The Australian Research Data Commons (ARDC) invites you to participate in a short survey about your
interaction with the ARDC and use of our national research infrastructure and services. The survey will take
approximately 5 minutes and is anonymous. It’s open to anyone who uses our digital research infrastructure
services including Reasearch Link Australia.
We will use the information you provide to improve the national research infrastructure and services we
deliver and to report on user satisfaction to the Australian Government’s National Collaborative Research
Infrastructure Strategy (NCRIS) program.
Please take a few minutes to provide your input. The survey closes COB Friday 29 May 2026.
Complete the 5 min survey now by clicking on the link below.
Unraveling the genetic networks of cancer development. Cancer causes nearly 30% of all deaths in Australia and the aging of our population means that its incidence will increase for the foreseeable future. The past two decades of cancer research have yielded great advances in identifying the genetic mutations that contribute to cancer, but our understanding of how these mutations cooperate to transform a healthy cell into a tumour cell remains limited. High-throughput genomic analysis of DNA fro ....Unraveling the genetic networks of cancer development. Cancer causes nearly 30% of all deaths in Australia and the aging of our population means that its incidence will increase for the foreseeable future. The past two decades of cancer research have yielded great advances in identifying the genetic mutations that contribute to cancer, but our understanding of how these mutations cooperate to transform a healthy cell into a tumour cell remains limited. High-throughput genomic analysis of DNA from large numbers of tumours is essential to identify and understand the combinations of cancer mutations that are most deadly. Such studies can form the basis for developing better diagnostics and new treatments for patients whose tumours are resistant to current therapies.Read moreRead less
Redox-Tuneable Sensitisers for Photodynamic Therapy of Malignant and Non-Malignant Proliferative Diseases. Cancer is currently Australia's leading cause of death with 85 231 new cases reported during 2000, costing the health system >$2 billion annually. Photodynamic Therapy is a promising anti-cancer therapy which combines the action of a photosensitising drug and light to destroy tumours. This project will lead to the development of new photosensitisers which will enable the specific targeting ....Redox-Tuneable Sensitisers for Photodynamic Therapy of Malignant and Non-Malignant Proliferative Diseases. Cancer is currently Australia's leading cause of death with 85 231 new cases reported during 2000, costing the health system >$2 billion annually. Photodynamic Therapy is a promising anti-cancer therapy which combines the action of a photosensitising drug and light to destroy tumours. This project will lead to the development of new photosensitisers which will enable the specific targeting of tumours while protecting healthy tissue from damage. Post-treatment skin photosensitivity will be minimised by antioxidant features integrated into the photosensitisers. The development of improved photosensitisers during this project will ultimately lead to improved treatment and new alternatives for Australian cancer sufferers.Read moreRead less
Genetic manipulation of Clostridium sporogenes. The overall objective of this project is to develop genetic methods for the manipulation of the anaerobic bacterium Clostridium sporogenes. Specifically, the project aims to manipulate this microorganism so that genes encoding enzymes that convert prodrugs to anticancer drugs can be introduced and stably maintained on its chromosome. The significance of the project is that the resultant bacteria, and others constructed using these methods, will th ....Genetic manipulation of Clostridium sporogenes. The overall objective of this project is to develop genetic methods for the manipulation of the anaerobic bacterium Clostridium sporogenes. Specifically, the project aims to manipulate this microorganism so that genes encoding enzymes that convert prodrugs to anticancer drugs can be introduced and stably maintained on its chromosome. The significance of the project is that the resultant bacteria, and others constructed using these methods, will then be able to be tested for their ability to act as specific drug delivery systems for use in the treatment of solid tumours.Read moreRead less
Specific gene inhibition through functional genomics and high through-put small molecule screening. This project will utilise functional genomic technologies in an attempt to identify genes in childhood neuroblastoma as potential candidates for the future development of molecular-targeted gene therapy. By screening large 'libraries' of chemical compounds, we aim to identify compounds with the ability to specifically inhibit these gene targets. This project will therefore define novel molecular t ....Specific gene inhibition through functional genomics and high through-put small molecule screening. This project will utilise functional genomic technologies in an attempt to identify genes in childhood neuroblastoma as potential candidates for the future development of molecular-targeted gene therapy. By screening large 'libraries' of chemical compounds, we aim to identify compounds with the ability to specifically inhibit these gene targets. This project will therefore define novel molecular targets and possibly facilitate the future development of new therapeutic approaches to treating neuroblastoma. In addition, the project will develop know-how that can be utilised by both the industry partner and the broader research community and will introduce to Australian science novel techniques and skills. Read moreRead less
