Bentham Science Publishers

Nanoelectronics Devices: Design, Materials, and Applications provides information about the progress of nanomaterial and nanoelectronic devices and their applications in diverse fields (including semiconductor electronics, biomedical engineering, energy production and agriculture). The book is divided into two parts. The editors have included a blend of basic and advanced information with references to current research. The book is intended as an update for researchers and industry professionals in the field of electronics and nanotechnology. It can also serve as a reference book for students taking advanced courses in electronics and technology. The editors have included MCQs for evaluating the readers' understanding of the topics covered in the book.

Topics covered in Part 1 include basic knowledge on nanoelectronics with examples of testing different device parameters.

- The present, past, and future of nanoelectronics,

- An introduction to Nanoelectronics and applicability of Moore's law

- Transport of charge carrier, electrode, and measurement of device parameters

- Fermi level adjustment in junction less transistor,

- Non-polar devices and their simulation

- The negative capacitance in MOSFET devices

- Effect of electrode in the device operation

- Second and Sixth group semiconductors,

- FinFET principal and future, Electronics and optics integration for fast processing and data communication

- Batteryless photo detectors

- Solar cell fabrication and applications

- Van der Waals assembled nanomaterials

Nanoscience is a multidisciplinary area of science which enables researchers to create tools that help in understanding the mechanisms related to the interactions between nanomaterials and biomolecules (nanotechnology). Nanomaterials represent nanotechnology products. These products have an enormous impact on technical industries and the quality of human life. Nanomaterials directly or indirectly have to interact with biosystems. It is, therefore, essential to understand the beneficial and harmful interactions of nanomaterials with and within a biosystem, especially with reference to humans.

This book provides primary and advanced information concerning the interactions between nanomaterials and the components of a typical biosystem to readers. Chapters in the book cover, in a topic-based approach, the many facets of nanomolecular interactions with biological molecules and systems that influence their behavior, bioavailability and biocompatibility (including nucleic acids, cell membranes, tissues, enzymes and antibodies). A note on the applications of nanomaterials is also presented in the conclusion of the book to illustrate the usefulness of this class of materials.

The contents of the book will benefit students, researchers, and technicians involved in the fields of biological sciences, such as cell biology, medicine, molecular biology, food technology, cosmetology, pharmacology, biotechnology, and environmental sciences. The book also provides information for the material science personnel, enabling them to understand the basics of target-oriented nanomaterials design for specific objectives.

Nanotechnology is a diverse science that has brought about new applications in fields such as colloidal science, device physics and supra molecular chemistry.

Environmental pollution treatment by nanomaterials is an emerging application of nanotechnology. It is gaining importance because of the increased environmental challenges due to the impact of modern industrial activities. Industrial activity involves the production and use of various toxic organic and inorganic chemicals which pollute nearby water streams, indirectly influencing aquatic and human life. Thus, there is a need to protect the environment through the development of new technologies and by enacting awareness drives for environmental sustainability. This volume summarizes cutting-edge research on nanomaterial utilization for environmental challenges.

Chapters introduce readers to the concepts of environmental protection, sustainability and monitoring. Readers will also learn about technologies used for keeping the environment safer, including ion exchangers, metallic oxide complexes, nanocomposite materials, porous membranes and nanocatalysts.

This volume is intended to be an introductory reference for students and researchers undertaking advanced courses in materials science, environmental science and engineering, giving readers a glimpse into the fascinating world of nanotechnology.

Nanomaterials in Glioblastoma Research, Diagnosis, and Therapy offers a comprehensive exploration of how nanotechnology is revolutionizing the fight against glioblastoma (GBM), one of the deadliest and most treatment-resistant brain cancers. The book covers the molecular and epigenetic mechanisms underlying GBM, laying the foundation for innovative strategies in diagnosis and therapy. It highlights cutting-edge advances, including nanomaterial-based biosensors for early diagnosis, biomaterials to enhance immunotherapy, and novel therapeutic approaches like gold nanoparticles, cold plasma, and combinational nanomedicine. The book also addresses critical challenges such as overcoming the blood-brain barrier through oral delivery nanostructures and provides future perspectives on clinical applications.

Key Features:

- Insights into GBM genetics, epigenetics, and molecular pathways.

- Applications of nanomaterials in drug delivery, imaging, and immunotherapy.

- Detailed coverage of advanced diagnostics and therapeutic strategies.

- Future directions and challenges in nanotechnology-based GBM treatment.

This book explains various methods needed to overcome the challenges faced during environmental remediation with a focus on nanotechnology. The book comprises ten edited chapters that aim to inform and educate readers about recent technologies that are beneficial for pollution control.

Starting with an introduction to environmental remediation, the book covers innovative nanomaterials including spinel nanoferrites, carbonaceous quantum dots, carbon nanotubes and nanobioadsorbents. In addition to highlighting the environmental benefits of these materials, the book includes chapters on the potential of nanotechnology for harnessing the environment to generate energy through nanogenerators and piezoelectric energy harvesting devices.

