New photobioreactor to up-scale axenic cultures of microalgae. This project aims to deliver a scalable photo-bioreactor for the large scale axenic culture of microalgae to close the technology gap for research and development in the Australian algae biotechnology sector. Algae biotechnology is a rapidly emerging area, particularly in biofuel production. The project aims to test and demonstrate a photo-bioreactor for its applicability to produce sufficient algae biomass to study a low abundance p ....New photobioreactor to up-scale axenic cultures of microalgae. This project aims to deliver a scalable photo-bioreactor for the large scale axenic culture of microalgae to close the technology gap for research and development in the Australian algae biotechnology sector. Algae biotechnology is a rapidly emerging area, particularly in biofuel production. The project aims to test and demonstrate a photo-bioreactor for its applicability to produce sufficient algae biomass to study a low abundance photosynthetic protein complex to advance knowledge of coral bleaching.Read moreRead less
Immobilized biocatalysts on selected filter media to control odour emissions from wastewater treatment and composting facilities. Odour is one of the common problems faced by wastewater and solid waste industries as a result of public complaints about poor local air quality. Although odour removal technologies exist, they encounter a number of problems. The lack of harsh chemicals required for the proposed technology means there is no wastewater stream to treat. This will have an impact on the r ....Immobilized biocatalysts on selected filter media to control odour emissions from wastewater treatment and composting facilities. Odour is one of the common problems faced by wastewater and solid waste industries as a result of public complaints about poor local air quality. Although odour removal technologies exist, they encounter a number of problems. The lack of harsh chemicals required for the proposed technology means there is no wastewater stream to treat. This will have an impact on the reduction of chemicals disposed to the environment, preventing unnecessary contamination of land and water resources. The lower space requirement of the technology will free up land, formerly required for large biofilters, for other uses including civic amenities.Read moreRead less
Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of el ....Synthetic Biology Derived Electroactive Whole Cell Microbial Biosensors. The aim of this project is to develop, using synthetic biology, electrically integrated microbial biosensors for the detection of heavy metals in the environment. Building on our existing technology, this project aims to produce novel ‘biobricks’ capable of electrically integrating electric microbes into real time environmental monitors for heavy metal contaminants. This expansion of synthetic biology, and integration of electric bacteria into sensor systems, will result in a new platform technology that expands our abilities to protect the ecology, agriculture and health of terrestrial, marine and agricultural at risk areas from economic and environmental damage.Read moreRead less
Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iro ....Developing and testing a novel biological reduction cell to remediate heavy metal and acid-containing industrial and mine leachates. Echo Remediation Ltd. has a new reduction cell that uses sulfur and bacteria to remove heavy metals and acidity from mine leachates, but development is now required to make it viable. The project aims to optimise the process using molecular approaches to study the effects of operating conditions on the bacterial communities. As part of the investigation, active iron reducers will be selected and introduced to the cell (in conjunction with chemical amendments) and their colonization monitored. The new technology once developed has the potential to be used at mine sites in Australia and overseas and its employment offers a sustainable, biological "green" approach to mine waste remediation.Read moreRead less
New drugs against parasitic nematodes of livestock animals. New drugs against parasitic nematodes of livestock animals. This project aims to develop an innovative technology platform to deliver novel anti-infectives as biotechnological outcomes, using postgenomics, computing and chemistry. Advanced molecular, computer and chemistry technologies provide unprecedented opportunities to design radically new interventions against socioeconomically important infectious diseases affecting billions of a ....New drugs against parasitic nematodes of livestock animals. New drugs against parasitic nematodes of livestock animals. This project aims to develop an innovative technology platform to deliver novel anti-infectives as biotechnological outcomes, using postgenomics, computing and chemistry. Advanced molecular, computer and chemistry technologies provide unprecedented opportunities to design radically new interventions against socioeconomically important infectious diseases affecting billions of animals worldwide. Anticipated outcomes are the design of radically new chemotherapies to control parasitic diseases, the translation of fundamental research into biotechnological outcomes, international visibility of Australian science, and a solid skills- and knowledge-base in veterinary drug development.Read moreRead less
Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the u ....Exploiting bacterial metal resistance machinery for metal ion nano-biosensors development. This project aims to integrate advanced materials chemistry, molecular biology, bio-electrochemical and synchrotron imaging approaches to understand the role of silver resistance machinery of bacteria in their ability to form silver nanoparticles. This aims to enable discovery of new metal-specific reductase enzymes. The fundamental biomolecular understanding of bacterial silver resistance will allow the use of a silver-binding protein to develop a series of next-generation nano-biosensors. These biosensing platforms will provide high-throughput, cost-effective, selective, sensitive and continuous monitoring of heavy metal ions in effluents from mining and mineral processing industries in a real-time fashion.Read moreRead less
Microbial infestation of pre-painted steel building materials: chemical and microbial characterization, model development and control strategies. Coated steel building materials are a multi-billion dollar Australian industry. Microorganisms form slime layers on those materials, which are unsightly and reduce their energy benefits. The project will identify the problem organisms, the factors that facilitate their growth and will develop novel biofilm resistant, functional building materials.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100121
Funder
Australian Research Council
Funding Amount
$384,671.00
Summary
Genomic library infrastructure for ancient environmental samples. This project aims to enable automated genome recovery from diverse environmental samples, without contamination risk. For more than 100 years, environmental scientists have studied diverse organism / environment interactions using a variety of conceptual and technical tools. Recently, studies of ancient and historical DNA have come to complement these tools and to occupy a significant place in environmental studies conducted over ....Genomic library infrastructure for ancient environmental samples. This project aims to enable automated genome recovery from diverse environmental samples, without contamination risk. For more than 100 years, environmental scientists have studied diverse organism / environment interactions using a variety of conceptual and technical tools. Recently, studies of ancient and historical DNA have come to complement these tools and to occupy a significant place in environmental studies conducted over serial time. The project’s addition to the existing dual Ancient DNA complex facility at Griffith University will comprise two liquid handling workstations, each being housed in separate, self-contained, ancient DNA laboratories. The new facility will enable many researchers to have unprecedented access to an ancient DNA facility and a high level of technical support.Read moreRead less
Identification of new antibacterial agents that inhibit type III secretion. The development of new antibacterial drugs is an unmet global health priority. This project will investigate several plant-derived compounds that have been found to display promising antibacterial activity. This project has the potential to identify compounds that may result in a new antibiotic therapy.
Novel biodiagnostic platforms for human metabolites. The innovative biosensor technologies developed in this project will be utilised at first by Australian athletes, enabling them to better monitor physiological conditions during training and thereby help maintain international competitiveness. Real-time sensing of lactate and other metabolites in athletes using advanced biomaterials coupled to frontier telemetry protocols for remote sensing will be extendable to bio-diagnostic needs in human h ....Novel biodiagnostic platforms for human metabolites. The innovative biosensor technologies developed in this project will be utilised at first by Australian athletes, enabling them to better monitor physiological conditions during training and thereby help maintain international competitiveness. Real-time sensing of lactate and other metabolites in athletes using advanced biomaterials coupled to frontier telemetry protocols for remote sensing will be extendable to bio-diagnostic needs in human health care and have significant social and economic benefits. Australia's international position in the application of interfacial science and nanomaterials for outcomes in biomedical engineering will be strengthened. Read moreRead less