3D/4D Printing in Additive Manufacturing: Process Engineering and Novel Excipients

3D and 4D Printing in Biomedical Applications Pub Date : 2018-12-14 DOI:10.1002/9783527813704.CH1

C. Muehlenfeld, S. Roberts

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引用次数: 12

Abstract

In recent years, additive manufacturing, which is more colloquially referred to as three-dimensional (3D) printing, has seen high-impact implementation in manufacturing applications in areas such as aeronautics, robotics, electronics, industrial goods, and even the food industry. These wide-ranging applications have resulted in a change in focus for biomedical research [1]. 3D printing is a generic term that describes various methods of constructing objects in a layer-by-layer manner. Although the birth of 3D printing dates back to 1984, when Charles Hull invented the first stereolithographic printer, 3D printing started to increasingly change the way in which manufacturing was performed from the year 2000 onward. This chapter will introduce the basic concepts of 3D and 4D printing technologies as they pertain to biomedical applications. In particular, 4D printing (printing of objects with the ability to change over time) has a strong potential for biomedical applications. Patient-specific products such as medical devices, tissue constructs (including muscle structures, bone, and ear tissue), and, eventually, artificial organs may be fabricated using 4D printing [2–6].

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增材制造中的3D/4D打印:工艺工程和新型辅料

近年来，增材制造，更通俗地称为三维(3D)打印，在航空、机器人、电子、工业产品甚至食品工业等领域的制造应用中已经看到了高影响力的实施。这些广泛的应用导致了生物医学研究重点的变化[1]。3D打印是一个通用术语，描述了以逐层方式构建对象的各种方法。尽管3D打印的诞生可以追溯到1984年，当时Charles Hull发明了第一台立体平版打印机，但从2000年开始，3D打印开始越来越多地改变制造方式。本章将介绍3D和4D打印技术的基本概念，因为它们与生物医学应用有关。特别是，4D打印(打印具有随时间变化能力的物体)在生物医学应用方面具有强大的潜力。患者特异性产品，如医疗器械、组织结构(包括肌肉结构、骨骼和耳组织)，以及最终的人造器官都可以使用4D打印制造[2-6]。

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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3D and 4D Printing in Biomedical Applications

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