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ADVANCED MATERIALS and MANUFACTURING TECHNIQUES for BIOMEDICAL APPLICATIONS The book provides essential knowledge for the synthesis of biomedical products, development, nanomaterial properties, fabrication processes, and design techniques for different applications, as well as process design and optimization. In origin, biomaterials can come from nature or be synthesized in the laboratory with a variety of approaches that use metals, polymers, ceramic, or composite materials. They are often used or adapted for various biomedical applications. Biomaterials are commonly used in scaffolds, orthopedic, wound healing, fracture fixation, surgical sutures, artificial organ developments, pins and screws to stabilize fractures, surgical mesh, breast implants, artificial ligaments and tendons, and drug delivery systems. The sixteen chapters in Advanced Materials and Manufacturing Techniques in Biomedical Applications cover the synthesis, processing, design, manufacturing, and characterization of advanced materials; self-healing, bioinspired, nature-resourced, nanobiomaterials for biomedical applications; and manufacturing techniques such as rapid prototyping, additive manufacturing, etc. Audience The book is for engineers, technologists, and researchers working in the area of biomedical engineering and manufacturing techniques. It is also appropriate for upper-level undergraduate and graduate students.
This book discusses advanced materials and manufacturing processes with insights and overviews on tribology, automation, mechanical, biomedical, and aerospace engineering, as well as the optimization of industrial applications. The book explores the different types of composite materials while reporting on the design considerations and applications of each. Offering an overview of futuristic research areas, the book examines various engineering optimization and multi-criteria decision-making techniques and introduces a specific control framework used in analyzing processes. The book includes problem analyses and solving skills and covers different types of composite materials, their design considerations, and applications. This book is an informational resource for advanced undergraduate and graduate students, researchers, scholars, and field professionals, providing an update on the current advancements in the field of manufacturing processes.
This volume focuses on the fundamentals and advancements in micro and nanomanufacturing technologies applied in the biomedical and biochemical domain. The contents of this volume provide comprehensive coverage of the physical principles of advanced manufacturing technologies and the know-how of their applications in the fabrication of biomedical devices and systems. The book begins by documenting the journey of miniaturization and micro-and nano-fabrication. It then delves into the fundamentals of various advanced technologies such as micro-wire moulding, 3D printing, lithography, imprinting, direct laser machining, and laser-induced plasma-assisted machining. It also covers laser-based technologies which are a promising option due to their flexibility, ease in control and application, high precision, and availability. These technologies can be employed to process several materials such as glass, polymers: polycarbonate, polydimethylsiloxane, polymethylmethacrylate, and metals such as stainless steel, which are commonly used in the fabrication of biomedical devices, such as microfluidic technology, optical and fiber-optic sensors, and electro-chemical bio-sensors. It also discusses advancements in various MEMS/NEMS based technologies and their applications in energy conversion and storage devices. The chapters are written by experts from the fields of micro- and nano-manufacturing, materials engineering, nano-biotechnology, and end-users such as clinicians, engineers, academicians of interdisciplinary background. This book will be a useful guide for academia and industry alike.
ADVANCED MATERIALS and MANUFACTURING TECHNIQUES for BIOMEDICAL APPLICATIONS The book provides essential knowledge for the synthesis of biomedical products, development, nanomaterial properties, fabrication processes, and design techniques for different applications, as well as process design and optimization. In origin, biomaterials can come from nature or be synthesized in the laboratory with a variety of approaches that use metals, polymers, ceramic, or composite materials. They are often used or adapted for various biomedical applications. Biomaterials are commonly used in scaffolds, orthopedic, wound healing, fracture fixation, surgical sutures, artificial organ developments, pins and screws to stabilize fractures, surgical mesh, breast implants, artificial ligaments and tendons, and drug delivery systems. The sixteen chapters in Advanced Materials and Manufacturing Techniques in Biomedical Applications cover the synthesis, processing, design, manufacturing, and characterization of advanced materials; self-healing, bioinspired, nature-resourced, nanobiomaterials for biomedical applications; and manufacturing techniques such as rapid prototyping, additive manufacturing, etc. Audience The book is for engineers, technologists, and researchers working in the area of biomedical engineering and manufacturing techniques. It is also appropriate for upper-level undergraduate and graduate students.
