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Medical Additive Manufacturing
Concepts and Fundamentals
- 1st Edition - April 3, 2024
- Editors: Shadpour Mallakpour, Chaudhery Mustansar Hussain
- Language: English
- Paperback ISBN:9 7 8 - 0 - 3 2 3 - 9 5 3 8 3 - 2
- eBook ISBN:9 7 8 - 0 - 3 2 3 - 9 5 3 8 4 - 9
Medical Additive Manufacturing: Concepts and Fundamentals provides an overview of the latest research in the field of additively manufactured medical materials. It starts with a… Read more
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Request a sales quoteMedical Additive Manufacturing: Concepts and Fundamentals provides an overview of the latest research in the field of additively manufactured medical materials. It starts with a broad overview of the current state of medical additive manufacturing and then dives into cutting-edge topics such as medical imaging technologies for additive manufacturing and computer-aided design principles for anatomic modeling. The chapters discuss the state of additive manufacturing in an array of medical fields such as radiology, tissue engineering, nuclear medicine, orthopedics, surgery, cardiology, neurology, optometry, obstetrics, and veterinary medicine. This book concludes with chapters discussing regulatory considerations for additive manufacturing in hospitals and what the future holds for the field.
- Synthesizes the latest research in medical additive manufacturing
- Outlines basic additive manufacturing concepts, the different types of manufacturing, optimal material selection, design production and configuration, and more
- Discusses cutting-edge applications in drug delivery, tissue engineering, biosensor devices, electrically conductive polymers, green catalysis, and more
Academic researchers and grad students in mechanical engineering, biomedical engineering, manufacturing, and materials science, Professionals in these same areas
- Cover image
- Title page
- Table of Contents
- Copyright
- Dedication
- List of contributors
- About the editors
- Preface
- Acknowledgments
- 1. COVID-19 pandemic: the latest achievements in the field of emergency medical devices using 3D printing technology
- Abstract
- 1.1 Introduction
- 1.2 The development of medical equipment through 3D printing during COVID-19
- 1.3 Conclusions
- Acknowledgments
- Significant websites about the topic
- References
- 2. Medical additive manufacturing in the battle against the COVID-19 pandemic
- Abstract
- 2.1 Introduction
- 2.2 Medical additive manufacturing
- 2.3 Additively manufactured medical healthcare devices
- 2.4 MAM against the COVID-19 pandemic
- 2.5 COVID-19’s effects on the MAM industry
- 2.6 Technology evolution pathways of MAM-versus-COVID-19 research
- 2.7 Challenges in MAM against COVID-19
- 2.8 Summary and future perspectives
- References
- 3. Latest innovations in tissue engineering by 3D-printed hyaluronic acid-based hydrogels
- Abstract
- 3.1 Introduction
- 3.2 Applications of 3D-printed hyaluronic acid hydrogels in regenerative biomedicine
- 3.3 Conclusions and future perspectives
- Acknowledgments
- Significant websites about the topic
- References
- 4. Engineering aspects and medical materials of medical additive manufacturing
- Abstract
- 4.1 Additive manufacturing
- 4.2 Distinct types of materials used for biomedical implant manufacturing applications
- 4.3 Mechanical properties of distinct biomedical materials
- 4.4 Merits and demerits of additive manufactured parts
- 4.5 Application of distinct 3D printing materials in distinct sectors
- 4.6 Future scope and challenges
- 4.7 Conclusion
- Acknowledgments
- Declaration of competing interest
- References
- 5. Computer-aided modeling principles for anatomic design
- Abstract
