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Under a single cover, this book brings together various aspects of functional bioengineered materials and nanostructured biomaterials including commonly used implants and sustained release nanodevices. The book includes expert reviews on the advances and current problems associated with the implants and nanodevices. Containing recent citations and bibliographies, this book will be an indispensable source of information for new researchers and scientists.
This book characterizes how to design and synthesize nanomaterials of an organic and mineral nature. The book also discusses the visualization of developed nanomaterials and their bio-applications, as well as describes the biomedical effects and environmental impact of nanomaterials. This is an ideal book for students studying biomedicine or the life sciences, as well as researchers and professionals in medicine, environmental protection, biotechnology, agriculture, and the food industry. More specifically, this book addresses the important nanomaterials and nanobiotechnologies that are used in those fields in biomedicine and life sciences.
Smart Nanoparticles for Biomedicine explores smart nanoparticles that change their structural or functional properties in response to specific external stimuli (electric or magnetic fields, electromagnetic radiation, ultrasound, etc.). Particular attention is given to multifunctional nanostructured materials that are pharmacologically active and that can be actuated by virtue of their magnetic, dielectric, optically-active, redox-active, or piezoelectric properties. This important reference resource will be of great value to readers who want to learn more on how smart nanoparticles can be used to create more effective treatment solutions. Nanotechnology has enabled unprecedented control of the interactions between materials and biological entities, from the microscale, to the molecular level. Nanosurfaces and nanostructures have been used to mimic or interact with biological microenvironments, to support specific biological functions, such as cell adhesion, mobility and differentiation, and in tissue healing. Recently, a new paradigm has been proposed for nanomedicine to exploit the intrinsic properties of nanomaterials as active devices rather than as passive structural units or carriers for medications. - Discusses the synthesis, characterization and applications of a new generation of smart nanoparticles for nanomedicine applications - Explores the problems relating to the biocompatibility of a range of nanoparticles, outlining potential solutions - Describes techniques for manipulating specific classes of nanoparticles for a variety of treatment types
Biomedical Applications of Functionalized Nanomaterials: Concepts, Development and Clinical Translation presents a concise overview of the most promising nanomaterials functionalized with ligands for biomedical applications. The first section focuses on current strategies for identifying biological targets and screening of ligand to optimize anchoring to nanomaterials, providing the foundation for the remaining parts. Section Two covers specific applications of functionalized nanomaterials in therapy and diagnostics, highlighting current practice and addressing major challenges, in particular, case studies of successfully developed and marketed functionalized nanomaterials. The final section focuses on regulatory issues and clinical translation, providing a legal framework for their use in biomedicine. This book is an important reference source for worldwide drug and medical devices policymakers, biomaterials scientists and regulatory bodies.
This book highlights the wide applications of nanomaterials in healthcare and environmental remediation. Presenting nano-based materials that positively influence the growth and proliferation of cells present in soft and hard tissue and are used for the regeneration bone tissue and/or suppression of cancer cells, it also discusses the natural products that can be incorporated in nanofibers for the treatment of cancer. Further, it describes the use of blending and functionalization to produce chitosan nanofibers for biomedical applications, and reviews the role of plasma-enhanced gold nanoparticles in diagnostics and therapeutics. Lastly, the book also introduces various nanotechnology approaches for the removal of waste metabolites in drinking water, and explores the emerging applications of nanorobotics in medicine. Given its scope, this book is a valuable resource for scientists, clinicians, engineers and researchers aiming to gain a better understanding of the various applications of nanotechnology.