Key features of the book include notes on fundamental issues and challenges regarding environmental remediation, easy to read content with pictorial illustrations and scholarly references for each chapter. The book is an informative resource for students and academicians in science, technology and environmental science discipline.

The development of a vector for the delivery of therapeutic drugs in a controlled and targeted fashion is still a major challenge in the treatment of many diseases. The conventional application of drugs may lead to many limitations including poor distribution, limited effectiveness, lack of selectivity and dose dependent toxicity. An efficient drug delivery system can address these problems. Recent nanotechnology advancements in the biomedical field have the potential to meet these challenges in developing drug delivery systems. Nanomaterials are changing the biomedical platform in terms of disease diagnosis, treatment and prevention. Nanomaterials aided drug delivery provides an advantage by enhancing aqueous solubility that leads to improved bioavailability, increased resistance time in the body, decreased side effects by targeting drugs to the specific location, reduced dose dependent toxicity and protection of drugs from early release.

In this two-part book, the contributors have compiled reports of recent studies illustrating the promising nanomaterials that can work as drug carriers which can navigate conventional physiological barriers. A detailed account of several types of nanomaterials including polymeric nanoparticles, liposomes, dendrimers, micelles, carbon nanomaterials, magnetic nanoparticles, solid lipid-based nanoparticles, silica nanomaterials and hydrogels for drug delivery is provided in separate chapters. The contributors also present a discussion on clinical aspects of ongoing research with insights towards future prospects of specific nanotechnologies.

Part II covers the following topics:

· Solid lipid nanoparticles and nanostructured lipid carriers

· Silica based nanomaterials

· Hydrogels

· Metallic nanoparticles

· Computational and experimental binding interactions of drug and β-cyclodextrin

· Clinical milestones in nanotherapeutics

· Drug delivery systems based on poly(lactide-co-glycolide) and its copolymers

The book set is an informative resource for scholars who seek updates in nanomedicine with reference to nanomaterials used in drug delivery systems.

Frontiers in Nanomedicine offers an up-to-date understanding of nanomaterials to readers having clinical or biomolecular research interests. Scientists, both aspiring and experienced, will find, in each volume, a comprehensive overview of current molecular strategies for using nanoscale materials in medicine.

Nanomedicine and Neurosciences: Advantages, Limitations and Safety Aspects presents different aspects of nanomedicine applied to neuroscience for the diagnosis of disease and the role of nanoparticles in targeted drug delivery systems for neurodegenerative disorders. Topics covered in this volume cover the physiology of neurodegeneration, targeted therapies for Alzheimer's disease and Parkinson's disease, blood brain barrier drug delivery systems, in vivo studies of drug nanoconjugates, nanomedicine safety, and more.

This book explains key concepts and applications of nanotechnology in clinical medicine and pharmacology. The chapters have been contributed by experts and provide a broad perspective about the current and future developments in pharmacology, toxicology, cell biology, and materials science. The book is divided into 2 main sections. The first section concerns nanobiotechnology for human health including gastrointestinal disease, kidney diseases, pulmonary disorders, reproductive system, COVID-19, and cancer. The second section is devoted to toxicological aspects of nanomaterials which involve toxicological assessments of nanotherapeutics and potential solutions for nanotoxicology. Key Features - Emphasizes the high degree of interdisciplinary research in pharmacology, toxicology and nanoscience - Summarizes the results of theoretical, methodological, and practical studies in different medical subspecialties - includes special topics such as novel nanotoxicology assessment methods and nano vaccines - Includes references for further reading

Burns can cause life-threatening injury and the lengthy hospitalization and rehabilitations required in burn therapy lead to higher healthcare costs. The risk of infection has also been one of the important concerns of burn wound management. The purpose of the burn wound care management is speedy wound healing and epithelization to limit the infection. The topical application of therapeutic agents is quintessential for the longevity of patients having significant burns.

In recent times, research on herbal medicine for burn wound management has been vastly increased because of their safer toxicological profiles in contrast to synthetic medicines. Despite the promising therapeutic potential of herbal medicines in this area, herbal medications have some limitations which include low pharmacological activity, solubility and stability. Nanotechnology-based smart drug delivery approaches which involve the use of small molecules as nanocarriers, however, can help to overcome these biopharmaceutical challenges.

This book provides an overview of plant-mediated metallic nanoparticulate systems and nanophytomedicine based therapeutic treatment modalities for burn wound lesions. Nine chapters deliver updated information about nanomedicines for burn wound therapy. Contributions are written by experts in nanomedicine and phytomedicine and collectively cover the pathophysiology of wound lesions, current and future outlook of nanomedicine based treatments for burn wound lesions, the role of biocompatible nanomaterials in burn wound management, plant-mediated synthesis of metal nanoparticles for treating burn wound sepsis, phytomedicine based nanoformulations and the phyto-informatics models involved in the wound healing process which are used to select appropriate nanotherapeutic agents.

This reference serves as an accessible source of information on the topic of nanomedicine for burn treatments for all healthcare professionals (medical doctors, nurses, students trainees) and researchers in allied fields (pharmacology, phytomedicine) who are interested in this area of medicine.