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一种高性能的开源注射器挤出机,针对FRESH 3D生物打印过程中的挤出和回缩进行了优化。

A high performance open-source syringe extruder optimized for extrusion and retraction during FRESH 3D bioprinting.

作者信息

Tashman Joshua W, Shiwarski Daniel J, Feinberg Adam W

机构信息

Department of Biomedical Engineering, Carnegie Mellon University, Pittsburgh, PA, United States.

Department of Materials Science & Engineering, Carnegie Mellon University, Pittsburgh, PA, United States.

出版信息

HardwareX. 2021 Apr;9. doi: 10.1016/j.ohx.2020.e00170. Epub 2021 Jan 1.

DOI:10.1016/j.ohx.2020.e00170
PMID:34746519
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8570565/
Abstract

Recent advances in embedded 3D bioprinting have significantly improved the resolution of individual filaments to below 100 μm; however, printing with such small filaments requires accurate extrusion of nanoliter volumes of bioink. Commercially available bioprinters and extruders are expensive and most utilize pneumatic control, which limits the minimum extrusion volume and prevents retraction (pulling bioink back into the reservoir), which is essential to printing high resolution features and complex internal geometry. Here we present a new generation of our open-source syringe pump designed for extrusion-based 3D bioprinting of soft materials: the Replistruder 4. The Replistruder 4 takes advantage of the geometry customizability and ease of 3D plastic printing while improving performance by integrating mass produced high-precision linear motion components. Simultaneously this new syringe pump remains compact and lightweight enough for several to be utilized on a 3D bioprinter for multimaterial bioprinting. To facilitate multiple use cases the Replistruder 4 is compatible with a range of syringes including disposable BD and Hamilton gastight syringes. In addition, we describe the process of designing clamps for other syringes. We demonstrate the performance of a Replistruder 4 with a 2.5 mL Hamilton gastight syringe by printing collagen type I constructs with individual filaments comprising 3.35 nL and patent channels down to 300 μm in width. With smaller volume Hamilton gastight syringes this performance can be further improved. Thus, the Replistruder 4 provides an open-source solution to print soft materials at the resolution limits of current embedded bioprinting platforms.

摘要

嵌入式3D生物打印技术的最新进展已将单根细丝的分辨率显著提高至100μm以下;然而,使用如此细的细丝进行打印需要精确挤出纳升级体积的生物墨水。市售的生物打印机和挤出机价格昂贵,且大多采用气动控制,这限制了最小挤出体积,并阻碍了回抽(将生物墨水抽回储液器),而回抽对于打印高分辨率特征和复杂内部几何结构至关重要。在此,我们展示了新一代专为基于挤出的软材料3D生物打印设计的开源注射泵:Replistruder 4。Replistruder 4利用了几何形状的可定制性以及3D塑料打印的便捷性,同时通过集成大量生产的高精度直线运动部件来提高性能。与此同时,这款新型注射泵保持了紧凑轻便的特点,足以让多个泵在一台3D生物打印机上用于多材料生物打印。为便于多种应用场景,Replistruder 4与一系列注射器兼容,包括一次性BD注射器和汉密尔顿气密注射器。此外,我们还描述了为其他注射器设计夹具的过程。我们通过打印由3.35 nL单根细丝组成且宽度低至300μm的专利通道的I型胶原蛋白构建体,展示了配备2.5 mL汉密尔顿气密注射器的Replistruder 4的性能。使用体积更小的汉密尔顿气密注射器,这种性能还可进一步提升。因此,Replistruder 4提供了一种开源解决方案,可在当前嵌入式生物打印平台的分辨率极限下打印软材料。

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