Operative Planning in Thoracic Surgery: A Pilot Study Comparing Imaging Techniques and Three-Dimensional Printing

Smelt, Jeremy; Suri, Tanay; Valencia, Oswaldo; Jahangiri, Marjan; Rhode, Kawal; Nair, Arjun; Billè, Andrea

doi:10.1016/j.athoracsur.2018.08.052

Cited by 20 publications

(18 citation statements)

References 20 publications

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“…Applications include prosthetics, 4,5 anatomical models for surgical planning, 6,7 and education 8‐13 . The ability of AM to produce highly customized anatomical models that can not only be visualized but also manipulated in three dimensions by touch has shown promise as a valuable tool in diverse medical fields ranging from neurosurgery, 14,15 orthopedics, 16,17 otolaryngology, 18 and cardiothoracic surgery 19 . These devices and models can often be printed directly from, or in concert with, computed tomography (CT) images of patient anatomy 20 .…”

Section: Introductionmentioning

confidence: 99%

3D printed bismuth oxide‐polylactic acid composites for radio‐mimetic computed tomography spine phantoms

2020

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Polylactic acid (PLA) composite filaments with varying concentrations of bismuth oxide microparticle additives were fabricated for use with commercially available fused filament fabrication (FFF) printing systems for the production of spine phantoms that mimic the radiopacity of bone. Thermal analysis showed that the additives had limited impact on the glass transition temperature and melting point of the filaments, allowing for their use in commercial FFF systems with standard printer settings. The ultimate strength of the printed test specimens was found to reduce slightly when bismuth oxide was added in high concentrations, with a moderate reduction of 12% compared to PLA at the highest concentration of 30 wt%. The modulus of the specimens increased by up to 24% with the addition of the additive. The radiopacity of specimens printed with the composite filaments were measured by X‐ray microcomputed tomography (micro‐CT) and clinical computed tomography (CT). The CT number was found to increase by approximately 196 HU per wt% of bismuth oxide added to the filaments. A phantom model of a cervical spine deformity was successfully printed by FFF with a composite filament which was calibrated to mimic the radiopacity of cervical and cortical bone. The results indicate that the composite filaments have direct applicability for the production of phantoms used for education and preoperative planning.

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Section: Introductionmentioning

confidence: 99%

3D printed bismuth oxide‐polylactic acid composites for radio‐mimetic computed tomography spine phantoms

2020

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“…In fact, to design margin or intersegmental line before operation by using 3D reconstruction is a critical step in APL. Current researches are limited to preoperative planning using 3D reconstruction and simulation (23). There is no in-depth study on the guidance of intra-operation.…”

Section: Discussionmentioning

confidence: 99%

Three-dimensional reconstruction/personalized three-dimensional printed model for thoracoscopic anatomical partial-lobectomy in stage I lung cancer: a retrospective study

Qiu

et al. 2020

Transl Lung Cancer Res

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Background: Considering the complexity of vascular or bronchial variations and the difficulty of nodule localization during segmental resection, the three-dimensional (3D) reconstruction and printing model can provide a guarantee for safe operation and, to some extent, can simplify the surgical procedure. We conducted this study to estimate the avail of 3D reconstruction and personalized model in anatomical partiallobectomy (APL).Methods: We prospectively collected and retrospectively reviewed the data of 298 cases who underwent APL in our institute from April 2017 to May 2019. The patients were divided into "3D-reconstruction" group (131 patients), "3D model" group (31 patients) and "non-3D" group (136 patients). We adopted the ANOVA analysis and Chi-square test to compare the perioperative data between the three groups. Subjective satisfaction questionnaires for surgeons were provided to evaluate the value of personalized 3D printed model. Results:The proportion of complex segmentectomy in 3D model group (87.1%) was significantly higher than that in the 3D-reconstruction group (60.3%) and non-3D group (55.9%) (P=0.006), and the average operation time of complex segmentectomy in 3D model group (99.56 minutes) was significantly shorter than that of the other group (all P<0.05). The average intraoperative blood loss in the 3D model group (12.9 mL) was significantly lower than that in the 3D reconstruction group (20.9 mL) (P=0.001) and non-3D group (18.2 mL) (P=0.022). For simple segmentectomy, the operation time, postoperative drainage, and postoperative hospital stay were similar among the three groups. The questionnaire survey showed that most surgeons were satisfied with the clinical effectiveness of the personalized 3D printed model.Conclusions: 3D printing technology can improve understanding of the anatomy, decrease the operation time, and reduce the potential risk of thoracoscopic anatomical partial lobectomy in stage I lung cancer. A pre-operative rating scale was designed to standardize the application of this technology.

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“…Furthermore, these 3D digital models can be converted into tangible, physical models by way of 3D printing [ 8 , 9 ]. Rather than 3D visualization where a volumetric model is viewed on a 2D computer screen, a 3D printed model can provide a real indication of depth and tactile feedback, thus allowing surgeons to develop a clearer understanding of surgical anatomy [ 10 , 11 ]. With a better visualization of disease location relative to adjacent organs, surgeons utilising 3D printed models for pre-operative planning have been shown to have greater surgical outcomes including, decreased operative time [ 12 – 14 ], blood loss [ 12 , 13 ], and incision length [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

A review and guide to creating patient specific 3D printed anatomical models from MRI for benign gynecologic surgery

et al. 2021

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Background Patient specific three-dimensional (3D) models can be derived from two-dimensional medical images, such as magnetic resonance (MR) images. 3D models have been shown to improve anatomical comprehension by providing more accurate assessments of anatomical volumes and better perspectives of structural orientations relative to adjacent structures. The clinical benefit of using patient specific 3D printed models have been highlighted in the fields of orthopaedics, cardiothoracics, and neurosurgery for the purpose of pre-surgical planning. However, reports on the clinical use of 3D printed models in the field of gynecology are limited. Main text This article aims to provide a brief overview of the principles of 3D printing and the steps required to derive patient-specific, anatomically accurate 3D printed models of gynecologic anatomy from MR images. Examples of 3D printed models for uterine fibroids and endometriosis are presented as well as a discussion on the barriers to clinical uptake and the future directions for 3D printing in the field of gynecological surgery. Conclusion Successful gynecologic surgery requires a thorough understanding of the patient’s anatomy and burden of disease. Future use of patient specific 3D printed models is encouraged so the clinical benefit can be better understood and evidence to support their use in standard of care can be provided.

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Operative Planning in Thoracic Surgery: A Pilot Study Comparing Imaging Techniques and Three-Dimensional Printing

Cited by 20 publications

References 20 publications

3D printed bismuth oxide‐polylactic acid composites for radio‐mimetic computed tomography spine phantoms

3D printed bismuth oxide‐polylactic acid composites for radio‐mimetic computed tomography spine phantoms

Three-dimensional reconstruction/personalized three-dimensional printed model for thoracoscopic anatomical partial-lobectomy in stage I lung cancer: a retrospective study

A review and guide to creating patient specific 3D printed anatomical models from MRI for benign gynecologic surgery

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