Novel Vitamin E Analogues with Enhanced Specificity for Malignant Cells. The aim of this project is to synthesise and characterise novel compounds based on vitamin E succinate that are capable of efficiently and selectively killing cancer cells. The new compounds will be tested for their ability to induce programmed cell death in cancer cells and the most active of them will be also tested for anti-cancer effect in a pre-clinical model. We believe that novel analogues based on vitamin E succinat ....Novel Vitamin E Analogues with Enhanced Specificity for Malignant Cells. The aim of this project is to synthesise and characterise novel compounds based on vitamin E succinate that are capable of efficiently and selectively killing cancer cells. The new compounds will be tested for their ability to induce programmed cell death in cancer cells and the most active of them will be also tested for anti-cancer effect in a pre-clinical model. We believe that novel analogues based on vitamin E succinate can lead to the discovery of very effcient and selective anti-cancer drugs with no side-effects that may be used for patient treatment in the future. This makes our project of exceptional significance.Read moreRead less
Regulation of cell surface sialylation by targeting the CMP-sialic acid transporter and sialyltransferase: Towards the development of anti-metastatic agents. The mortality rates for many of the cancers afflicting the world's population are mirrored in Australia, particularly colon cancer. It's generally accepted that colon cancer, and cancers as a whole, are a significant healthcare issue in this country, representing a major challenge to biomedical researchers and healthcare professional. The e ....Regulation of cell surface sialylation by targeting the CMP-sialic acid transporter and sialyltransferase: Towards the development of anti-metastatic agents. The mortality rates for many of the cancers afflicting the world's population are mirrored in Australia, particularly colon cancer. It's generally accepted that colon cancer, and cancers as a whole, are a significant healthcare issue in this country, representing a major challenge to biomedical researchers and healthcare professional. The economic and social impact is immense, placing a huge strain on the healthcare system, as well as on the families affected. Any alternative treatment reducing cancer metastasis would be of enormous national and international benefit. It's believed that the significant studies outlined in this proposal, which are based on exciting preliminary data, will make a sizeable contribution to achieving this goal.Read moreRead less
Regulation of tissue morphogenesis in reproductive function and metastatic cancer. Infertility, endocrine and metabolic disorders and reproductive cancers are all increasing medical problems and principal contributors to morbidity and mortality in the Australian community. This research takes the novel approach of investigating the mechanisms of dynamic remodeling in reproductive organs. Novel hormonally controlled mechanisms of tissue remodeling unique to reproductive organs and cancers in ad ....Regulation of tissue morphogenesis in reproductive function and metastatic cancer. Infertility, endocrine and metabolic disorders and reproductive cancers are all increasing medical problems and principal contributors to morbidity and mortality in the Australian community. This research takes the novel approach of investigating the mechanisms of dynamic remodeling in reproductive organs. Novel hormonally controlled mechanisms of tissue remodeling unique to reproductive organs and cancers in adults have been discovered. The results are being applied to new medical alternatives for infertile patients and new diagnostics and therapeutics for patients with metastatic cancers. The information is also being applied to improve reproductive efficiency in animal production industries.Read moreRead less
How IGFBP-3 improves cancer cell responsiveness to DNA-damaging therapies. A protein called IGFBP-3 can modulate the way cancer cells respond to treatments such as radiotherapy and certain chemotherapy drugs. These therapies, which act by damaging cells' DNA, play an important role in the treatment of many cancers, but their effectiveness is limited by the ability of cells to oppose the treatment by repairing damaged DNA. This project aims to discover how IGFBP-3 acts to change cancer cells' res ....How IGFBP-3 improves cancer cell responsiveness to DNA-damaging therapies. A protein called IGFBP-3 can modulate the way cancer cells respond to treatments such as radiotherapy and certain chemotherapy drugs. These therapies, which act by damaging cells' DNA, play an important role in the treatment of many cancers, but their effectiveness is limited by the ability of cells to oppose the treatment by repairing damaged DNA. This project aims to discover how IGFBP-3 acts to change cancer cells' response to treatment, using breast cancer cells growing in culture as a model system. This work has the potential to lead to improvements in the treatment of cancer patients by increasing our understanding of what happens when cancer cells are exposed to radio- or chemotherapy.Read moreRead less