- 5.1 Introduction
- 5.2 3D printing/additive manufacturing technologies
- 5.3 3D printing/additive manufacturing techniques for additive production of anatomical models
- 5.4 Material choice
- 5.5 Biomaterials
- 5.6 Printing techniques
- 5.7 Initial anatomical models
- 5.8 Traditional Anatomical models and their flaws
- 5.9 Associated work
- 5.10 Computer-aided synthesis technology development
- 5.11 Computerized 3D modeling—simulations and 3D printing
- 5.12 Three-dimensional (3D) model deformation
- 5.13 The model of deformation
- 5.14 Parametrization of the surface
- 5.15 Strain energy density function variations
- 5.16 Conclusion
- References
- 6. Advanced application of additive manufacturing in the footwear industry: from customized insoles to fully 3D-printed shoes
- Abstract
- 6.1 Introduction
- 6.2 Different additive manufacturing techniques
- 6.3 3D-printed personalized footwear
- 6.4 Customized 3D-printed shoe soles
- 6.5 Therapeutic 3D-printed shoe soles
- 6.6 3D-printed shoe lasts
- 6.7 Conclusion and outlook
- Acknowledgment
- Declaration of competing interest
- References
- 7. Additive manufacturing in limb prosthetics and orthotics: the past, present and future of 3D printing orthopedic assistive devices
- Abstract
- 7.1 Introduction
- 7.2 3D printing technologies in prosthetics and orthotics
- 7.3 3D printing materials in prosthetics and orthotics
- 7.4 Infrastructural aspects and initial costs
- 7.5 Use cases and good practices
- 7.6 The future of 3D printing in prosthetics and orthotics—toward 4D printing
- 7.7 Summary
- References
- 8. Design of bionically adequate “soft-soft” joint endoprosthesis. FDM fabricated UHMWPE and PEEK-based composites
- Abstract
- 8.1 Introduction
- 8.2 Materials and experimental methods
- 8.3 Wear patterns for polymer-polymer tribological contacts, providing the possibility of their fabrication by 3D-printing
- 8.4 Simulation of the wear process in the UHMWPE/20PP(3D)–PEEK/30CF(3D) tribological contact for different both loading schemes and lubrication conditions
- 8.5 FEM analysis of the role of the gradient elastic properties of the cup material in the formation of the stress–strain state of an endoprosthesis
- 8.6 Conclusions
- Funding
- References
- 9. Digital fabrication in craniofacial surgery
- Abstract
- 9.1 Digital fabrication: a life-changer for health professionals
- 9.2 The six main principles of medical digital fabrication
- 9.3 Digital fabrication in craniofacial surgery
- 9.4 Digital fabrication and surgical education
- 9.5 Digital fabrication and the social image of craniofacial surgery
- 9.6 Conclusion
- References
- 10. Entering a new era in pharmaceutics through 3D/4D printing technologies
- Abstract
- 10.1 A brief introduction to 3D/4D printing
- 10.2 Applications of 3D/4D printing technology in pharmaceutic
- 10.3 Conclusions
- Other sources regarding pharmaceutical applications of 3D/4D printing
- Acknowledgments
- Conflict of interests
- References
- 11. Novel biomaterials based on diverse polysaccharide gums with gelatin used in three-dimensional printing techniques
- Abstract
- 11.1 Introduction
- 11.2 Gellan gum ink
- 11.3 Xanthan gum ink
- 11.4 Guar gum ink
- 11.5 Arabic gum ink
- 11.6 Gelatin ink
- 11.7 Conclusions and further remarks
- Acknowledgments
- Significant websites about the topic
- References
- 12. Additive manufacturing in the next world
- Abstract
- 12.1 Introduction
- 12.2 Additive manufacturing technologies
- 12.3 Additive manufacturing applications in key sectors
- 12.4 Advantages and challenges of additive manufacturing in the next world
- 12.5 Implications for the next world
- 12.6 Future trends and opportunities
- 12.7 Conclusion
- References
- 13. Medical additive manufacturing—The way to the future!
