在三维聚合物结构上电流体动力打印可生物降解的 PLGA 微图案

IlHo Seo, Rizwan Ul Hassan, Byeongseok Ryu, Won‐Gun Koh, WonHyoung Ryu
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引用次数: 0

摘要

聚乳酸-共聚乙醇酸(PLGA)等生物可降解聚合物以不同的形式用于各种植入式装置,如组织支架、给药装置和生物传感器。然而,生物可降解聚合物在植入设备上的高分辨率图案化尚未得到广泛探索。虽然与其他打印方法相比,电流体动力打印(EHD)可以实现高分辨率打印,但由于打印不稳定,很少尝试对 PLGA 溶液进行 EHD 打印。这种印刷不稳定性源于 PLGA 油墨的挥发性,它会导致喷嘴堵塞或印刷过程中油墨条件的改变。本文研究了 PLGA 油墨配方和电压输入曲线,以实现稳定的高分辨率 EHD 印刷。以最佳比例添加甘油以及控制电压脉冲形状对 PLGA 图形的 EHD 印刷稳定性和分辨率都有很大影响。通过优化油墨和电压输入,可在导电和绝缘表面上稳定打印出小至 5 微米的 PLGA 微图案,从而实现药物的可控释放。此外,使用环型电极还可以在 PLLA 管和支架支柱的三维表面上进行 PLGA 微图案的 EHD 打印。
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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Electrohydrodynamic Printing of Biodegradable PLGA Micro‐Patterns on 3D Polymer Structures
Biodegradable polymers such as polylactic‐co‐glycolic acids (PLGA) are used for various implantable devices such as tissue scaffolds, drug delivery devices, and biosensors in different forms. However, high‐resolution patterning of biodegradable polymers on implantable devices has not been explored much yet. While electrohydrodynamic printing (EHD) can achieve high‐resolution printing compared to other printing methods, EHD printing of PLGA solutions is rarely attempted due to unstable printing. Such printing instability originates from the volatile nature of PLGA inks, and it causes nozzle clogging or change of ink conditions during printing. Here, PLGA ink formulation and a voltage input profile are studied for stable and high‐resolution EHD printing. Addition of glycerol at an optimal ratio as well as the control of voltage pulse shape strongly influenced both the stability and resolution of EHD printing of PLGA patterns. With the optimized inks and voltage inputs, stable printing of PLGA micropatterns down to 5 µm is achieved on both conductive and insulating surfaces for controlled drug release. Furthermore, use of a ring type electrode allows for EHD printing of PLGA micropatterns on 3D surfaces of PLLA tubes and stent struts.
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