Foreword to the 2nd Edition

Chapter 1

Introduction

Frank J Rybicki

Chapter 2

Image processing including software considerations for medical 3D printing

Chapter 3

Pre-processing and Preparation of Medical 3D Printed Models

Prashanth Ravi, Shivum Chokshi

Chapter 4

Peter C. Liacouras, Eugene Huo, Dimitrios Mitsouras

Chapter 5

Thoracic 3D Printing

Aakanksha Sriwastwa, Rajul Gupta, Prashanth Ravi; Shayne Kondor; Shivum Chokshi; Adnan Sheikh; Carolina Souza;

Chapter 6

Justin Ryan, Aakanksha Sriwastwa, Prashanth Ravi, Betty Ann Schwarz; Andreas Giannopoulos

Chapter 7

Musculoskeletal 3D Printing

Rajul Gupta; Sean P. Martin; Aakanksha Sriwastwa; Betty Ann Schwarz; Satheesh Krishna; Kirstin M. Small; Leonid L. Chepelev; Adnan Sheikh; Matthew DiPaola

Chapter 8

3D Printing in Oral and Maxillofacial Surgery 

Brian B. Farrell, R. Bryan Bell, Andy Christensen

Chapter 9

Case Examples of Advanced 3D Printing in Hospitals and Medical Centers

Rajul Gupta; Victoria A Sears; Daniel L Price; Kyle S Ettinger; Frank J. Rybicki; Jonathan M. Morris

Chapter 10

3D Printing and Digital Design for Maxillofacial Prosthetics

Rosemary Seelaus, Gerald T Grant

Patient-Specific Planning in Head and Neck Reconstruction including Virtual Reality

Lee W.T. Alkureishi, Pravin K. Patel

Chapter 12

3D Printing and Neurotechnology in Cranial Reconstruction 

Charity Huggins, Bradley Rabinovitz, Mehran Armand, Chad Gordon

Chapter 13

Arafat Ali, Aakanksha Sriwastwa

Chapter 14

Application of 3D printing in the Spine

David Ting-chang Wang, Arafat Ali, Rajul Gupta, Aakanksha Sriwastwa, 

Chapter 15

Applications of 3D printing in the Abdomen and Pelvis 

Shivum Chokshi, David Ballard; Rajul Gupta; Seetharam Chadalavada; Nicole Wake

Chapter 16

3D Printing in the Management of Breast Cancer

Chapter 17

Radiological Society of North America (RNSA) – American College of Radiology (ACR) 3D Printing Registry

Kenneth C. Wang, Amy E. Alexander

Chapter 18

Establishing a Medical 3D Printing Lab and Considerations for Ensuring Quality of the 3D Printed Medical Parts

Prashanth Ravi; Aakanksha Sriwastwa; Shivum Chokshi; Shayne Kondor; Frank J. Rybicki

Chapter 19

3D Printing in Medical Education

Shivum Chokshi; Ibrahim Bin Huzaifa; Aakanksha Sriwastwa; Adnan Sheikh; Frank J. Rybicki; Rajul Gupta

Chapter 20

Biofabricated Tissues & Organs

Naomi C Paxton, Paul D Dalton

Chapter 21

FDA Regulatory Pathways and Technical Considerations for the 3D Printing of Medical Models and Devices

James C. Coburn; Gerald T. Grant 

Chapter 22

Augmented & Virtual Reality in Medicine

Justin Sutherland; Daniel J La Russa;

Back matter and after word (in memoriam)

Dr. Frank J. Rybicki pioneered medical 3D printing in health care facilities. He developed and supervised the first radiology-based Continuing Medical Education (CME) educational program in 3D printing, and he designed the first hands-on CME-based training program. Dr. Rybicki founded and is Editor-in-Chief of  3D Printing in Medicine (2022 Impact Factor of 3.7) that launched in 2015. In the fall of 2016, after founding the organization one year earlier, Dr. Rybicki was named the first Chairperson of the Radiological Society of North America Special Interest Group (SIG) on 3D Printing, initiating a new chapter for the field of advanced surgical planning. In September 2018, as part of an American College of Radiology team, Dr. Rybicki co-led the successful AMA/ CPT application for category III billing codes for anatomic modelling (effective July 1, 2019).

