Enhancing Selectivity and Detection in Miniaturised Analytical Separation Systems. Miniaturisation-compatible stationary phases and detection techniques will be developed for microseparation techniques of capillary electrochromatography and chip-based separation systems, and their analytical applications will be investigated. Replaceable stationary phases (RSP) of chromatographic particles suspended in reversible gels will be created by delivering a liquid RSP to the column followed by in situ ....Enhancing Selectivity and Detection in Miniaturised Analytical Separation Systems. Miniaturisation-compatible stationary phases and detection techniques will be developed for microseparation techniques of capillary electrochromatography and chip-based separation systems, and their analytical applications will be investigated. Replaceable stationary phases (RSP) of chromatographic particles suspended in reversible gels will be created by delivering a liquid RSP to the column followed by in situ immobilisation. This approach offers flexibility in optimising a number of parameters of the column and of its use for sample pre-treatment and preconcentration. Pulsed potentiometric detection will be developed for the abovementioned microseparation techniques, combining the advantages of pulsed amperometric techniques with the more universally responding potentiometric detection.Read moreRead less
Self-assembled nanolayers of functionalised latexes as selective and adaptable nano-stationary phases in separation science. A new approach is proposed for the design and synthesis of functionalised ion-exchange stationary phases for analytical nano-separation methods. Desired charged functional groups are first affixed chemically onto nanometre sized latex particles and these particles are then self-assembled mechanically as monoloayer coatings onto a suitable supporting template such as fused ....Self-assembled nanolayers of functionalised latexes as selective and adaptable nano-stationary phases in separation science. A new approach is proposed for the design and synthesis of functionalised ion-exchange stationary phases for analytical nano-separation methods. Desired charged functional groups are first affixed chemically onto nanometre sized latex particles and these particles are then self-assembled mechanically as monoloayer coatings onto a suitable supporting template such as fused silica, monolithic silica or polymer beds, microfibres or microtubes, and channels in microchips. The resultant coated surface then acts as a highly efficient ion-exchange stationary phase which will be used in a wide range of separation technologies including ion chromatography, capillary electrophoresis, capillary electrochromatography and solid-phase microextraction.Read moreRead less
Separation science based on nanoparticle-coated monolithic scaffold stationary phases. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pre-and post-blast identification of explosives in counter-ter ....Separation science based on nanoparticle-coated monolithic scaffold stationary phases. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pre-and post-blast identification of explosives in counter-terrorism applications; environmental, clinical, and forensic analysis; energy generation and foods. The project will also lead to very significant new intellectual property having extremely high commercial potential worldwide, and thereby generates the promise of considerable direct financial returns to Australia.Read moreRead less
Integrated microfluidic device for the direct analysis of drugs and metabolites in biological fluids. Due to the way in which multiple processes are integrated in a micro Total Analysis System (µTAS), they offer substantial advantages over current technology, in terms of speed, cost of analysis, portability and operator simplicity and safety. This has considerable potential benefit for Australia, specifically for the remote and rural analysis of drugs and metabolites in biological fluids such a ....Integrated microfluidic device for the direct analysis of drugs and metabolites in biological fluids. Due to the way in which multiple processes are integrated in a micro Total Analysis System (µTAS), they offer substantial advantages over current technology, in terms of speed, cost of analysis, portability and operator simplicity and safety. This has considerable potential benefit for Australia, specifically for the remote and rural analysis of drugs and metabolites in biological fluids such as blood, serum, urine and saliva. These devices will have application for point-of-care testing in therapeutic drug monitoring, which will improve medical treatment and the patient's quality of life, as well as for on-site analysis in forensics for the rapid determination of illicit drugs and performance enhancing substances in our elite athletes.
