Design, printing optimization, and material testing of a 3D-printed nasal osteotomy task trainer.

IF 3.2 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Lauren Schlegel, Eric Malani, Sara Belko, Ayan Kumar, Eric Barbarite, Howard Krein, Ryan Heffelfinger, Morgan Hutchinson, Robert Pugliese
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引用次数: 1

Abstract

Background: For difficult or rare procedures, simulation offers an opportunity to provide education and training. In developing an adequate model to utilize in simulation, 3D printing has emerged as a useful technology to provide detailed, accessible, and high-fidelity models. Nasal osteotomy is an essential step in many rhinoplasty surgeries, yet it can be challenging to perform and difficult to receive adequate exposure to this nuanced portion of the procedure. As it currently stands, there are limited opportunities to practice nasal osteotomy due to the reliance on cadaveric bones, which are expensive, difficult to obtain, and require appropriate facilities and personnel. While previous designs have been developed, these models leave room for improvement in printing efficiency, cost, and material performance. This manuscript aims to describe the methodology for the design of an updated nasal osteotomy training model derived from anatomic data and optimized for printability, usability, and fidelity. Additionally, an analysis of multiple commercially available 3D printing materials and technologies was conducted to determine which offered superior equivalency to bone.

Methods: This model was updated from a first-generation model previously described to include a more usable base and form, reduce irrelevant structures, and optimize geometry for 3D printing, while maintaining the nasal bones with added stabilizers essential for function and fidelity. For the material comparison, this updated model was printed in five materials: Ultimaker Polylactic Acid, 3D Printlife ALGA, 3DXTECH SimuBone, FibreTuff, and FormLabs Durable V2. Facial plastic surgeons tested the models in a blinded, randomized fashion and completed surveys assessing tactile feedback, audio feedback, material limitation, and overall value.

Results: A model optimizing printability while maintaining quality in the area of interest was developed. In the material comparison, SimuBone emerged as the top choice amongst the evaluating physicians in an experience-based subjective comparison to human bone during a simulated osteotomy procedure using the updated model.

Conclusion: The updated midface model that was user-centered, low-cost, and printable was designed. In material testing, Simubone was rated above other materials to have a more realistic feel.

Abstract Image

Abstract Image

Abstract Image

3d打印鼻截骨任务训练器的设计、打印优化和材料测试。
背景:对于困难或罕见的程序,模拟提供了提供教育和培训的机会。在开发一个适当的模型,以利用模拟,3D打印已经成为一种有用的技术,提供详细的,可访问的,高保真模型。鼻截骨术是许多鼻整形手术中必不可少的一步,但它的执行可能具有挑战性,并且难以充分暴露于手术的这一微妙部分。就目前的情况而言,由于依赖于尸体骨骼,因此实施鼻截骨术的机会有限,而尸体骨骼价格昂贵,难以获得,并且需要适当的设施和人员。虽然以前的设计已经开发出来,但这些模型在打印效率、成本和材料性能方面留下了改进的空间。本文旨在描述一个更新的鼻截骨训练模型的设计方法,该模型来源于解剖学数据,并优化了可打印性、可用性和保真度。此外,对多种商用3D打印材料和技术进行了分析,以确定哪种材料和技术具有更好的骨等效性。方法:该模型从先前描述的第一代模型更新,包括更可用的基础和形式,减少不相关的结构,并优化3D打印的几何形状,同时通过添加稳定剂来保持鼻骨的功能和保真度。为了进行材料比较,这个更新的模型用五种材料打印:Ultimaker聚乳酸、3D Printlife藻类、3DXTECH SimuBone、FibreTuff和FormLabs Durable V2。面部整形外科医生对这些模型进行了盲法随机测试,并完成了评估触觉反馈、音频反馈、材料限制和整体价值的调查。结果:一个模型优化印刷可印刷性,同时保持在感兴趣的领域的质量被开发。在材料比较中,在基于经验的主观比较中,SimuBone成为评估医生在使用更新模型进行模拟截骨手术时与人骨的首选。结论:设计了以用户为中心、低成本、可打印的更新版中脸模型。在材料测试中,Simubone被评为比其他材料更真实的感觉。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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