Selectivity enhancement in separation science using responsive materials. Increasing public demand for quality products from the chemical, pharmaceutical, biotechnology and food industries requires access to innovative methods of chemical analysis. This project will establish a new class of separation materials of enhanced selectivity and resolving power for the fast, sensitive and reliable analysis of these products.
Micro-electrofluidic platforms for monitoring 3D human biological models. The ability to study living cells and human biological models (cell cultures) delivers greater understanding of basic biological function and response to applied (bio)chemical stimuli. Creating the physical environments to sustain biological models, and mimic natural conditions and fluidic pathways, is immensely challenging, yet essential to deliver meaningful observational data. This project will deliver this capability t ....Micro-electrofluidic platforms for monitoring 3D human biological models. The ability to study living cells and human biological models (cell cultures) delivers greater understanding of basic biological function and response to applied (bio)chemical stimuli. Creating the physical environments to sustain biological models, and mimic natural conditions and fluidic pathways, is immensely challenging, yet essential to deliver meaningful observational data. This project will deliver this capability through the convergence of expertise and innovation in analytical chemistry, materials science and cellular biology, ultilising the latest technology and understanding of 3D micro/electrofluidics, to enable the study and stimulation of advanced biological models, sustained within precisely controlled 3D micro-environments.Read moreRead less
Resolving dissolved organic matter: new multi-dimensional separation approaches. To fully understand and model global carbon cycles the source, nature and fate of oceanic dissolved organic carbon is an essential element. This project will develop, model and apply new orthogonol and complementary separation science based technologies to further the comprehensive characterisation and understanding of these complex systems.
Lectin based open tubular micro-reactors for probing protein-protein binding. This project seeks to develop non-invasive technology for the measurement and quantitation of lectin-carbohydrate binding events, in the first instance glycopeptides and glycoproteins. The goal is not only to provide accurate protein-protein association and dissociation constant data within the developed system, but to do so within an enclosed micro-fluidic environment, with the added advantages of also providing ‘trap ....Lectin based open tubular micro-reactors for probing protein-protein binding. This project seeks to develop non-invasive technology for the measurement and quantitation of lectin-carbohydrate binding events, in the first instance glycopeptides and glycoproteins. The goal is not only to provide accurate protein-protein association and dissociation constant data within the developed system, but to do so within an enclosed micro-fluidic environment, with the added advantages of also providing ‘trap and release’ extraction capabilities, and being easily coupled to both chromatographic and mass spectrometry systems. Read moreRead less
Polymer Inclusion Membranes for Electrokinetic Sampling and Separation. This proposal aims to understand the chemical and physical properties governing the transport of ions into and within advanced extracting polymeric materials, known as polymer inclusion membranes, under the influence of an applied voltage. These membranes are dry-to-touch and represent a new and potentially powerful analytical platform for environmental, medical and industry sample preparation. By understanding the transport ....Polymer Inclusion Membranes for Electrokinetic Sampling and Separation. This proposal aims to understand the chemical and physical properties governing the transport of ions into and within advanced extracting polymeric materials, known as polymer inclusion membranes, under the influence of an applied voltage. These membranes are dry-to-touch and represent a new and potentially powerful analytical platform for environmental, medical and industry sample preparation. By understanding the transport mechanism, new membranes will be developed, capable of purifying and concentrating diverse targets chemicals from liquid and solid samples. These processes can take place during sample transportation to a centralised laboratory thus simplifying and streamlining analysis upon arrival to decrease drastically its costs.Read moreRead less
A field-portable comprehensive multidimensional gas chromatograph. This project represents an innovative new direction for chemical analysis of environmental contaminants with further case studies planned in a number of diverse application areas. State-of-the-art field-portable instrumentation will be developed to bridge the capability gap for performing in-field analysis of highly complex samples.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100018
Funder
Australian Research Council
Funding Amount
$630,000.00
Summary
Purchase of a high resolution Nuclear Magnetic Resonance spectrometer with liquid chromatography module. A high resolution Nuclear Magnetic Resonance spectrometer and liquids separation module will support Tasmanian research of international significance across the biological and medical sciences, chemistry and Tasmanian industries including profiling studies in human health, plant biology, molecular basis of disease and complex mixture analysis.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100059
Funder
Australian Research Council
Funding Amount
$350,790.00
Summary
Advanced high resolution biomolecular analysis facility for Tasmania. This project aims to establish an advanced, multi-purpose mass spectrometry platform for high-throughput and targeted biomolecular analysis, including proteomics and metabolomics. The purpose of the project is to provide a centralised state-of-the-art facility that supports research programs in plant science, agricultural research, food safety, animal and human health research and separation science. Potential benefits from th ....Advanced high resolution biomolecular analysis facility for Tasmania. This project aims to establish an advanced, multi-purpose mass spectrometry platform for high-throughput and targeted biomolecular analysis, including proteomics and metabolomics. The purpose of the project is to provide a centralised state-of-the-art facility that supports research programs in plant science, agricultural research, food safety, animal and human health research and separation science. Potential benefits from the project include increased agricultural productivity and food security, improved knowledge of age and injury-related changes in neurophysiology, helping to prevent the extinction of iconic Tasmanian wildlife and the development of advanced micro-electroseparation technologies.Read moreRead less
Polymer nanoparticles and their assembled supracolloidal monolithic structures for applications in separation science. This project will generate new polymeric materials that will improve the analysis of complex samples. This will be applied in a wide range of areas of national importance including: pharmaceutical analysis and drug discovery; environmental, clinical and forensic analysis; and energy generation and foods.
Hierarchically porous polymer monoliths for separation science. Understanding the molecular composition of biomarkers involved in cell-cell communication and the fate of nanoparticles in the environment is critical to improve our understanding of diseases and environmental processes. This project will develop a new approach for the design of separation media that will greatly improve the efficiency of techniques used to analyse these complex samples. The separation media will consist of a polyme ....Hierarchically porous polymer monoliths for separation science. Understanding the molecular composition of biomarkers involved in cell-cell communication and the fate of nanoparticles in the environment is critical to improve our understanding of diseases and environmental processes. This project will develop a new approach for the design of separation media that will greatly improve the efficiency of techniques used to analyse these complex samples. The separation media will consist of a polymer containing large flow-through pores as well as well-defined mesopores. This dual porous skeleton will allow for the size-based separation of biomarkers and nanoparticles. The new separation media will enable the development of new technologies with applications in areas such medicine and environmental science.Read moreRead less