Applications of Nanoscience in Photomedicine

Michael R. Hamblin (Redaktør) ; Pinar Avci (Redaktør)

Nanoscience has become one of the key growth areas in recent years. It can be integrated into imaging and therapy to increase the potential for novel applications in the field of photomedicine. In the past commercial applications of nanoscience have been limited to materials science research only, however, in recent years nanoparticles are rapidly being incorporated into industrial and consumer products. Les mer
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Om boka

Nanoscience has become one of the key growth areas in recent years. It can be integrated into imaging and therapy to increase the potential for novel applications in the field of photomedicine. In the past commercial applications of nanoscience have been limited to materials science research only, however, in recent years nanoparticles are rapidly being incorporated into industrial and consumer products. This is mainly due to the expansion of biomedical related research and the burgeoning field of nanomedicine. Applications of Nanoscience in Photomedicine covers a wide range of nanomaterials including nanoparticles used for drug delivery and other emerging fields such as optofluidics, imaging and SERS diagnostics. Introductory chapters are followed by a section largely concerned with imaging, and finally a section on nanoscience-enabled therapeutics.

Fakta

Innholdsfortegnelse

Introduction; Lab on a chip; SERS diagnostics; Optofluidics; Chemical imaging; Wide field diagnostic imaging;
Plasmonic bubbles; Gold nanoparticles; Quantum dots; Fluorescent nanoparticles for cancer imaging; Photoacoustics imaging; Photo-controlled nanoparticles; Nanocells for PDT; Chlorophyll-based multifunctional nanoparticles; Smart nanoprobes; Silica-based nanoparticles; Nanoparticles/light/gene delivery; Bucky balls;
Gold nanorods; Targeted gold nanoshells; Porphysomes; Graphene/SWCNT; Optogenetics; Self-lighting nanoparticles for PDT; Nano-drug delivery vehicles for PDT; Upconverting nanoparticles; Light activated antimicrobial nanoparticles

Om forfatteren

Michael R Hamblin Ph.D. is a Principal Investigator at the Wellman Center for Photomedicine at Massachusetts General Hospital, an Associate Professor of Dermatology at Harvard Medical School and is a member of the affiliated faculty of the Harvard-MIT Division of Health Science and Technology. He was trained as a synthetic organic chemist and received his PhD from Trent University in England. His research interests lie in the areas of photodynamic therapy (PDT) for infections, cancer, and heart disease and in low-level light therapy (LLLT) for wound healing, arthritis, traumatic brain injury and hair-regrowth. He directs a laboratory of around a sixteen post-doctoral fellows, visiting scientists and graduate students. His research program is supported by NIH, CDMRP, USAFOSR and CIMIT among other funding agencies. He has published 252 peer-reviewed articles, over 150 conference proceedings, book chapters and International abstracts and holds 8 patents. He is Associate Editor for 7 journals, on the editorial board of a further 12 journals and serves on NIH Study Sections. For the past 9 years Dr Hamblin has chaired an annual conference at SPIE Photonics West entitled "Mechanisms for low level light therapy" and he has edited the 9 proceedings volumes together with four other major textbooks on PDT and photomedicine. He has several other book projects in progress at various stages of completion. In 2011 Dr Hamblin was honored by election as a Fellow of SPIE. Pinar Avci, MD is a Research Fellow in Wellman Center for Photomedicine, Massachusetts General Hospital and Harvard Medical School Department of Dermatology, Boston USA. She received her MD degree in General Medicine from Semmelweis University, and is currently pursuing her PhD in Department of Dermatology, Venereology and Dermato-oncology, Semmelweis University, Budapest, Hungary. She is currently conducting research in the area of Photodynamic therapy (PDT) – a localized approach for treatment of cancer and infections and its effects in developing anti-tumor immunity.