建立用于临床的即时护理增材制造工作流程。

Establishing a point-of-care additive manufacturing workflow for clinical use.

作者信息

Daoud Georges E, Pezzutti Dante L, Dolatowski Calvin J, Carrau Ricardo L, Pancake Mary, Herderick Edward, VanKoevering Kyle K

机构信息

The Ohio State University College of Medicine, Columbus, OH USA.

Department of Engineering, The Ohio State University, Columbus, OH USA.

出版信息

J Mater Res. 2021;36(19):3761-3780. doi: 10.1557/s43578-021-00270-x. Epub 2021 Jul 6.

DOI:10.1557/s43578-021-00270-x

PMID:34248272

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8259775/

Abstract

Additive manufacturing, or 3-Dimensional (3-D) Printing, is built with technology that utilizes layering techniques to build 3-D structures. Today, its use in medicine includes tissue and organ engineering, creation of prosthetics, the manufacturing of anatomical models for preoperative planning, education with high-fidelity simulations, and the production of surgical guides. Traditionally, these 3-D prints have been manufactured by commercial vendors. However, there are various limitations in the adaptability of these vendors to program-specific needs. Therefore, the implementation of a point-of-care in-house 3-D modeling and printing workflow that allows for customization of 3-D model production is desired. In this manuscript, we detail the process of additive manufacturing within the scope of medicine, focusing on the individual components to create a centralized in-house point-of-care manufacturing workflow. Finally, we highlight a myriad of clinical examples to demonstrate the impact that additive manufacturing brings to the field of medicine.

摘要

增材制造，即三维（3D）打印，是基于利用分层技术构建三维结构的技术而建立的。如今，其在医学中的应用包括组织和器官工程、假肢制造、用于术前规划的解剖模型制作、高保真模拟教育以及手术导板的生产。传统上，这些3D打印件是由商业供应商制造的。然而，这些供应商在适应特定程序需求方面存在各种限制。因此，需要实施一种床旁内部三维建模和打印工作流程，以实现三维模型生产的定制。在本手稿中，我们详细介绍了医学范围内的增材制造过程，重点关注各个组件，以创建一个集中的内部床旁制造工作流程。最后，我们列举了大量临床实例，以证明增材制造给医学领域带来的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cbc8/8259775/0cd76beb5d96/43578_2021_270_Fig1_HTML.jpg

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建立用于临床的即时护理增材制造工作流程。

Establishing a point-of-care additive manufacturing workflow for clinical use.

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