Dr Stuart Higgins is a Research Associate in the Departmental of Materials at Imperial College London. He works within the group of Prof. Molly Stevens, focusing on the microfabrication of innovative materials for biomedical applications.
Stuart holds a CRUK Early Detection Primer Award to investigate organic bioelectronic sensors for the early detection of breast cancer in blood samples. He also works on the fabrication of nanostructured surfaces that can be used to study cell-biomaterial interfaces. This work uses cell-based image profiling to allow the changes in hundreds of thousands of cells to be measured, quantified, and modelled.
Previously, his research has included exploring the fabrication of flexible electronics based on organic semiconductors. He developed organic field-effect transistors for use in flexible displays and complementary logic circuits, and organic diodes for high-performance energy harvesting systems for wireless smart packaging.
Before joining the Stevens Group, Stuart was a Research Associate in the group of Prof. Henning Sirringhaus in the Cavendish Laboratory at the University of Cambridge. He completed his PhD under the supervision of Prof. Alasdair Campbell in the Department of Physics at Imperial College London. He graduated from Imperial College London with an MSci degree in Physics, during which he spent a year working at the Max Planck Institute for Nuclear Physics in Germany under the supervision of Priv.-Doz. Dr. José Ramón Crespo López-Urrutia.
Stuart produces the award-winning podcast, Scientists not the Science, which explores the culture of working in science, and created the project Science in the Supermarket, which aims to bring engagement activities into neutral third spaces such as supermarkets, promoting the benefits of studying STEM subjects to young people.
et al., 2022, Polysaccharide-polyplex nanofilm coatings enhance nanoneedle-based gene delivery and transfection efficiency, Small, ISSN:1613-6810
et al., 2022, Block length-dependent protein fouling on Poly(2-oxazoline)-based polymersomes: influence on macrophage association and circulation behavior, Small, ISSN:1613-6810
et al., 2022, Coarse-grained simulations suggest potential competing roles of phosphoinositides and amphipathic helix structures in membrane curvature sensing of the AP180 N-terminal homology domain, The Journal of Physical Chemistry B: Biophysical Chemistry, Biomaterials, Liquids, and Soft Matter, Vol:126, ISSN:1520-5207, Pages:2789-2797
et al., 2022, Coarse-grained simulations suggest phosphoinositides and amphipathic helix structure play opposing roles in membrane curvature sensing of the AP180 N-terminal homology domain, The Journal of Physical Chemistry B: Biophysical Chemistry, Biomaterials, Liquids, and Soft Matter, ISSN:1520-5207
et al., 2022, Novel endosomolytic compounds enable highly potent delivery of antisense oligonucleotides, Communications Biology, Vol:5, ISSN:2399-3642