As technology advances, it is imperative to stay current in the newest developments made within the engineering industry and within material sciences. Trends in manufacturing such as 3D printing, casting, welding, surface modification, computer numerical control (CNC), non-traditional, Industry 4.0 ergonomics, and hybrid machining methods must be closely examined to utilize these important resources for the betterment of society. Advanced Manufacturing Techniques for Engineering and Engineered Materials provides a unified and complete overview about the recent and emerging trends, developments, and associated technology with scope for the commercialization of techniques specific to manufacturing materials. This book also reviews the various machining methods for difficult-to-cut materials and novel materials including matrix composites. Covering topics such as agro-waste, conventional machining, and material performance, this book is an essential resource for researchers, engineers, technologists, students and professors of higher education, industry workers, entrepreneurs, researchers, and academicians.
The text begins by discussing the processing and characterization of nano-manufactured resorbable bionanocomposites and presents the latest advances in carbon-based polymer nanocomposite materials for sensing applications. It further presents different characterization techniques such as scanning electron, transmission electron, atomic force microscopy, and powder X-ray diffraction for the identification of bionanocomposites. This book: • Introduces nano-manufactured processed composites for biomedical application, processing, and characterization of bionanocomposites. • Presents biobased nano-manufactured processed composites for imaging, tissue repairing, and drug-delivery applications. • Explains future trends of nano-manufactured composites in 3D bio-implants and fluorescent bioimaging. • Highlights the challenges and perspectives of polymeric nano-manufactured composites for biomedical applications. • Covers multifunctional nano-manufactured bio-composites, and advances in polymeric membranes for healthcare applications. It is primarily written for senior undergraduates, graduate students, and academic researchers in the fields of manufacturing engineering, biomedical engineering, materials science and engineering, mechanical engineering, and production engineering.
The text comprehensively highlights the key issues surrounding the implementation of waste-to-energy systems, such as site selection, regulatory aspects and financial, and economic implications. It further discusses environmental aspects of food waste to energy conversion, microbial fuel cells (MFCs) for waste recycling and energy production, and valorization of algal blooms and their residues into renewable energy. This book: Discusses the environmental impact of waste-to-energy and sustainable waste-to-energy technologies in a comprehensive manner. Presents life cycle assessment studies and perspective solutions in waste-to-energy sectors. Covers applications of smart materials in thermal energy storage systems. Explains thermo-chemical technologies for recycling plastic waste for energy production and recovery of valuable products. Illustrates biorefineries and case studies for sustainable waste valorization. It is primarily written for senior undergraduate nad graduate students, and academic researchers in the fields of mechanical engineering, environmental engineering, energy studies, production engineering, industrial engineering, and manufacturing engineering.
The text discusses synthesis, processing, design, simulation and characterization of biomaterials for biomedical applications. It synergizes exploration related to various properties and functionalities in the biomedical field through extensive theoretical and experimental modeling. It further presents advanced integrated design and nonlinear simulation problems occurring in the biomedical engineering field. It will serve as an ideal reference text for senior undergraduate and graduate students, and academic researchers in fields including biomedical engineering, mechanical engineering, materials science, ergonomics, and human factors. The book: Employs a problem-solution approach, where, in each chapter, a specific biomedical engineering problem is raised and its numerical, and experimental solutions are presented Covers recent developments in biomaterials such as OPMF/KGG bio composites, PEEK-based biomaterials, PF/KGG biocomposites, oil palm mesocarp Fibre/KGG biocomposites, and polymeric resorbable materials for orthopedic, dentistry and shoulder arthroplasty applications Discusses mechanical performance and corrosive analysis of biomaterials for biomedical applications in detail Presents advanced integrated design and nonlinear simulation problems occurring in the biomedical engineering field Presents biodegradable polymers for various biomedical applications over the last decade owing to their non-corrosion in the body, biocompatibility and superior strength in growing state Synergizes exploration related to the various properties and functionalities in the biomedical field through extensive theoretical and experimental modeling
The integration of artificial intelligence (AI) stands as both a promise and a challenge in the field of healthcare. As technological advancements reshape the industry, academic scholars find themselves at the forefront of a crucial dialogue about the ethical implications and societal repercussions of AI. The accelerating sophistication of AI technologies brings forth a central dilemma: how to maintain the crucial human touch required for compassionate and effective patient care in the face of unprecedented technical progress. This challenge is not only a theoretical concern but a pressing reality as healthcare systems increasingly rely on AI-driven solutions. Approaches to Human-Centered AI in Healthcare emerges as a significant guide, offering a comprehensive exploration of the opportunities and challenges entwined with the integration of AI into healthcare. The book becomes a critical compass, navigating readers through the intricate intersections of AI and patient care. By delving into real-world case studies, cutting-edge research findings, and practical recommendations, it provides a roadmap for scholars to navigate the complexities of healthcare AI. In doing so, it aims not only to inform but to shape the discourse around the responsible integration of AI, ensuring that the fundamental principles of compassionate patient care remain at the forefront.