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3D Bioprinting for Reconstructive Surgery. Woodhead Publishing Series in Biomaterials

  • ID: 4226349
  • Book
  • November 2017
  • Region: Global
  • 450 Pages
  • Elsevier Science and Technology
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3D Bioprinting for Reconstructive Surgery: Techniques and Applications examines the combined use of materials, procedures and tools necessary for creating structural tissue constructs for reconstructive purposes. Offering a broad analysis of the field, the first set of chapters review the range of biomaterials which can be used to create 3D-printed tissue constructs. Part Two looks at the techniques needed to prepare biomaterials and biological materials for 3D printing, while the final set of chapters examines application-specific examples of tissues formed from 3D printed biomaterials.

3D printing of biomaterials for tissue engineering applications is becoming increasingly popular due to its ability to offer unique, patient-specific parts-on demand-at a relatively low cost. This book is a valuable resource for biomaterials scientists, biomedical engineers, practitioners and students wishing to broaden their knowledge in the allied field.

  • Discusses new possibilities in tissue engineering with 3D printing
  • Presents a comprehensive coverage of the materials, techniques and tools needed for producing bioprinted tissues
  • Reviews emerging technologies in addition to commercial techniques

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1. Introduction to 3D Tissue Engineering, biomaterials, techniques and applications

Part 1: Biomaterials and bio-inks for structural regenerative medicine and 3-D reconstructive tissue engineering 2. Biopolymers 3. Hydrogels 4. Ceramics 5. Biocomposites 6. Metals 7. Biomaterial Preparation Directory

Part 2: Techniques for structural regenerative medicine and 3-D constructive tissue engineering 8. Stem Cell Preparation Techniques 9. Practical Laboratory Methods for 3-D Tissue Engineering 10. Bio-microfluidic Devices 11. 3-D Biofabrication Approaches 12. Bioink Preparation 13. Biorepair Technologies 14. Bioreactor Processes 15. 3-D Computational Design of Biostructures

Part 3: Applications of structural regenerative medicine and 3-D constructive tissue engineering 16. 3-D of Bone and Orthopaedic Structures 17. Biofabrication of Nerve Systems 18. 3-D bioprinting of Cartilage 19. 3-D Dermal and Skin System Engineering 20. Fabrication Methods for Muscle and Tendons 21. Arteries and Vessel Fabrication 22. Conclusions

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Thomas, Daniel
Dr. Daniel Thomas B.Eng (Hons)., M.Sc., Eng.D., C.Sci., C.Eng., FBCS is an interdisciplinary researcher and writer who comes from an academic background in materials engineering, 3D Bioprinting, and tissue engineering disciplines.
Jessop, Zita M.
Ms. Zita M. Jessop MB BChir, MA Cantab, MRCS is an Academic Clinical Lecturer in the Reconstructive Surgery & Regenerative Medicine Research Group in Swansea University and Registrar at the Welsh Centre for Burns and Plastic Surgery. Ms. Jessop graduated from Cambridge University Medical School and completed her basic surgical training in London Deanery before taking up her clinical academic post in Wales. Her doctorate research, focusing on 3D bioprinting for cartilage tissue engineering, was supported by the Royal College of Surgeons Research Fellowship and the Medical Research Council Clinical Research Training Fellowship. Ms. Jessop is a member of the editorial boards of Bioprinting and 3D Printing in Medicine, the welsh representative on the Reconstructive Surgical Trials Network, has delivered over 60 national and international presentations and published over 30 articles and book chapters to date. Ms. Jessop was awarded a number of prizes from the British Association of Plastic and Reconstructive Surgeons and the Royal College of Surgeons of England and completed international fellowships in Utrecht (Norman Capener Travelling Fellowship) and Melbourne (Ethicon Travelling Fellowship). More recently, Ms. Jessop achieved a Fulbright Scholarship which she intends to spend at the Wyss Institute for Biologically Inspired Engineering at Harvard Medical School, to expand her field of expertise in biofabrication.
Whitaker, Iain S.
Professor Iain Whitaker MA Cantab PhD FRCS Eng (Plast) is the Chair of Plastic & Reconstructive Surgery in Wales, Director of the Reconstructive Surgery & Regenerative Medicine Research Group (www.reconregen.com) and Honorary Consultant Plastic Surgeon. After studying medicine at Cambridge University he completed specialised plastic, reconstructive & aesthetic surgery training including time in England, Wales, USA and Sweden, with fellowships in France (Young Plastic Surgeon Scholar) and Australia (Rowan Nick's Scholar). His current major research focus is on mesenchymal tissue engineering and novel platform technologies such as 3D Bioprinting to allow customised biofabrication. His team includes several clinical lecturers and post doctoral researchers working in close association with multidisciplinary specialists in the fields of Engineering, Biomaterials, Cell Biology and Large Industrial Supporters in both the UK and USA. Iain is the Chief or Principle Investigator on grants of >£3 million pounds in salary and consumable costs from a variety of sources including the Welsh Assembly Government, the Medical Research Council, the Royal College of Surgeons, the British Association of Plastic, Reconstructive & Aesthetic Surgeons and Charitable Bodies. Iain has published approaching 200 papers (H index 31, i10 62), several book chapters and books and has won multiple National & International Fellowships, awards and prizes throughout his career. He is currently a Deputy Editor for The Journal of Plastic, Reconstructive & Aesthetic Surgery (JPRAS) and sits on the Research Council of BAPRAS.
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