Over the past few decades, there has been unprecedented progress in the design of versatile biopolymer-based nanoplatforms for pharmaceutical and biomedical applications, particularly due to their attractive traits, including excellent biocompatibility, outstanding biodegradability, low immunogenicity, and facile chemical modifiability. Biopolymer-Based Nanomaterials in Drug Delivery and Biomedical Applications serves as a clear and detailed body of information on the synthesis and characterization of biopolymer-based materials in nanomedicine. This book describes various nanomaterials consisting of biopolymers including polysaccharides (i.e., derived from plants, animals, bacteria, algae, and fungi) and polypeptides in terms of their structures, synthetic protocols, and characterization and uses as therapeutic drugs and gene delivery carriers and in other biomedical fields. The chapters of this book, which are contributed by internationally renowned scholars working in the arena of biopolymer-based nanomaterials, would offer a wide vision on the potential future applications of these nanomaterials in the delivery and targeting of bioactive molecules of pharmaceutical interests and in tissue engineering, biosensing, bioimaging, and diagnostic purposes. The state-of-the-art information presented in the book would also encourage young investigators and researchers to further bring cutting-edge developments in the field of nanomedicine in the near future.

Master's Thesis from the year 2011 in the subject Physics - Quantum Physics, grade: -, Shahjalal University of Science and Technology (Department of Physics), course: Nanostructure Physics, language: English, abstract: This book contains a comprehensive account of application of WKB method to pure Physics of nanostructures containing single or symmetric double barrier V(x) in their band model in presence of longitudinal magnetic field applied along x direction. It concentrates on effects on transmission coefficient of single and symmetric double barriers by three dimensional electron gas (3DEG). Analytical expressions for longitudinal magnetic field dependent transmission coefficient of single and symmetric double barrier of general shape are obtained first. These general expressions are then used to obtain analytical expressions of longitudinal magnetic field dependent transmission coefficient of single and symmetric double barriers of many different shapes we encounter in studying nanostructure Physics. This is followed by thorough numerical investigation to bring out effects of longitudinal magnetic field on transmission coefficient of all these barriers. Comparisons with standard results where available showed excellent agreements. Results of numerical investigation have been explained completely. The book makes well documented, with thorough calculation and discussion, pure Physics of semiconductor nanostructures.