Böcker i Smart Nanomaterials Technology-serien

The book in hand, namely ¿Metal and Metal-Oxide Based Nanomaterials (Synthesis, Agricultural, Biomedical and Environmental Interventions¿, focuses on the synthesis methods, characterization techniques, and diverse interventions utilizing these nanomaterials in the fields of agriculture, biomedicine, and environmental remediation. The specific applications discussed include food packaging, post-harvest disease management, crop production, drug delivery systems, other biomedical applications, photocatalytic degradation of environmental pollutants, and wastewater treatment. Additionally, it also addresses the potential risks associated with zinc nanoparticles in aquatic ecosystems and emphasizes the importance of further research and regulation in this field. Overall, the book provides valuable insights and serves as a comprehensive resource for researchers and scientists across various interdisciplinary subjects. It serves as a valuable resource for scientists, researchers, and students in nanotechnology, nanomedicine, environmental science, plant science, agriculture, chemistry, biotechnology, pharmacognosy, pharmaceuticals, industrial chemistry, and other interdisciplinary subjects. Moreover, this also inspires further research, innovation, and the development of sustainable solutions for a better future.

This book covers a number of engineered nanotheranostics platforms and nanomedicines applications of FDA-approved medicines for early-stage diagnosis and treatment of cancer. The book focuses on (i) the basic design and bioengineering of safe medicines, (ii) physicochemical understanding of surface engineered medicines and their characteristics, (iii) various examples for site-specific bioimaging and multimode therapies, (iv) stimuli-responsive approaches for targeted drug delivery applications, (v) targeted therapeutics approaches for cancer cells or solid tumor ablations, (vi) targeted mechanisms of administrative biomedicines, (vii) impact of surface modification or engineering of biomedicines for site-selective tumor binding ability, and (vii) requirements for clinical trials and FDA approval. The content of this book appeal to readers who are interested in recent developments of FDA-approved cost-effective rapid cancer imaging and therapeutic platforms.

This book highlights the recent advancement in point-of-care testing (POCT) technologies utilizing ¿smart¿ nanomaterials for the analysis of biomarkers related to disease, which includes metabolites, enzymes, proteins, nucleic acids, cancer cells and multidrug-resistant pathogen. The POCT refers to medical diagnostic tests performed near the place and time of patient care. During the recent pandemic of COVID-19, many realized the importance of affordable, rapid and accurate POCT devices and their usefulness to combat the spread of the infection. The chapters in this book describe the emergence of ¿smart¿ nanomaterials with unique physical and chemical properties being utilized in POCT devices for immobilizing biorecognition elements and labels for signal generation, transduction and amplification. It showcases the applications of these smart nanomaterials and their superiority in developing point-of-care diagnostics devices in a wide range of applied fields like food industry, agriculture sector, water quality assessment, pharmaceuticals and tissue engineering. It also looks into the challenges associated and future direction of research in this promising field. This book caters as reference book for researches from the field of nanobiotechnology and biomedical sciences who are interested in the development of rapid, affordable and accurate POCT devices.

This book gives a complete overview of current developments on the green synthesis and extraction of nano-emulsions for numerous uses in food, agriculture, biomedical, and cosmetics sectors. In the food and agriculture section, the book demonstrates the use of nano-emulsions to deliver nutraceuticals, coloring, and flavoring agents, in the development of biodegradable coating, improving the quality of packing films and enhancing the shelf life and nutritional value of foods. It also shows that nano-emulsions are very good for pesticides formulation where it enhances the solubility of poorly water-soluble pesticides, resulting in increased pesticide bioactivity compared to conventional pesticides. In the biomedicine applications section, the chapters show that nano-emulsion can dissolve hydrophobic drugs and is used as a drug delivery system for many cancers treatment such as lung cancer, breast cancer, prostate cancer, liver, and gastric cancer. Also, nano-emulsions are an excellent candidate for encapsulating drugs or imaging probes for targeted delivery and immunotherapy. This book caters to scientists, researchers, and students interested in nanotechnology, nanomedicine, environmental science, plant science, agriculture, chemistry, biotechnology, pharmacognosy, pharmaceuticals, industrial chemistry, and many other interdisciplinary subjects.

This book covers the various aspects of nanohybrid materials and its composites for their application in treatment of toxic textiles dyes for cleaning the environment especially water and wastewater. The book first looks into the various preparation and characterization techniques for nanohybrid materials. The replacement of other conventional materials with highly efficient (high surface area, pore size, and chemical and mechanical strength) nanohybrid materials and their application in the field of environmental purification through treatment of textile dyes is highlighted in the later part of the book. The book caters to students, researchers, and scientists who are working in the field of wastewater treatment for incorporating novel materials to remove toxic textile dyes from contaminated wastewater.

