Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. ....Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. It will promote capacity of Australia for manufacturing global biomaterial products for tissue engineering. We will also develop in-situ imaging analytical protocols for the rapid analysis of broad arrays of functional molecules, with significant bearing on BioMEMS design to develop methods for diagnosis of fatal diseases.Read moreRead less
Biomaterial applications of synthetic elastin. The grant will develop a new collaboration between two established laboratories. The Weiss Lab (synthetic elastin; University of Sydney, Australia) will send elastin materials to the Langer Lab (interface of biotechnology and materials science; MIT, USA). Prof. Weiss will visit the Langer Lab and be trained in and participate collaboratively in the use of established MIT methodologies that will focus on applications in cardiac tissue engineering, co ....Biomaterial applications of synthetic elastin. The grant will develop a new collaboration between two established laboratories. The Weiss Lab (synthetic elastin; University of Sydney, Australia) will send elastin materials to the Langer Lab (interface of biotechnology and materials science; MIT, USA). Prof. Weiss will visit the Langer Lab and be trained in and participate collaboratively in the use of established MIT methodologies that will focus on applications in cardiac tissue engineering, controlled release of drugs and vocal fold repair. The MIT group will benefit from access to and the use of elastin materials that are developed in AustraliaRead moreRead less
Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiati ....Molecular signals that regulate the regenerative properties of intestinal epithelial cells. Most cancer deaths are due to the cancer spreading to other organs. Cancer is much more difficult to treat once it has spread to other organs in the body where the cancer cells can exist in a dormant state. Dormant cancer cells evade conventional anticancer treatment and can remain dormant for a very long time before they change back to a 'tumour-growing' state. An understanding of how the cancer initiating (stem cell) property of tumour cells is maintained offers potential novel avenues to eliminate persistent cancer cells. This knowledge will ultimately lead to better management and treatment of cancer, and increase survival. An understanding of stem cell behaviour is also central to the control of degenerative conditions.Read moreRead less
The first integrated multimodal assay for the ultrasensitive detection of dengue contamination of blood. This project will develop the first screening test to check for dengue contamination of blood donations in Australia. This will help ensure safe, continued supply from blood donors, particularly in Queensland where dengue is on the rise.
Single-session Introduction of Mutations in Parallel Lines (SIMPL). This project aims to develop a novel method for markedly accelerating production of genetically modified mice, which are a key 'tool' for studying biological processes and diseases. The work plans to take CRISPR, the latest gene-editing technique, to the next level by developing a novel CRISPR-based method to generate different mouse strains with distinct variations of the same gene sequences, at a fraction of the present cost a ....Single-session Introduction of Mutations in Parallel Lines (SIMPL). This project aims to develop a novel method for markedly accelerating production of genetically modified mice, which are a key 'tool' for studying biological processes and diseases. The work plans to take CRISPR, the latest gene-editing technique, to the next level by developing a novel CRISPR-based method to generate different mouse strains with distinct variations of the same gene sequences, at a fraction of the present cost and time. This project should overcome a major barrier to studying gene function with unprecedented detail, thereby opening new avenues for future research into biological processes. Thus, the outcomes from this project should impact on the entire field of biomedical research, and advance Australia's biotech industry.Read moreRead less
Intracellular trafficking and function of a recycling receptor which prolongs the serum half-life of novel therapeutic proteins. The life span of recombinant engineered proteins for therapeutic use is a critical factor in their effectiveness, ease of clinical application and cost. This project will exploit interactions with a natural receptor, which prolongs the lifespan of serum proteins, to enhance survival of therapeutic engineered proteins.