Dr Frankie Rawson is an accomplished cross-disciplinary scientist who has made significant contributions at the intersection of bioelectronics, biosensors, bioelectricity, and electrochemistry.
Dr Frankie Rawson holds a diverse academic background with expertise in bioelectronics, biosensors, bioelectricity, and electrochemistry. Their multidisciplinary approach combines principles from biology, electronics, and electrochemistry to develop innovative solutions for understanding and manipulating biological systems.
Bioelectronic Devices: Frankie Rawson has been at the forefront of developing bioelectronic devices that interface with biological systems. Their research involves designing and fabricating novel electronic devices capable of interacting with living cells, tissues, or organisms. These devices have applications in areas such as neurobiology, regenerative medicine, and bioelectronic medicine.
Biosensors and Bioelectricity: Frankie Rawson has made significant contributions to the field of biosensors, particularly in the development of sensitive and selective detection platforms. Their research focuses on leveraging bioelectricity and electrochemical techniques to detect and quantify biomolecules of interest. These biosensors have potential applications in healthcare diagnostics, environmental monitoring, and food safety.
Electrochemical Methods in Biological Systems: Frankie Rawson's expertise extends to the application of electrochemical methods for studying biological systems. They have developed innovative electrochemical techniques to investigate the redox processes and electron transfer mechanisms involved in biological reactions. Their research has shed light on important biochemical processes and has implications for fields such as enzymology, metabolic engineering, and bioenergetics.
Collaborative Research: Frankie Rawson actively collaborates with scientists from various disciplines, including biologists, chemists, engineers, and medical researchers. Their cross-disciplinary approach fosters collaborations that drive innovation and lead to the development of integrated solutions for complex biological challenges.
Impact and Future Directions: Dr Frankie Rawson's research has had a significant impact on the fields of bioelectronics, biosensors, bioelectricity, and electrochemistry. Their work has advanced our understanding of the interface between biology and electronics, enabling the development of cutting-edge technologies and techniques for monitoring and manipulating biological systems. Frankie's contributions have the potential to revolutionize fields such as healthcare, personalized medicine, and bioengineering.
Dr Frankie Rawson's expertise as a cross-disciplinary scientist in bioelectronics, biosensors, bioelectricity, and electrochemistry has positioned them as a leading figure in these interdisciplinary fields. Their research accomplishments, development of bioelectronic devices, advancements in biosensing technologies, and innovative approaches to studying electrochemical processes in biological systems have made a lasting impact. Dr Frankie Rawson's work continues to push the boundaries of scientific knowledge and holds great promise for transformative applications in various domains.
Dr Rawson's research is truly multidisciplinary spanning the chemical-biology interface. Therefore, his expertise spans multiple disciplines, including Electrochemistry, Cell Surface Biochemistry, Bionanotechnology, Surface Chemistry, Electroceutics, Functional Materials and Biosensors, and Bioelectronics.
Dr Rawson teaches on the Pharmacy module Medical Diagnostics (B34MED) and Masters in Bioengineering module Biomedical Applications of Biomaterials (MM4BAB)
His research interests are to develop smart novel bioelectronic nano-system for studying and controlling cellular processes on a molecular scale. This involves fundamental studies of charge transfer… read more
BUNTY SHARMA, AKHIL JAIN, LLUISA PEREZ-GARCIA, JULIE A WATTS, FRANKIE JAMES RAWSON and GANGA RAM CHAUDHARY, 2022. Metallocatanionic vesicles mediated enhanced singlet oxygen generation and photodynamic therapy of cancer cells Journal of Material Chemistry B. MECHELLE R. BENNETT, CARA MOLONEY, FRANCESCO CATRAMBONE,, FEDERICO TURCO, BENJAMIN MYERS, KATALIN KOVACS, PHILIP J. HILL, CAMERON ALEXANDER, FRANKIE J. RAWSON and PRATIK GURNANI, 2022. Oxygen-Tolerant RAFT Polymerization Initiated by Living Bacteria ACS Macro Letters. 11(8), 954–960 PAOLA SANJUAN-ALBERTE, CHARLIE WHITEHEAD, JOSHUA N. JONES,, JOÃO C. SILVA, NATHAN CARTER, SIMON KELLAWAY, RICHARD J.M. HAGUE, JOAQUIM M.S. CABRAL, FREDERICO C. FERREIRA, LISA J. WHITE and FRANKIE J. RAWSON, 2022. Printing biohybrid materials for bioelectronic cardio-3D-cellular constructs iScience. 15(7), 104552
BEN MYERS, PHIL HILL, FRANKIE J. RAWSON and KATALIN KOVACS, 2022. Enhancing Microbial Electron Transfer Through Synthetic Biology and Biohybrid Approaches Johnson Matthey Technology Review.
His research interests are to develop smart novel bioelectronic nano-system for studying and controlling cellular processes on a molecular scale. This involves fundamental studies of charge transfer from prokaryotic and eukaryotic cells in addition to break through methodologies of surfaces functionalization and control on the nano-scale.
Current projects underway include:
Hijacking transplasma membrane electron transport systems (EPSRC)
Electrochemical differentiation of cell states (BBSRC)
Interfacing cells with electrocatalytic sensors for real-time cell communication (Leverhulme Trust)
Advanced manufacturing of macroporous nanoelectronic artificial functional scaffolds for synthetic tissues