This book provides researchers and professionals in the area of biomedical photonics with a toolbox of novel methodologies for biomedical applications, including health diagnostics, cancer detection and treatment.
Advanced photonics methods for biomedical applications give researchers in universities and industries, and clinicians an overview of the novel tools for cancer diagnostics and treatment. This book provides researchers and professionals in the area of biomedical photonics with a toolbox of novel methodologies for biomedical applications, including health diagnostics, cancer detection, and treatment. It covers the theory, modeling, and design of each method, alongside their applications, fabrication, characterization, and measurements in clinical practice. A wide scope of concepts concerning innovative science and technologies of medicine will be covered, providing the readers with the latest research, developments, and technologies. It will also be a valuable resource for students and early-career researchers, alongside those involved in the design of the novel photonics-based techniques for health diagnostics and cancer detection and treatment.
Key features
Discusses novel methods of cancer diagnostics and cancer treatment.
Details non and minimally invasive photonics techniques.
Explores the applications of machine learning and artificial intelligence to these novel techniques.
1. In Vivo Fluorescence Measurements of Biological Tissue Viability.
2. The Discrete Analysis of the Tissue Biopsy Images with Metamaterial Formalisation.
3. Biomedical Applications of Terahertz Radiation.
4. Polarimetric and Spectral Imaging Approach for Meat Quality Control and Characterization of Biological Tissues.
Edik Rafailov received the PhD degree from the Ioffe Institute in 1992. In 1997 he moved to St Andrews University (UK) and in 2005 he established a new group at Dundee University. In 2014 he and his Optoelectronics and Biomedical Photonics Group moved to Aston University (UK). He has authored and co-authored over 450 articles in refereed journals and conference proceedings, including two books, ten invited chapters, and numerous invited talks. He coordinated the 14.7M FP7 FAST-DOT project development of new ultrafast lasers for biophotonics applications and the 12.5M NEWLED project, which aims to develop a new generation of white LEDs. He coordinates the H2020 FET Mesa-Brain (which aims to develop 3D nano-printing technology for functional three-dimensional human stem cell-derived neural networks), NEUROPA (which aims to develop novel non-invasive theragnostic approaches), the H2020 PLATFORMA project, and the EPSRC (EP/R024898/1 proposal. He also leads a few other projects funded by the EU and EPSRC (UK). His current research interests include high-power CW and ultrashort-pulse lasers; generation of UV/visible/IR/MIR and THz radiation nanostructures; nonlinear and integrated optics; and biomedical photonics.
Tatjana Grics research career has been focused on the investigation of waveguide devices (waveguide modulators, filters etc.), namely on proposing their electrodynamical analysis. Applied research includes the design of microwave frequency selective structures, waveguide modulators, and filters. Fundamental research is primarily concerned with developing rigorous computational methods for the electrodynamical analysis of the waveguide structures. Another major goal of her studies is plasmonics as the examination of the interaction between electromagnetic field and free electrons in a metal. The optically active nanostructures have been simulated and their fundamental photonic properties have been explored. Moreover, the broad scope of research carried out by Dr. Gric has included investigations into the new fascinating properties of novel materials. Dr. Gric is involved in development of unusual materials and structures that can manipulate the flow of light in ways that are useful in optical sensing, photovoltaics, solid-state lighting, fiber optics, and other applications. Dr. Gric has published extensively in her field of investigation with more than 50 peer-reviewed papers in top journals in physics, electrodynamics, and optics and has written one book and two book chapters. It is worth noting that her recent publication rate as the first author is increasing.
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