The cellular basis of branching morphogenesis during kidney development. This project aims to study the process of branching morphogenesis which drives the development of the kidney. Previous studies group have demonstrated, in general terms, how branching progresses during gestation. However, little is known about the fundamental cellular events which trigger or characterise this basic developmental process. This project expects to provide deep insights into the cellular basis of tissue and org ....The cellular basis of branching morphogenesis during kidney development. This project aims to study the process of branching morphogenesis which drives the development of the kidney. Previous studies group have demonstrated, in general terms, how branching progresses during gestation. However, little is known about the fundamental cellular events which trigger or characterise this basic developmental process. This project expects to provide deep insights into the cellular basis of tissue and organ development. In studying this process the project should provide critical insights into how cells act, individually and collectively, to build tissues.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100191
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
An advanced mass spectrometer for applications in phospho-proteomics, glycomics and top-down sequencing of proteins. This cutting-edge mass spectrometry facility will benefit the Hunter Valley research community comprising 100 researchers in this field. It will enable the researchers to enhance their research productivity in areas of national importance, including better understanding the etiology of disease states, reproductive health and the regulation of plant growth.
Morphological development of the kidney – a paradigm for organogenesis. This project aims to shed new light on how the kidney develops, how normal adult function is established and how congenital kidney malformations occur. It aims to investigate a mathematical pattern that has been discovered in the program of branching morphogenesis which dictates kidney development. By combining cutting-edge genetic approaches, morphological analysis and mathematical modelling, this project plans to explore h ....Morphological development of the kidney – a paradigm for organogenesis. This project aims to shed new light on how the kidney develops, how normal adult function is established and how congenital kidney malformations occur. It aims to investigate a mathematical pattern that has been discovered in the program of branching morphogenesis which dictates kidney development. By combining cutting-edge genetic approaches, morphological analysis and mathematical modelling, this project plans to explore how this pattern is established, how it dictates kidney development and whether it constitutes an ancient mechanism central to organ formation. Project outcomes may improve understanding of fundamental developmental processes and developmental disease and variation. Project findings may also be important for understanding the development of other organ systems.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.
Defining a role for non-coding RNAs in gonadal sex differentiation. This project aims to increase knowledge in the area of developmental biology, studying how gene regulation by so-called non-coding RNAs contributes to tissue patterning. The project plans to use a unique model system: gonadal development in the chicken embryo. It also plans to use novel molecular approaches that exploit the chicken model to study the role of microRNAs and a long non-coding RNA in patterning the embryonic gonad. ....Defining a role for non-coding RNAs in gonadal sex differentiation. This project aims to increase knowledge in the area of developmental biology, studying how gene regulation by so-called non-coding RNAs contributes to tissue patterning. The project plans to use a unique model system: gonadal development in the chicken embryo. It also plans to use novel molecular approaches that exploit the chicken model to study the role of microRNAs and a long non-coding RNA in patterning the embryonic gonad. The project aims to provide a deeper understanding of how genes operate to control tissue patterning and organogenesis. It may thus inform the field of sex determination specifically, and, more broadly, stem cell biology and tissue engineering.Read moreRead less
Development of an electrode for stimulation of a transplanted neosphincter. This project aims to develop a novel electrode as an integral component of a new treatment for severe stress urinary incontinence. Treatments for severe stress urinary incontinence are associated with complications and are not completely effective. The new electrode is designed to be activated by an implanted stimulator to control an innervated smooth muscle graft (the neosphincter) to regulate the flow of urine from the ....Development of an electrode for stimulation of a transplanted neosphincter. This project aims to develop a novel electrode as an integral component of a new treatment for severe stress urinary incontinence. Treatments for severe stress urinary incontinence are associated with complications and are not completely effective. The new electrode is designed to be activated by an implanted stimulator to control an innervated smooth muscle graft (the neosphincter) to regulate the flow of urine from the bladder. Project research into the design of the electrode will focus on providing safe, effective and efficient stimulation of the neosphincter, while ensuring minimal damage to the surrounding tissues and affording straightforward implantation at surgery.Read moreRead less
Development of an electrode assembly for the stimulation of a transplanted innervated smooth muscle sphincter. This project will design and assess a number of different electrode designs for use in a medical device being developed for the treatment of severe stress urinary incontinence. The project will identify an optimal electrode design, which will be used in future clinical trials of the device.
The structure and patterning of branching morphogenesis in the developing kidney. This project aims to understand a fundamental developmental process known as branching morphogenesis, which drives the formation of many organs including the kidney, lungs and glands. Understanding this process will be of key importance in understand how our organs form.