This book gives a complete overview of current developments in the fabrication and diverse applications of metal and metal oxide nanomaterials synthesized from agricultural/horticultural products and organic waste materials. Nanoparticles are thought to have been present on earth naturally since its origin in the form of soil, water, volcanic dust, and minerals. Besides their natural origin, they have been also synthesized by using physical, chemical, and biological means. The chapters in this book look at agricultural as well as horticultural wastes from industries, such as palm oil, rubber, paper, wood, vegetable, coffee/tea, rice, wheat, maize, grass, and fruit juice processing factories, and describe the methods to extract and synthesize metal and metal oxide nanoparticles, which are then applied in various sectors such as food, agriculture, cosmetics, and medicines industries. The book is a reference source for academician, scientists, policymakers, students, and researchers scientist working in minimizing the environmental pollution and implementing nanotechnology into agricultural waste products to produce eco-friendly and cost-effective nanoparticles.

This book looks at the interaction between plants and nanomaterials/nanocomposites, and their effects ecology, the food chain and human health. It focuses on nanomaterials/nanocomposites phytotoxicity, which is an important precondition to promote the application of nanotechnology and to avoid the potential ecological risks. It describes the influencing factors of nanotoxicity of nanomaterials and the mechanisms of these toxic effects and defense mechanisms in plants. The chapters in this book are written by internationally renowned researchers and professionals and provides exciting and remarkable information (on the above-mentioned topics) to the scientist, researcher and student working field of plant biology, agricultural science, nanobiotechnology, plant biochemistry, plant physiology, plant biotechnology and many other interdisciplinary subjects.

The book showcases the newest research on smart nanoplatforms responding to ¿hypoxiä; an omnipresent pathological feature of many modern-day diseases and its potential applications. The book demonstrates the versatility of hypoxia targeted smart nanoplatforms in disease management in diverse pathological settings presented in chapters contributed by various experts in the field. The themes in the book touch upon critical facets to address pathological hypoxia such as nanomaterials enhancing oxygenation, hypoxia responsive nanoformulations which deliver the drug directly to the hypoxic site, limited toxicity and enhanced efficacy of smart nanoformulations to counter molecular consequences of hypoxia, and theranostics combining hypoxia detection systems with drug delivery systems. This book disseminates the current implications of smart nanomaterials in disease management that can be exploited by scholars, researchers, and pharma industries to develop, manufacture, and commercialize hypoxia targeted diagnostics and therapeutics.

Nanotechnology is gaining importance in every field of science and technology. Green synthesis of nanomaterials involves the use of microorganisms such as bacteria, fungi, viruses; and different lower and higher plants. Green synthesis of nanomaterials from plant extracts becoming popular in comparison to synthesis using microorganisms. Plant based-nanomaterials synthesis is easy, have no need to bring back from the culture medium, and is safe. Additionally, plant-based nanomaterials are eco-friendly, in comparison to physical and chemical modes of synthesis. Several lower and higher plants are rich in terms of secondary metabolites. These metabolites have been used as medicine in crude extract form or with some other formulations. They have been also used to isolate the bioactive compounds in modern medicine as well as in herbal medicine systems. Thus, phytochemicals present in the plant and their parts play an important role in nanomaterials synthesis, mainly due to the presence of a significant number of secondary metabolites, for instance, alkaloids, flavonoids, saponins, steroids, tannins, etc. Further, essential and aromatic oils have been also explored for nanomaterials synthesis, and they are also equally useful in terms of their various biological applications. These organic ingredients come from a wide range of plant components, such as leaves, stems, roots, shoots, flowers, bark, and seeds. Globally, the presence of different plants has shown a capability to produce huge and diverse groups of secondary metabolites. The functional groups present in the plant extract acts as capping and stabilizing agent. Most of the time, pure isolated bioactive compounds are more biologically active; hence scholars are focusing their research on the synthesis of nanomaterials using some particular class of secondary metabolites. Investigations have shown that the green synthesized nanomaterials were found to be more biologically active in comparison to chemicallysynthesized nanomaterials. These nanomaterials and or nanocomposites found different applications especially in drug delivery, detection and cure of cancer cells, diagnosis of a genetic disorder, photoimaging, and angiogenesis detection. They have also shown several applications in agricultural, horticultural as well as forestry sectors. The book in hand covers a wide range of topics as mentioned above. It incorporates chapters that the authors have skilfully crafted with clarity and precision, reviewing up-to-date literature with lucid illustrations. The book would cater to the need of graduate students as a textbook and simultaneously be useful for both novices and experienced scientists and or researchers working in the discipline of nanotechnology, nanomedicine, medicinal plants, plant science, economic botany, chemistry, biotechnology, pharmacognosy, pharmaceuticals, industrial chemistry, and many other interdisciplinary subjects. It should also inspire industrialists and policy makers associated with plant-based nano products.