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Development of bioengineered 3D tumour models for preclinical breast cancer research

3D organoid model technologies have led to the development of innovative tools for precision medicine in cancer treatment. Yet, the lack of resemblance to native tumours, and the limited ability to test drugs in a high-throughput mode, has limited translation to practice.This project will progress organoid models by using advanced tissue engineering technologies and high-throughput 3D bioprinting to recreate ‘mini-tumours-in-a-dish’ from a patient’s own tumour cells, and study the effects of various components of the tumour microenvironment on drug response.In …

Study level
PhD, Master of Philosophy, Honours
Faculty
Faculty of Health
School
School of Biomedical Sciences
Research centre(s)
Centre for Biomedical Technologies

Multi-microbial 3D printing for screening microbiome functions

The ability to 3D print bacteria has relevance to a wide range of applications, ranging from developing novel anti-microbial modalities to probiotics for promoting human health. Traditional culture techniques used in microbiology such as agar plates and suspension cultures have limited spatio-temporal control over the bacteria microenvironment as well as their interaction partners, in particular, mammalian host cells. This project aims to bridge this technological gap by combining 3D printing and microfluidics technologies to spatially control the localization of multiple …

Study level
PhD, Master of Philosophy
Faculty
Faculty of Health
School
School of Biomedical Sciences
Research centre(s)

Multi-microbial 3D printing for screening microbiome functions

The ability to 3D print bacteria has relevance to a wide range of applications, ranging from developing novel anti-microbial modalities to probiotics for promoting human health.Traditional culture techniques used in microbiology such as agar plates and suspension cultures have limited spatio-temporal control over the bacteria microenvironment as well as their interaction partners - in particular, mammalian host cells. This project aims to bridge this technological gap by combining 3D printing and microfluidics technologies to spatially control the localisation of multiple …

Study level
PhD, Master of Philosophy
Faculty
Science and Engineering Faculty
School
School of Mechanical, Medical and Process Engineering
Research centre(s)

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