Functionalized Magnetic Nanosystems For Diagnostic Tools And Devices
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Functionalized Magnetic Nanosystems for Diagnostic Tools and Devices
Functionalized Magnetic Nanosystems for Diagnostic Tools and Devices: Current and Emerging Research Trends explores the various aspects of functionalization of magnetic nanosystems in great detail, providing a thorough review of the associated benefits and challenges. The book begins with an overview of each key pillar for the design and application of functionalized magnetic nanosystems, from the synthesis, processing methods, and characterization techniques, to biocompatibility and toxicity considerations. Later chapters focus on specific nanomaterials and targeted biomedical applications, including point-of-care diagnosis, cancer therapy, medical imaging, biosensing and more. Importance is given to the safety considerations; environmental, legal and ethical implications, and commercial aspects of functionalized magnetic nanosystems - providing guidance relevant for advancing research into clinical practice. - Provides an overview of fundamentals in the design and application of magnetic nanosystems, from synthesis and processing to functionalization and toxicity assessment - Explores research in industry and clinical practice, providing insights into ethical, environmental, legal, and commercial aspects - Covers a wide range of diagnostic applications for functionalized magnetic nanosystems, such as in medical imaging, drug detection, tissue engineering, and more
Functionalized Magnetic Nanoparticles for Theranostic Applications
This unique book provides a comprehensive introduction to the multifaceted realm of functionalized magnetic nanoparticles in the field of theranostics, exploring the fundamental concepts, synthesis methods, characterization techniques, and potential applications. In recent years, the intersection of nanotechnology and medicine has ushered in a new era of therapeutics and diagnostics. Among the myriad nanostructures, magnetic nanoparticles (MNPs) have emerged as versatile candidates with immense potential for theranostic applications. Their unique combination of magnetic properties and functionalization capabilities has paved the way for innovative approaches in both the diagnosis and treatment of various diseases. Understanding the synthesis, characterization, and manipulation of these MNPs is essential for harnessing their full potential in theranostics. Advances in nanotechnology have enabled precise control over their size, shape, and surface chemistry, allowing for tailored functionalities to suit specific biomedical applications. From superparamagnetic iron oxide nanoparticles (SPIONs) to magnetic nanorods and beyond, the diverse landscape of MNPs offers a rich playground for innovation. The convergence of diagnosis and therapy is facilitated by functionalized MNPs; their magnetic properties render them invaluable tools for imaging modalities such as magnetic resonance imaging (MRI), offering high-resolution anatomical and functional information for disease detection and monitoring. Simultaneously, functionalizing MNPs with targeting ligands, therapeutic agents, or stimuli-responsive moieties empowers them to actively engage in targeted drug delivery, hyperthermia, or magnetic manipulation of biological processes. This synergistic approach exemplifies the essence of theranostics—combining therapy and diagnostics to achieve personalized and precise medical interventions. The book discusses the challenges ahead, including the translation of functionalized MNPs from bench to bedside, which necessitates rigorous preclinical and clinical evaluations to ensure safety, efficacy, and biocompatibility. Moreover, the complex interplay between nanoparticles and biological systems demands a multidisciplinary approach, bridging the gap between materials science, biology, and clinical medicine. Regulatory hurdles, scalability issues, and ethical considerations further underscore the need for concerted efforts and strategic collaborations in the development and commercialization of MNP-based theranostic platforms. The readers will find that “Functionalized Magnetic Nanoparticles for Theranostic Applications” comprehensively covers the chemical, structural, and biological properties of functionalized magnetic nanoparticles for theranostic applications as well as most of the challenges. Audience This unique reference book will be of great value to materials engineers, polymer scientists, and technologists working in the electronic, electrical, and biomedical industries. It will also be of great use to graduate, postgraduate, and engineering students working in materials and polymer science.
CFD Simulation
Author: Fateh Mebarek-Oudina
language: en
Publisher: Walter de Gruyter GmbH & Co KG
Release Date: 2025-05-19
Information about the author: Fateh Mebarek-Oudina received his PhD in 2010. He has published more than 120 papers in reputed international journals. Currently, he works as a full professor at Skikda University in Algeria and regularly serves as a reviewer for more than 250 international journals. He is ranked in the Top 2% Scientists Worldwide (2020, 2021, 2022, 2023) by Stanford University. His research work is focused on heat and mass transfer, MHD, mathematical simulation and modelling, biofluids, nanofluids, hybrid nanofluids, ternary nanofluids, microfluidics, and computational fluid dynamics. Information abiout the book: Mathematical modeling presented in the book is designed to help engineers understand physical systems, including magnetohydrodynamic effects on the non-Newtonian fluid flow and multiphase flow. Special attention will be given to heat transfer and entropy generation analysis on hybrid nanofluids. The process of entropy generation for nanofluid flows through porous channels will also be discussed and analyzed by means of a theoretical approach and CFD modeling. Some applications to blood-mediated gold-silver nanoparticles will be presented with detailed numerical examples. The book is designed to facilitate a more profound understanding for engineers of adopting CFD models to natural manufacturing environments. Overall, the primary objective of the book is to present mathematical modeling with CFD applications to simulate real-world engineering, industrial, and medical science problems to expose various analytical and numerical techniques and, at the same time, extend to expose researchers and academicians to the recent advancement in these diverse fields.