Nanoparticles for Biomedical Applications: Fundamental Concepts, Biological Interactions and Clinical Applications brings into one place information on the design and biomedical applications of different classes of nanoparticles. While aspects are dealt with in individual journal articles, there is not one source that covers this area comprehensively. This book fills this gap in the literature. - Outlines an in-depth review of biomedical applications of a variety of nanoparticle classes - Discusses the major techniques for designing nanoparticles for use in biomedicine - Explores safety and regulatory aspects for the use of nanoparticles in biomedicine
NanoScience in Biomedicine provides up-to-date information in the frontier fields of nano biomedicine focusing on basic concepts and recent developments in many topical areas including particular nanomaterials synthesis, field emission of carbon nanotubes, flexible dye-sensitized nano-porous films, magnetic nanofluids, and intrinsically electroconducting nanoparticles. Novel methods of synthesizing nanoscale biomaterials and their applications in biomedicine are also included such as nano-sized materials for drug delivery, bioactive molecules for regenerative medicine, nanoscale mechanisms for assembly of biomaterials, and nanostructured materials constructed from polypeptides. This book is organized in three parts: Part I introduces most recent developments in all aspects of design, synthesis, properties, and applications of nanoscale biomaterials. Part II focuses on novel nanotechnologies in biomedicine. Part III includes some of the new developments of nanomaterials’ synthesis and recent studies on nanostructure-properties relationships. The book comprehensively addresses the most critical issues in a tutorial manner so that technical non-specialists and students in both biomedical sciences and engineering will be able to benefit. All chapters are contributed by internationally recognized scholars. Dr. Donglu Shi is a professor at the Chemical and Materials Engineering Department, University of Cincinnati, USA.
Research on biomedical applications of nanomaterials has exhibited the rapidly evolving field of biomedical sciences by showing how effective they are in treatment. These particles hold considerable potential for biomedical applications. Work is ongoing, and the results suggest a possibility for a sustainable future for nanomaterials in both therapeutic and biomedical fields. This book highlights current and emerging applications, taking global research findings into consideration. We believe the focus on the identification and role of nanomaterial applications in therapeutic and biomedical sciences can lead to novel solutions in the fields. The chapters of this book are disseminated in a manner that can be readily adopted as sources for new and further study. The editors integrate advanced texts in their research that help graduate students, researchers and professors. Additionally, we believe that international readers will be able to make use of this book for reference purposes.
Advancement in the field of nanotechnology has revolutionized the field of medicines and pharmaceuticals in the twentieth century. The proper use of nanomaterials in medical applications requires a proper understanding of these compounds. This correct understanding, beyond the physical and chemical properties, must also have the correct logic of use. In other words, the strategic use of nanomaterials with applicable perspective can also help to advance research, but if we go forward with the current research perspective that leads to the expansion of inapplicable researches, the intrinsic importance of using these nanomaterials is eliminated. This book, considering the importance of nanomaterials and their application in medicine, as well as the significant growth of biomaterials in research fields, introduces the variables law (Rabiee's theory) for the implementation of this research and the establishment of a proper strategy. Considering that the degree of number of biomaterial and host variables follow a variety factors, and by increasing the degree of number of biomaterials and host variables, the degree of total variables also increases and as a result, performance and, consequently, biomaterial behavior in the host environment will have less control and predictive capabilities. For an external substance that is supposed to be in the human body, it must be predictable and controllable, In addition, according to the principle that the host in a fixed person does not have the ability to change, therefore, by using the simpler biomaterials (with less variables), the above goal is more accessible. It should be noted that in addition to observing biocompatibility tests for a biomaterial based on existing protocols and standards, the Applicable Compatibility (AC) parameter is also required in accordance with Rabiee's theory. This book is written in accordance with Rabiee's theory and the contents of this book should be evaluated from this perspective.
Nanoscale structures and materials have been explored in many biological applications because of their novel and impressive physical and chemical properties. Such properties allow remarkable opportunities to study and interact with complex biological processes. This book analyses the state of the art of piezoelectric nanomaterials and introduces their applications in the biomedical field. Despite their impressive potentials, piezoelectric materials have not yet received significant attention for bio-applications. This book shows that the exploitation of piezoelectric nanoparticles in nanomedicine is possible and realistic, and their impressive physical properties can be useful for several applications, ranging from sensors and transducers for the detection of biomolecules to “sensible” substrates for tissue engineering or cell stimulation.