Dr. Jonathan M. Morris is a Board-Certified Radiologist and CAQ Neuroradiologist. He is Professor of Radiology at the Mayo Clinic where he directs the 3D Printing Anatomic Modeling Unit, among the largest of all hospital-based 3D printing manufacturing facilities. His work has pioneered and scaled the use of patient specific anatomical models and custom 3D printed sterilizable class II osteotomy guides for craniomaxillofacial and orthopedic procedures.  Similarly, he pioneered the incorporation of 3D printing into the Electronic Medical Record, Radiology Information Management System, and Billing systems across a 5 state enterprise at Mayo Clinic with Anatomic Modeling Units at the 3 major facilities in Rochester, MN, Jacksonville, FL, and Scottsdale AZ. He is past president of the RSNA 3D Printing Special Interest Group. He received his M.D. at Howard University College of Medicine, completed an internship at Washington Hospital Center, a research fellowship at the National Institutes of Health, and his radiology and neuroradiology fellowships at Mayo Clinic. He is the Executive Medical Director for Immersive and Experiential Learning and Medical Director for Biomedical and Scientific Visualization, Division of Experiential Learning at the Mayo Clinic College of Medicine and Science. In this role Dr. Morris is focused on developing and deploying extended realities, virtual reality, augmented reality in medical education, intraoperative guidance, and medical capital equipment training. Additionally, he is an expert in minimally invasive thermal ablation of tumors in the neuroaxis.

Gerald T. Grant, DMD, MS, FACP received his D.M.D. degree from the University of Louisville, School of Dentistry in 1985, and his specialty training in Maxillofacial Prosthetics from the Naval Postgraduate Dental School, Bethesda, Maryland in 1999. He is a Diplomat of the American Board of Prosthodontics. Dr. Grant has over 15 years of experience in the use of digital design and 3D printing in customized medical and dental care (both research and application). He directed the development and was Service Chief of the 3D Medical Applications Center, Department of Radiology, at Walter Reed National Military Medical Center, one of the first and largest in-hospital services, providing medical models, surgical guides, and custom medical/dental devices world-wide to US military facilities for Wounded Warrior care around the world. Having retired after 33 years of service in the United States Navy, he served as Professor and Interim Chair of the Oral Health and Rehabilitation Department at the University of Louisville School of Dentistry for seven years and continues with an adjunct professor position, where he has developed collaborative research teams involving the Schools of Medicine, Engineering, and Dentistry for Advanced Digital Applications in the design and fabrication of medical devices for craniofacial reconstruction, dental restoration and rehabilitation, and bio-printing/bio-fabrication. He is currently serving as a Maxillofacial Prosthodontist at the Lexington, Kentucky Veterans Dental Clinic, where he is developing institutional pathways for digital dental technologies and research. 

This new edition describes the fundamentals of three-dimensional (3D) printing as applied to medicine and extends the scope of the first edition of 3D Printing in Medicine to include modern 3D printing within Health Care Facilities, also called at the medical “Point-Of-Care” (POC). This edition addresses the practical considerations for, and scope of hospital 3D printing facilities, image segmentation and post-processing for Computer Aided Design (CAD) and 3D printing. The book provides details regarding technologies and materials for medical applications of 3D printing, as well as practical tips of value for physicians, engineers, and technologists.

Individual, comprehensive chapters span all major organ systems that are 3D printed, including cardiovascular, musculoskeletal, craniomaxillofacial, spinal, neurological, thoracic, and abdominal. The fabrication of maxillofacial prosthetics, the planning of head and neck reconstructions, and 3D printed medical devices used in cranial reconstruction are also addressed. The second edition also includes guidelines and regulatory considerations, costs and reimbursement for medical 3D printing, quality assurance, and additional applications of CAD such as virtual reality. There is a new Forward written by Ron Kikinis, PhD and a new Afterword written by Michael W. Vannier, MD.

This book offers radiologists, surgeons, and other physicians a rich source of information on the practicalities and expanding medical applications of 3D printing. It will also serve engineers, physicist, technologists, and hospital administrators who undertake 3D printing. The second edition is designed as a textbook and is expected to serve in this capacity to fill educational needs in both the medical and engineering sectors.