This work pursues a novel route to functionalizing large surfaces with hybrid nanoparticles. It also casts new light on the combined use of surface plasmon resonance and X-rays. SPR spectroscopy is employed to study Au-based plasmonic nanostructures fabricated by novel methods, and a new experimental device is developed combining SPR with X-ray absorption spectroscopy at a synchrotron beamline. Using the new SPR-XAS setup developed in this work, the author has studied in-situ and real-time effects of X-ray irradiation in materials such as glasses and Co-phthalocyanines.
This is a comprehensive treatment of the field of SPR sensors, in three parts. Part I introduces principles of surface plasmon resonance bio-sensors, electromagnetic theory of surface plasmons, theory of SPR sensors and molecular interactions at sensor surfaces. Part II examines the development of SPR sensor instrumentation and functionalization methods. Part III reviews applications of SPR biosensors in the study of molecules, and in environmental monitoring, food safety and medical diagnostics.
Nanoanalytics is a novel branch of analytical chemistry which explores applications of nanotechnologies in chemical analysis. This comprehensive publication gives an overview of the analytical techniques used to study nanoobjects and nanoparticles as well as the application of nanomaterials themselves in the development of new methods of analysis. The authors also address important metrology aspects and give future prospects of the area.
This informative book compiles the most up-to-date applications of nanobiosensors in fields ranging from agriculture to medicine. The introductory section describes different types of nanobiosensors and use of nanobiosensors towards a sustainable environment. The applications are divided into four broad sections for easy reading and understanding. The book discusses how manipulation, control and integration of atoms and molecules are used to form materials, structures, devices and systems in nano-scale. Chapters in the book shed light on the use of nanosensors in diagnostics and medical devices. Application in food processing as well as in cell signaling is also described. Nanobiosensors have immense use, and this book captures the most important ones.
A groundbreaking book on the recent advances in chemical finishing, innovative fabrication strategies frequently adopted for the mechanical finishing of textiles, as well as the environmental issues in textile sectors Advanced materials are undoubtedly becoming very popular as substitutes for traditional materials in the textile engineering field. Advanced textile engineering materials are giving way to innovative textile materials with novel functions and are widely perceived as offering huge potential in a wide range of applications such as healthcare, defense, personal protective equipment, textile antennas, garments for motion capture, and sensors, etc. Advanced Engineering Textile Materials contains 13 chapters written by high profile contributors with many years of experience in textile technology, and cover fundamental and advanced approaches associated with the design and development of textile implants, conductive textiles, 3D textiles, smart-stimuli textiles, antiballistic textiles and fabric structures designed for a medical application intrabody/extra-body, implantable/non-implantable) and various modification and processing techniques.
Nanotechnology and Nanomaterials in the Treatment of Life-threatening Diseases takes a scientific approach to nanotechnology and nanomaterials applications in medicine, while also explaining the core biological principles for an audience of biomedical engineers, materials scientists, pharmacologists, and medical diagnostic technicians. The book is structured by major disease groups, offering a practical, application-based focus for scientists, engineers, and clinicians alike. The spectrum of medical applications is explored, from diagnostics and imaging to drug delivery, monitoring, therapies, and disease prevention. It also focuses specifically on the synthesis of nanomaterials and their potential health risks (particularly toxicity). Nanomedicine — the application of nanomaterials and devices for addressing medical problems — has demonstrated great potential for enabling improved diagnosis, treatment, and monitoring of many serious illnesses, including cancer, cardiovascular and neurological disorders, HIV/AIDS, and diabetes, as well as many types of inflammatory and infectious diseases. - Gain an understanding of how nanotechnologies and nanomaterials can be deployed in the fight against the major life-threatening diseases: cancer, neurological disorders (including Alzheimer's and Parkinson's), cardiovascular diseases, and HIV/AIDS - Discover the latest developments in nanomedicine, from therapies and drug delivery to diagnostics and disease prevention - The authors cover the health risks of nanomaterials as well as their benefits, considering toxicity and potential carcinogens
Chemical, Gas, and Biosensors for the Internet of Things and Related Applications brings together the fields of sensors and analytical chemistry, devices and machines, and network and information technology. This thorough resource enables researchers to effectively collaborate to advance this rapidly expanding, interdisciplinary area of study. As innovative developments in the Internet of Things (IoT) continue to open new possibilities for quality of life improvement, sensor technology must keep pace, Drs. Mitsubayashi, Niwa and Ueno have brought together the top minds in their respective fields to provide the latest information on the numerous uses of this technology. Topics covered include life-assist systems, network monitoring with portable environmental sensors, wireless livestock health monitoring, point-of-care health monitoring, organic electronics and bio-batteries, and more. - 2020 PROSE Awards - Winner: Category: Chemistry and Physics: Association of American Publishers - Describes the latest advances and underlying principles of sensors used in biomedicine, healthcare, biotechnology, nanotechnology and food and environment safety - Focuses on sensors' methods of data communication, logging and analysis for IoT applications - Explains the specific requirements of sensor design and performance improvement, helping researchers enhance sensitivity, selectivity, stability, reproducibility and response time
In recent years, nanomaterials have become one of the most dynamic exploration fields in the areas of engineering, technology, and science. This new volume focuses on the use of various bionanomaterials that can be introduced into the body as clinical devices for various medical purposes. The book also provides examples of cost-effective, sustainable alternatives to traditional medical procedures. The volume discusses how these materials have diverse applications in the biomedical fields, such as for cancer treatment, for orthopedic joint replacements, for medical diagnosis, for making bone plates, for wound healing, for nerve regeneration, for breast implants, in dental procedures, and so on. In addition, the book also covers some nonbiomedical applications of nanobiomaterials, such as, for example, to grow cells in a culture medium, as a blood protein test in laboratories, etc.
Wearable Physical, Chemical and Biological Sensors introduces readers of all backgrounds—chemistry, electronics, photonics, biology, microfluidics, materials, and more—to the fundamental principles needed to develop wearable sensors for a host of different applications. The capability to continuously monitor organ-related biomarkers, environmental exposure, movement disorders, and other health conditions using miniaturized devices that operate in real time provides numerous benefits, such as avoiding or delaying the onset of disease, saving resources allocated to public health, and making better decisions on medical diagnostics or treatment. Worn like glasses, masks, wristwatches, fitness bands, tattoo-like devices, or patches, wearables are being boosted by the Internet of Things in combination with smart mobile devices. Besides, wearables for smart agriculture are also covered. Written by experts in their respective fields, Wearable Physical, Chemical and Biological Sensors provides insights on how to design, fabricate, and operate these sensors. - Provides a holistic view of the field, covering physical, chemical, and biosensing approaches along with the advantages of their various functionalities - Covers all necessary elements for developing wearable sensors, including materials, biorecognition elements, transductions systems, signal amplification strategies, and system design considerations - Each chapter includes examples, summaries, and references for further reading
