Carlos Ezio Garciamendez-Mijares, Gilberto Emilio Guerra-Alvarez, Mónica Gabriela Sánchez-Salazar1,4, Andrés García-Rubio, Germán García-Martínez, Anne-Sophie Mertgen, C. Ceballos-González, Edna Johana Bolívar-Monsalve, Yu Shrike Zhang, G. Santiago, M. M. Álvarez
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This is achieved by circulating temperature-controlled water within the printhead, which is engineered as a single 3D-printed component consisting of a water-recirculation jacket surrounding the ink/bioink cartridge. The flexibility to circulate either warm or cold water allows the system to be adapted according to the needs dictated by the bioink composition. Herein, we demonstrate the ability to control the printability of GelMA or Pluronic fibers by decreasing or increasing the temperature, respectively, thereby regulating its viscosity. In addition, any commercial needle with a Luer lock can be incorporated into the printhead, allowing the easy fabrication of fibers of different diameters with a single printhead. 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引用次数: 0
摘要
生物打印机作为再生医学和其他生物医学工程应用的推动者显示出巨大的前景。在这项工作中,我们提出了一种灵活且具有成本效益的diy生物打印机设计,能够以0.05-0.1 mL/min的流速和500-700 μm的有效分辨率打印/生物打印明胶甲基丙烯酰(GelMA)和Pluronic结构。这种生物打印机最显著的特点是它能够控制生物墨水的流变性,只需在打印过程中调整挤出温度。这是通过在打印头内循环温度控制的水来实现的,打印头被设计成一个单一的3d打印组件,由围绕墨水/生物墨水墨盒的水循环套组成。温水或冷水循环的灵活性使系统能够根据生物链接成分的需要进行调整。在这里,我们展示了通过分别降低或提高温度来控制GelMA或Pluronic纤维的可打印性,从而调节其粘度的能力。此外,任何具有鲁尔锁的商业针都可以并入打印头,允许使用单个打印头轻松制造不同直径的纤维。我们证明了我们的生物打印机能够以高保真度打印简单的2D结构(即厚度为~522±36.83 μm的GelMA线可以以100 mm min - 1的线性速度打印)和由多达五层细胞负载的5% GelMA组成的3D结构。我们还证明了通过针尖(直径300 μm)生物打印的C2C12细胞具有足够的打印后活力(~90%),并且在培养7天后扩散。这种生物打印机的介绍可能会对生物打印机的使用做出显着的贡献,因为它的制造总体成本低,灵活性和开源特性,可修改和适应使用不同的3d打印打印头,以及使用GelMA进行生物打印的能力。
Development of an affordable extrusion 3D bioprinter equipped with a temperature-controlled printhead
Bioprinters show great promise as enablers of regenerative medicine and other biomedical engineering applications. In this work, we present a flexible and cost-effective design for a do-it-yourself bioprinter capable of printing/bioprinting gelatin methacryloyl (GelMA) and Pluronic constructs at flow rates of 0.05–0.1 mL/min and effective resolutions of 500–700 μm. The most distinctive feature of this bioprinter is its ability to control the rheology of bioinks simply by adjusting the extrusion temperature during printing. This is achieved by circulating temperature-controlled water within the printhead, which is engineered as a single 3D-printed component consisting of a water-recirculation jacket surrounding the ink/bioink cartridge. The flexibility to circulate either warm or cold water allows the system to be adapted according to the needs dictated by the bioink composition. Herein, we demonstrate the ability to control the printability of GelMA or Pluronic fibers by decreasing or increasing the temperature, respectively, thereby regulating its viscosity. In addition, any commercial needle with a Luer lock can be incorporated into the printhead, allowing the easy fabrication of fibers of different diameters with a single printhead. We showed that our bioprinter is capable of printing simple 2D constructs with high fidelity (i.e., lines of GelMA with a thickness of ~522 ± 36.83 μm can be printed at linear speeds of 100 mm min−1) and 3D constructs composed of as many as five layers of cell-laden 5% GelMA. We also demonstrated that C2C12 cells bioprinted through needle tips (300 μm in diameter) exhibit adequate post-printing viability (~90%), as well as spreading after 7 days of culture. The presentation of this bioprinter may contribute appreciably to the expansion of bioprinter use due to its low overall cost of manufacture, flexibility and open-source character, amenability to modification and adaptation for use with different 3D-printed printheads, and ability to bioprint using GelMA.
期刊介绍:
The International Journal of Bioprinting is a globally recognized publication that focuses on the advancements, scientific discoveries, and practical implementations of Bioprinting. Bioprinting, in simple terms, involves the utilization of 3D printing technology and materials that contain living cells or biological components to fabricate tissues or other biotechnological products. Our journal encompasses interdisciplinary research that spans across technology, science, and clinical applications within the expansive realm of Bioprinting.
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