- Abstract
- 13.1 Introduction
- 13.2 Medical additives
- 13.3 Historical development
- 13.4 Medical additive manufacturing
- 13.5 Additive manufacturing process
- 13.6 Applications
- 13.7 Future possibilities and challenges
- 13.8 Conclusion
- References
- 14. Medical additive manufacturing then, now, and will
- Abstract
- 14.1 Introduction
- 14.2 Current state of additive manufacturing in medicine
- 14.3 Advancements in additive manufacturing technologies
- 14.4 Innovative materials in additive manufacturing for medicine
- 14.5 Regulatory and ethical aspects
- 14.6 Economic impact and commercial aspects
- 14.7 Future directions and potential of additive manufacturing in medicine
- 14.8 Conclusion
- References
- 15. Applications and scope of nanotechnology in additive manufacturing for healthcare industry
- Abstract
- 15.1 Introduction
- 15.2 Boosting mechanical properties by CNT, carbon fibers, and nanomaterials
- 15.3 Biomedical and healthcare application of 3D printer
- 15.4 Nanoparticles used in additive manufacturing process
- 15.5 Conclusion
- References
- 16. Usage of autodesk fusion 360 software for 3D reconstruction of anatomical structure from the 2D X-ray image
- Abstract
- 16.1 Introduction
- 16.2 Objective
- 16.3 Target persons
- 16.4 3D reconstruction of anatomical structure from the 2D x-ray image
- 16.5 Selection
- 16.6 Preview mesh
- 16.7 Number of triangles
- 16.8 Refinement
- 16.9 Introduction
- 16.10 Literature reviews
- 16.11 Traditional method
- 16.12 Motivation
- 16.13 Development of novel dental implant guideway
- 16.14 Scope of work
- 16.15 Phase TWO
- 16.16 Phase THREE
- 16.17 Phase FOUR
- 16.18 Fabrication
- 16.19 Slice and preview
- 16.20 Print the file
- 16.21 Material of 3D printing
- 16.22 Assembly
- 16.23 Testing and validation
- 16.24 Concluding remarks/summary
- References
- 17. Advancements and future prospects of additive manufacturing in orthopedics
- Abstract
- 17.1 Introduction
- 17.2 Overview of 3D printing technology
- 17.3 Patient-matched implants and surgical guides
- 17.4 Advancements in 3D printing technology
- 17.5 Enhancing orthopedic education through 3D printing
- 17.6 3D-printed models for surgical planning
- 17.7 Future prospectss and implications
- 17.8 Conclusion
- Reference
- 18. Medical additive manufacturing—the magic wand for cardiology
- Abstract
- 18.1 Introduction
- 18.2 Classification of additive manufacturing
- 18.3 AM in cardiology
- 18.4 Advantages of AM in cardiology
- 18.5 3D printing in cardiology
- 18.6 Application of AM in cardiology
- 18.7 Conclusions
- References
- 19. Advances and new developments in cardiovascular research with additive manufacturing
- Abstract
- 19.1 Introduction
- 19.2 Additive manufacturing for cardiology
- 19.3 Conclusion
- References
- 20. 3D printing in ophthalmology: a progressive application
- Abstract
- 20.1 Introduction
- 20.2 Cornea
- 20.3 Retina
- 20.4 Spectacles
- 20.5 Contact lenses and intraocular lenses
- 20.6 Educational tools
- 20.7 Safety equipment in the COVID-19 pandemic
- 20.8 Future direction
- 20.9 Conclusion
- References
- 21. Medical additive manufacturing in pharmacy
- Abstract
- 21.1 Introduction
- 21.2 Pharmaceutical additive manufacturing/3D printing technological elements
- 21.3 3D printing technology
- 21.4 Combination products and medical technologies
- 21.5 The effect of gases and nanoparticles emitted from 3D printers
- 21.6 Obstacles as well as future viewpoints of drug additive manufacturing
- 21.7 Conclusion
- References
- 22. Medical additive manufacturing in pharmacy
- Abstract
- 22.1 Introduction
- 22.2 Personalized medicines
- 22.3 AM and drug delivery
- 22.4 Advanced additive manufacturing
- 22.5 4D printing technology
- 22.6 5D printing technology
- 22.7 6D printing technology
- 22.8 Applications of additive manufacturing
- 22.9 Designing of transdermal dosage form
- 22.10 Pulmonary drug delivery
- 22.11 Ophthalmic drug delivery
- 22.12 Nanomedicines
- 22.13 Conclusion and future perspective
- References
- 23. Multicomponent and multimaterials medical additive manufacturing
- Abstract
- 23.1 Introduction
- 23.2 Multimaterial composites for additive manufacturing
- 23.3 Summary
- References
- 24. Graphene-based nanocomposites in additive manufacturing
- Abstract
- 24.1 Introduction
- 24.2 Additive manufacturing techniques for preparing graphene nanocomposites
- 24.3 Graphene-based composites fabricated via AM
- 24.4 Applications of graphene-based nanocomposites fabricated via AM
- 24.5 Future scope
- References
- 25. Additive manufacturing strategies for personalized drug delivery systems and medical devices
- Abstract
- 25.1 Introduction