Read moreRead less
Towards Microfluidic-Based Advanced Remote Analysis. The research under this project will establish and systematically develop Advanced Remote Analysis as a new inter-disciplinary area and establish a leadership role for Australia. By addressing pressing needs such as monitoring the environment, remote medical diagnostics, advancing Australian science and technology, or monitoring for traces of explosives, this project falls directly into all four of the National Research Priorities with applica ....Towards Microfluidic-Based Advanced Remote Analysis. The research under this project will establish and systematically develop Advanced Remote Analysis as a new inter-disciplinary area and establish a leadership role for Australia. By addressing pressing needs such as monitoring the environment, remote medical diagnostics, advancing Australian science and technology, or monitoring for traces of explosives, this project falls directly into all four of the National Research Priorities with applications addressing corresponding Priority Goals. Other areas benefiting from the outcomes of this project will be remote monitoring of agricultural production including living species, and a number of other industries such as biotechnology, mineral processing, power generation etc.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989491
Funder
Australian Research Council
Funding Amount
$172,025.00
Summary
Multi-Purpose Mass Spectrometry Facility. The Australian Centre for Research on Separation Science (ACROSS) has been established using focused research themes to provide both fundamental and applied research outcomes in separation science. The requested Time of Flight Mass Spectrometer (TOFMS) will be utilised extensively by a large team of researchers working across the broad areas of analytical chemistry, pharmaceutical science, materials science, biochemistry, microfluidics, industrial chemi ....Multi-Purpose Mass Spectrometry Facility. The Australian Centre for Research on Separation Science (ACROSS) has been established using focused research themes to provide both fundamental and applied research outcomes in separation science. The requested Time of Flight Mass Spectrometer (TOFMS) will be utilised extensively by a large team of researchers working across the broad areas of analytical chemistry, pharmaceutical science, materials science, biochemistry, microfluidics, industrial chemistry and hydrometallurgy, aquaculture, forensic analysis, Antarctic studies, and environmental monitoring. This will directly support our work falling under National Research Priorities 1 An Environmentally Sustainable Australia, 2 Promoting and Maintaining Good Health, 3 Frontier Technologies for Building and Transforming Australian Industries, and 4 Safeguarding Australia.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668471
Funder
Australian Research Council
Funding Amount
$262,706.00
Summary
Hyphenated Capillary Electrophoresis - Mass Spectrometry Facility. The requested funding will facilitate the expansion of the activities of the University of Tasmania (UTas) node of the Australian Centre for Research on Separation Science and its collaborators. This initiative will involve the application of integrated, high resolution technologies for the separation and identification of complex chemical and biological samples. The instrument is to be shared by a number of highly research-activ ....Hyphenated Capillary Electrophoresis - Mass Spectrometry Facility. The requested funding will facilitate the expansion of the activities of the University of Tasmania (UTas) node of the Australian Centre for Research on Separation Science and its collaborators. This initiative will involve the application of integrated, high resolution technologies for the separation and identification of complex chemical and biological samples. The instrument is to be shared by a number of highly research-active groups at UTas in the fields of chemistry, biochemistry, plant and agricultural science, Antarctic studies, and pharmacy where detailed structural identification of components separated from complex mixtures is essential. These projects all focus on fundamental and applied research of great national significance.Read moreRead less
Synthesis, characterisation and evaluation of novel ion-exchange polymer monolithic stationary phases for separation science. This project will provide highly significant, fundamental advances in separation science by accelerating the design and development of new stationary phases and separation technologies suitable for the analysis of very complex samples. The project will lead to very significant new intellectual property having extremely high commercial potential worldwide, and therefore t ....Synthesis, characterisation and evaluation of novel ion-exchange polymer monolithic stationary phases for separation science. This project will provide highly significant, fundamental advances in separation science by accelerating the design and development of new stationary phases and separation technologies suitable for the analysis of very complex samples. The project will lead to very significant new intellectual property having extremely high commercial potential worldwide, and therefore the project has potential for considerable direct financial returns to Australia. The new technologies will be applied in a wide range of areas of national importance including pre-and post-blast identification of explosives in counter-terrorism applications; environmental, clinical, and forensic analysis; energy generation and foods. Read moreRead less
In-line SPE-CE for the direct determination of drugs and metabolites in biological fluids based on porous polymer monoliths. A new approach is proposed for the development of novel micro- and nano-scale solid-phase adsorbent materials. These materials are based on porous polymer monoliths formed in situ within a capillary acting as a mould. The allows the material to be readily placed in a defined position, in a process similar to photo-patterning, and alleviates many of the problems usually as ....In-line SPE-CE for the direct determination of drugs and metabolites in biological fluids based on porous polymer monoliths. A new approach is proposed for the development of novel micro- and nano-scale solid-phase adsorbent materials. These materials are based on porous polymer monoliths formed in situ within a capillary acting as a mould. The allows the material to be readily placed in a defined position, in a process similar to photo-patterning, and alleviates many of the problems usually associated with fabrication and miniaturisation. A simple photo-grafting process, initiated by UV light can be used for the selective chemical modification of these materials. These tailored monoliths can then be used for the in-line coupling of biological sample handling and capillary electrophoresis (CE) for the determination of drugs and related metabolites in biological fluids, thus avoiding time-consuming and costly off-line sample pre-treatment. This will lead to the development of new methods for the rapid determination of drugs, metabolites and other small molecules in clinical samples.Read moreRead less
Probing the Tasmanian Devil Serum Proteome for Preclinical Diagnosis of Devil Facial Tumour Disease. The Tasmanian Devil (Sarcophilus harrisii) is a carnivorous marsupial endemic to the island state of Tasmania, and is found all over the state. Over the past decade, a dramatic decline has occurred in the Devil population in association with the emergence of Devil Facial Tumour Disease (DFTD). This project aims to develop a preclinical diagnostic test for DFTD that will provide vital information ....Probing the Tasmanian Devil Serum Proteome for Preclinical Diagnosis of Devil Facial Tumour Disease. The Tasmanian Devil (Sarcophilus harrisii) is a carnivorous marsupial endemic to the island state of Tasmania, and is found all over the state. Over the past decade, a dramatic decline has occurred in the Devil population in association with the emergence of Devil Facial Tumour Disease (DFTD). This project aims to develop a preclinical diagnostic test for DFTD that will provide vital information for use in developing management strategies to ensure the ongoing survival of the Tasmanian Devil. The benefit to Australia in performing this research rests in the new technology that will be developed and the application of this technology to key areas of national and international significance.Read moreRead less