Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel ma ....Force-mediated dynamic chemistry in hydrogels. This project aims to develop a new class of biomimetic material, where applied force modulates the chemistry and mechanics by incorporating mechanochemical responsive linkages in hydrogel networks. This work intends to generate new knowledge in the chemistry and mechanical properties of soft materials using an interdisciplinary approach involving synthesis, computational modelling, and mechanical analysis. Expected outcomes include novel hydrogel materials that are mechanochemically active, tough, and fatigue resistant, along with design criteria for force-activated molecule immobilisation and release expected to provide significant benefit forbiomedical applications, additive manufacturing, soft robotics and flexible electronics.Read moreRead less
Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are d ....Precision porous polymer microparticles via integrated flow processes. This project aims at a step-change in functional, porous microparticle manufacture. To achieve this, the project will use precision flow chemistry techniques that will integrate emulsion preparation, microparticle production and chemical functionalisation in one continuous process. The expected outcome of the project is a process for the manufacture of a suite of designer porous polymer microparticles. Expected benefits are disruptive advances in a number of key technological sectors, including biomedicine, pharmacy, energy and bioprocessing. Platform technology for cartilage tissue engineering has been chosen as an exemplar of the power of precision microparticles.Read moreRead less
Biomimetic hydrogels. Hydrogels are promising materials to repair and regenerate damaged tissues, but their weak mechanical properties limit their applications. This project aims to develop hydrogels with better mechanical properties by mimicking the way natural tissues, such as cartilage, work. Specifically, we aim to develop a new class of hydrogels by adding molecular polymer brushes to traditional materials. We will design the hydrogels with long-term stability and render them suitable as vi ....Biomimetic hydrogels. Hydrogels are promising materials to repair and regenerate damaged tissues, but their weak mechanical properties limit their applications. This project aims to develop hydrogels with better mechanical properties by mimicking the way natural tissues, such as cartilage, work. Specifically, we aim to develop a new class of hydrogels by adding molecular polymer brushes to traditional materials. We will design the hydrogels with long-term stability and render them suitable as viable hosts for chondrocytes. Through this project, we will grow fundamental knowledge in polymer chemistry and tissue engineering, and pave the way for new technologies to repair damaged joints and tissues.Read moreRead less