionality. This proposal addresses the core issue of designing nanoparticles capable of delivering antioxidant properties in a biological environment. The major benefits to Australia are two-fold: first will be in the improved health outcomes by providing materials that are better suited to targeted therapeutic delivery, thereby improving the quality of life and reducing the need for further surgical intervention; the ....Advanced nanoparticles as biocompatible antioxidant agents with targeting functionality. This proposal addresses the core issue of designing nanoparticles capable of delivering antioxidant properties in a biological environment. The major benefits to Australia are two-fold: first will be in the improved health outcomes by providing materials that are better suited to targeted therapeutic delivery, thereby improving the quality of life and reducing the need for further surgical intervention; the second is in providing greater knowledge about nanoparticle interactions with the biological environment. This project will assist in the training of researchers in this field which will in turn provide economic growth through the development of Australian industries.Read moreRead less
Hydrogel systems for effective encapsulation of functional pancreatic islet cells. This proposal addresses the problem of maintaining viability and function of cells encapsulated within an immuno-isolation barrier material. The research will develop biosynthetic materials that are able to meet design criteria for an effective biomaterial for this application. The major benefits to Australia will be in improved health outcomes by providing safer, more efficacious materials, economic growth develo ....Hydrogel systems for effective encapsulation of functional pancreatic islet cells. This proposal addresses the problem of maintaining viability and function of cells encapsulated within an immuno-isolation barrier material. The research will develop biosynthetic materials that are able to meet design criteria for an effective biomaterial for this application. The major benefits to Australia will be in improved health outcomes by providing safer, more efficacious materials, economic growth development of the Australian Medical Device industry and in high level training of researchers in this field.Read moreRead less
microRNAs: discovery and analysis in mouse development. MicroRNAs (miRNAs) are a new class of regulatory molecule, recently found to be abundant and strongly conserved in several eukaryotic species, encoded by genes that are transcribed into short stem-loop structures and then processed into ~22nt single-stranded RNAs by the RNAi pathway. We have cloned novel miRNAs, and obtained the first evidence for regulation of a miRNA in a mammal. We propose to continue cloning novel miRNAs by the tried m ....microRNAs: discovery and analysis in mouse development. MicroRNAs (miRNAs) are a new class of regulatory molecule, recently found to be abundant and strongly conserved in several eukaryotic species, encoded by genes that are transcribed into short stem-loop structures and then processed into ~22nt single-stranded RNAs by the RNAi pathway. We have cloned novel miRNAs, and obtained the first evidence for regulation of a miRNA in a mammal. We propose to continue cloning novel miRNAs by the tried method, and to explore bioinformatics-based methods of identification. We will also study the expression of miRNAs in mouse embryos at successive stages, and develop a microarray assay for miRNA expression.Read moreRead less
A new generation of multi-modality biomedical image visualisations. This research will overcome the urgent and significant burden in the routine clinical visualisation of multiple-modality biomedical image data, which are complex and exquisitely detailed from the new generation of high-resolution medical imaging scanners. Together with our industry partner RPA Hospital, we will produce 3D visualisation methodologies that will simplify and revolutionise the way biomedical data are visualised, ana ....A new generation of multi-modality biomedical image visualisations. This research will overcome the urgent and significant burden in the routine clinical visualisation of multiple-modality biomedical image data, which are complex and exquisitely detailed from the new generation of high-resolution medical imaging scanners. Together with our industry partner RPA Hospital, we will produce 3D visualisation methodologies that will simplify and revolutionise the way biomedical data are visualised, analysed and interpreted by imaging specialists and disseminated to doctors and patients. Given the pivotal role that imaging plays in modern healthcare, this will improve diagnosis and assessment, and enhance Australia's leading position in the development of frontier technologies.Read moreRead less
Large scale knowledge and image based biomedical modelling and derivation of PET-CT disease maps and treatment response. The smart use of information to improve, promote and maintain good healthcare is a critical mission for our country. Cancer is a serious problem in Australian society and 1 in 4 individuals will be affected by it in their lifetime. Our research is focussed on two types of cancer - lung cancer and the lymphomas - and it will use IT in a novel way to extract important informatio ....Large scale knowledge and image based biomedical modelling and derivation of PET-CT disease maps and treatment response. The smart use of information to improve, promote and maintain good healthcare is a critical mission for our country. Cancer is a serious problem in Australian society and 1 in 4 individuals will be affected by it in their lifetime. Our research is focussed on two types of cancer - lung cancer and the lymphomas - and it will use IT in a novel way to extract important information from a very large biomedical data repository. We hope that it will improve personalised diagnosis and treatment in these cancers and provide new information on how some cancers spread and resist our usual treatments. We think our techniques will contribute to other research areas such as astronomy, agriculture, water/energy resources, and security.Read moreRead less