3D Printing for Biomedical Engineering Additive Manufacturing Processes, Properties, and Applications Additive Manufacturing Materials and Technologies Series

Langue : Anglais

Coordonnateurs : Hoque Md Enamul, Kumar R, Gibson Ian

Résumé
Sommaire
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3D Printing for Biomedical Engineering: Additive Manufacturing Processes, Properties, and Applications combines cutting-edge research developments with fundamental concepts related to processing, properties, and applications of advanced additive manufacturing technology in the medical field. State-of-the-art 3D bioprinting techniques such as the manufacturing of mini-organs for new drug testing as an alternative to animal testing are covered, as are reverse engineering techniques for the improvement of additive manufactured biomedical products. The book starts with chapters introducing readers to currently available additive manufacturing techniques for biomedical prototypes, along with design, development, process, and parameter considerations for these methods. Following chapters cover the mechanical, thermal, electrical, and optical properties of 3D printed biomedical prototypes. The next section of the book discusses 3D printing in different biomedical fields, such as in heart surgery, intervertebral disc implants, dentistry, facial reconstructive surgery, oral surgery, spinal surgery, and more. The book concludes with a section outlining immediate and future challenges in the field as well as related environmental and ethical issues.

Section A: Introduction, Fabrication, Properties and Testing 1. Introduction to 3D Printing Technologies and Biomedical Prototypes 2. 3D Printing Methods for Making Biomedical Components: Process and Parameters 3. Design and Development of Biomedical Devices 4. Mechanical Properties of 3D Printed Biomedical Prototypes 5. Thermal Properties of 3D Printed Biomedical Prototypes 6. Dielectric and Optical Properties of 3D Printed Biomedical Prototypes 7. Surface Properties of 3D Printed Biomedical Prototypes 8. Errors and Accuracy of 3D Printed Biomedical Prototypes 9. Improvement of 3D Printing with Reverse Engineering Section B: Implementation of 3D Printing in Biomedical Fields 10. 3D Printing for Congenital Heart Surgery 11. 3D Printing for Cranioplasty Implants 12. 3D Printing for Customized Intervertebral Disc Implants 13. 3D Printing for Dentistry 14. 3D Printing for Facial Reconstructive Surgery 15. 3D Printing for Oral and Maxillofacial Surgery 16. 3D Printing for Orthopaedic Surgery 17. 3D Printing for Prosthetic Sockets 18. 3D Printing for Repairing Fracture Bone Defects 19. 3D Printing for Spinal Surgery 20. 3D Printing for Surgical Aid Tools 21. 3D Printing for Tissue Engineering 22. 3D Printing for Therapeutic Strategy Section C: Challenges, Risks and Scopes 23. Opportunities, Challenges and Potentials of 3DPrinting 24. Environmental Issues and Welfares of 3D Printing 25. Ethical and Legal Issues with 3D Printing

Dr Md Enamul Hoque is a Professor in the Department of Biomedical Engineering at the Military Institute of Science and Technology (MIST), Dhaka, Bangladesh. Before joining MIST, he served in several leading positions in some other global universities such as Head of the Department of Biomedical Engineering at King Faisal University (KFU), Saudi Arabia; Founding Head of Bioengineering Division, University of Nottingham Malaysia Campus (UNMC) and so on. He received his PhD in 2007 from the National University of Singapore (NUS), Singapore. He also obtained his PGCHE (Post Graduate Certificate in Higher Education) from the University of Nottingham, UK in 2015. He is a Chartered Engineer (CEng) certified by the Engineering Council, UK; Fellow of the Institute of Mechanical Engineering (FIMechE), UK; Fellow of Higher Education Academy (FHEA), UK and Member, World Academy of Science, Engineering and Technology. He has published more than 100 articles, more than 10 books, over 75 book chapters, and over 100 International Conference presentations/proceedings.
Dr. R. Kumar is an Associate Professor in the Department of Mechanical Engineering at Eritrea Institute of Technology. His research interests include manufacturing, friction drilling, welding, and machining of aluminum, polymer composites and metal matrix composites.
Ian Gibson is a professor in Industrial Design Engineering and Scientific Director of the University's Fraunhofer Project Centre in complex systems engineering at the University of Twente. His first teaching position was at Nottingham University in 1992, where he was introduced to Rapid Prototyping, which is now more commonly known as 3D Printing (3DP) or Additive Manufacturing (AM). Ian has spent the last 25+ years working with this extremely enabling technology to solve problems in healthcare, automotive, aerospace, and other industrial sectors by engaging in applied research. In 2017, Ian was awarded the Freeform and Additive Manufacturing Excell

Outlines the design, development, process, and applications of 3D printed medical biomaterials
Covers the mechanical, thermal, electrical, optical, and surface properties of these materials
Applications discussed include heart surgery, intervertebral disc implants, oral surgery, facial reconstructive surgery, dentistry, drug development, and more