- 25.2 Conceptualization and development of 3DP medicines and medical devices
- 25.3 Factors affecting the 3D printing techniques
- 25.4 MAM or 3D printing manufacturing: technical aspects
- 25.5 Extrusion-based method
- 25.6 Powder-based method
- 25.7 Resin-based method
- 25.8 Droplet-based method
- 25.9 Polymers used in 3D printing techniques
- 25.10 Applications of 3D printing techniques
- 25.11 Modified 3D tablets
- 25.12 Effect of physical printing parameters on evaluation of 3D tablets
- 25.13 Immediate release tablets and caplets
- 25.14 Controlled, sustained, and delayed release dosage forms
- 25.15 Novel floating drug delivery systems
- 25.16 Buccal films
- 25.17 Application of additive manufacturing in medical devices
- 25.18 Challenges and future perspectives
- References
- 26. Technoeconomic analysis of medical additive manufacturing by cognitive data analysis and blockchain
- Abstract
- 26.1 Introduction
- 26.2 Medical additive manufacturing in the cardiology
- 26.3 Data analysis of the cardiovascular data set
- 26.4 Medical additive manufacturing in the neurology
- 26.5 Parkinson’s diseases assessment
- 26.6 Medical additive manufacturing by blockchain
- 26.7 Economic analysis of medical additive manufacturing
- 26.8 Case study on the blockchain-based medical additive manufacturing
- 26.9 Conclusion
- References
- 27. Additive manufacturing and its impact on pharmaceutical supply chains
- Abstract
- 27.1 Introduction
- 27.2 Systematic literature review
- 27.3 Analysis and synthesis
- 27.4 Thematic analysis
- 27.5 Discussion
- 27.6 Conclusion and limitations
- References
- 28. The future of medical additives manufacturing
- Abstract
- 28.1 Introduction
- 28.2 AM methods
- 28.3 Applications of 3DP in biomedicine and healthcare
- 28.4 Conclusion
- References
- Index
- No. of pages: 792
- Language: English
- Edition: 1
- Published: April 3, 2024
- Imprint: Elsevier
- Paperback ISBN: 9780323953832
- eBook ISBN: 9780323953849
SM
Shadpour Mallakpour
Professor Shadpour Mallakpour, organic polymer chemist, graduated from chemistry department, University of Florida (UF), Gainesville, Florida, U.S.A. in 1984. He spent two years as post-doc at UF. He joint to the department of chemistry, Isfahan University of Technology (IUT), Iran, since 1986. He held several positions such as chairman of department of chemistry and deputy of research, department of chemistry at IUT. From 1994-1995 he worked as visiting professor, University of Mainz, Germany and from 2003-2004 as visiting professor, Virginia Tech, Blacksburg, USA. Now he has published more than 900 journal papers and book chapters and more than 440 conference papers and got more than 40 items of awards. The most important award to him was given for the selection of first laureate on fundamental research, at 21st Khwarizmi International award in 2008. He is listed as the Top 1% Scientists in Chemistry in ISI Essential Science Indicators Since 2003. He was selected as academic guest of the 59th Meeting of Nobel Prize Winners in Chemistry, 2009, at Lindau, Germany. He presented many lectures as invited or keynote speaker in different national and international conferences or universities. He was member of organizing and scientific committees for many national and international conferences. He was also the chairperson of many national and international meetings. In recent year he focused on the preparation and characterization of polymers containing chiral amino acid moieties under green conditions using ionic liquids and microwave irradiation as new technology and bringing these aspects towards nanotechnology for the preparation of novel chiral bionanocomposite polymers as well as polymer nanocomposities for hazardous materials removal technologies.
Affiliations and expertise
Professor Shadpour Mallakpour, PhD, Organic polymer chemist,Department of Chemistry, Isfahan University of Technology, Isfahan, IranCM
Chaudhery Mustansar Hussain
Chaudhery Mustansar Hussain is an Adjunct Professor and Director of laboratories in the Department of Chemistry & Environmental Sciences at the New Jersey Institute of Technology (NJIT), United States. His research is focused on the applications of nanotechnology and advanced materials, environmental management, analytical chemistry, and other various industries. Dr. Hussain is the author of numerous papers in peer-reviewed journals as well as a prolific author and editor of around 150 books, including scientific monographs and handbooks in his research areas.
Affiliations and expertise
Adjunct Professor and Director of laboratories, New Jersey Institute of Technology (NJIT), USA