Novel Application of Rapid Prototyping for Simulation of Bronchoscopic Anatomy

Bustamante, Sergio; Bose, Somnath; Bishop, Paul D.; Klatte, Ryan; Norris, Frederick

doi:10.1053/j.jvca.2013.08.015

Cited by 65 publications

(46 citation statements)

References 7 publications

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“…Subsequent improvement in the surgeon’s competence may lead to enhanced clinical outcomes and a reduced risk of complications. Investigators from various surgical disciplines have demonstrated the utility of 3D printing in training, such as neurosurgery (72–77, 141, 142), cardiothoracic surgery (54, 78–80, 143–145), urology (81, 146), and general surgery (29) However, one of the major limitations currently is the ability to print in materials that closely mimic the biomechanical properties and modulus of real human tissue as well as possessing realistic colors. As more materials enter the scope of 3D printing, future 3D-printed biomodels will be able to more closely reproduce true anatomy (50, 72, 74, 79).…”

Section: D Printing In Plastic and Reconstructive Surgerymentioning

confidence: 99%

Emerging Applications of Bedside 3D Printing in Plastic Surgery

et al. 2015

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Modern imaging techniques are an essential component of preoperative planning in plastic and reconstructive surgery. However, conventional modalities, including three-dimensional (3D) reconstructions, are limited by their representation on 2D workstations. 3D printing, also known as rapid prototyping or additive manufacturing, was once the province of industry to fabricate models from a computer-aided design (CAD) in a layer-by-layer manner. The early adopters in clinical practice have embraced the medical imaging-guided 3D-printed biomodels for their ability to provide tactile feedback and a superior appreciation of visuospatial relationship between anatomical structures. With increasing accessibility, investigators are able to convert standard imaging data into a CAD file using various 3D reconstruction softwares and ultimately fabricate 3D models using 3D printing techniques, such as stereolithography, multijet modeling, selective laser sintering, binder jet technique, and fused deposition modeling. However, many clinicians have questioned whether the cost-to-benefit ratio justifies its ongoing use. The cost and size of 3D printers have rapidly decreased over the past decade in parallel with the expiration of key 3D printing patents. Significant improvements in clinical imaging and user-friendly 3D software have permitted computer-aided 3D modeling of anatomical structures and implants without outsourcing in many cases. These developments offer immense potential for the application of 3D printing at the bedside for a variety of clinical applications. In this review, existing uses of 3D printing in plastic surgery practice spanning the spectrum from templates for facial transplantation surgery through to the formation of bespoke craniofacial implants to optimize post-operative esthetics are described. Furthermore, we discuss the potential of 3D printing to become an essential office-based tool in plastic surgery to assist in preoperative planning, developing intraoperative guidance tools, teaching patients and surgical trainees, and producing patient-specific prosthetics in everyday surgical practice.

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Section: D Printing In Plastic and Reconstructive Surgerymentioning

confidence: 99%

Emerging Applications of Bedside 3D Printing in Plastic Surgery

et al. 2015

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“…A 3D printed model enabled experimentation with different-sized tracheal tubes in preparation for a challenging intubation of a 6yo child that required sequential single-lung ventilation for whole-lung lavage [71] (Figure 13). 3D-printed models of anatomical variants of the tracheobronchial tree have also been reported toward enhancing flexible bronchoscopy proficiency [72]. …”

Section: Thoracic Applicationsmentioning

confidence: 99%

Cardiothoracic Applications of 3-dimensional Printing

Giannopoulos

Steigner

George

et al. 2016

Journal of Thoracic Imaging

137

103

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Summary Medical 3D printing is emerging as a clinically relevant imaging tool in directing preoperative and intraoperative planning in many surgical specialties and will therefore likely lead to interdisciplinary collaboration between engineers, radiologists, and surgeons. Data from standard imaging modalities such as CT, MRI, echocardiography and rotational angiography can be used to fabricate life-sized models of human anatomy and pathology, as well as patient-specific implants and surgical guides. Cardiovascular 3D printed models can improve diagnosis and allow for advanced pre-operative planning. The majority of applications reported involve congenital heart diseases, valvular and great vessels pathologies. Printed models are suitable for planning both surgical and minimally invasive procedures. Added value has been reported toward improving outcomes, minimizing peri-operative risk, and developing new procedures such as transcatheter mitral valve replacements. Similarly, thoracic surgeons are using 3D printing to assess invasion of vital structures by tumors and to assist in diagnosis and treatment of upper and lower airway diseases. Anatomic models enable surgeons to assimilate information more quickly than image review, choose the optimal surgical approach, and achieve surgery in a shorter time. Patient-specific 3D-printed implants are beginning to appear and may have significant impact on cosmetic and life-saving procedures in the future. In summary, cardiothoracic 3D printing is rapidly evolving and may be a potential game-changer for surgeons. The imager who is equipped with the tools to apply this new imaging science to cardiothoracic care is thus ideally positioned to innovate in this new emerging imaging modality.

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“…Investigators used computerized tomography (CT) and magnetic resonance imaging (MRI) data to create anatomical models of long bones, facial bones, brain, heart, and lung. These applications of 3D printing have proved to be valuable in preoperative planning, education and training, intraoperative use of instruments, and even implantable devices [4,9]. Perhaps the most exciting potential of the technology is the efforts in creating biological scaffolds for reseeding, which lays the foundation for the development of organ printing in the future [10][11][12].…”

Section: D Printing and Medical Applicationsmentioning

confidence: 99%

3D Printing and Personalized Airway Stents

et al. 2017

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In recent years, the 3D printing industry has undergone rapid development. Clinicians and researchers have begun to apply this technology in procedural planning, tissue engineering, and device manufacturing. Rapid prototyping and additive manufacturing techniques in the healthcare field have already yielded very exciting results and point to a bright future involving these technologies. This is especially true in pulmonology. 3D printing industry growth is accompanied by increased availability of 3D printers and printable materials, which offers exciting arrays of possible applications. In this review, we present a brief history of 3D printing and its applications in the medical field with a focus on pulmonology. Additionally, we describe a methodology on how to 3D model and print personalized airway prosthesis via 3D Slicer and a commercial 3D printer. We hope this will help to stimulate additional innovation and application of 3D printing in medicine.

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Novel Application of Rapid Prototyping for Simulation of Bronchoscopic Anatomy

Cited by 65 publications

References 7 publications

Emerging Applications of Bedside 3D Printing in Plastic Surgery

Emerging Applications of Bedside 3D Printing in Plastic Surgery

Cardiothoracic Applications of 3-dimensional Printing

3D Printing and Personalized Airway Stents

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