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DNA nanotechnology for controlled antigen presentation to T cells. The project aims to present individual antigens to T cells and to image T cell receptor signalling with single molecule microscopy. Combining DNA origami nanotechnology with single molecule imaging should reveal the sensitivity of T cell signalling. A DNA force sensor will determine whether mechanical forces contribute to antigen discrimination. The project will use the nanotechnology strategy to identify antigen-specific T cells ....DNA nanotechnology for controlled antigen presentation to T cells. The project aims to present individual antigens to T cells and to image T cell receptor signalling with single molecule microscopy. Combining DNA origami nanotechnology with single molecule imaging should reveal the sensitivity of T cell signalling. A DNA force sensor will determine whether mechanical forces contribute to antigen discrimination. The project will use the nanotechnology strategy to identify antigen-specific T cells in tissue. The project is expected to advance understanding of T cell biology, and contribute to DNA nanotechnology and super-resolution microscopy whilst providing fundamental insights into antigen recognition by T cells and ultimately derive clinically relevant practical applications.Read moreRead less
Tuning Molecular Translocaton by Close-Field Electroporation. This project aims to determine the underlying mechanisms by which DNA and other molecules are able to migrate across the cell membrane in response to highly localised electric fields. It has recently been shown that focusing of electric fields at the cellular level, using an array of small electrodes, results in unexpectedly high cell transfection efficiencies. It has been termed 'close-field electroporation'. Here it is proposed t ....Tuning Molecular Translocaton by Close-Field Electroporation. This project aims to determine the underlying mechanisms by which DNA and other molecules are able to migrate across the cell membrane in response to highly localised electric fields. It has recently been shown that focusing of electric fields at the cellular level, using an array of small electrodes, results in unexpectedly high cell transfection efficiencies. It has been termed 'close-field electroporation'. Here it is proposed to establish the properties of the electric fields around cells and cell membrane interactions with these fields that enable molecular translocation. This fundamental science could have broad implications in the domains of drug delivery, gene therapy and neural stimulation.Read moreRead less