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Micro/nanofabrication of brittle hydrogels using 3D printed soft ultrafine fiber molds for damage-free demolding

材料科学 自愈水凝胶 微流控 脆性 纳米光刻 复合材料 3D打印 模具 生物相容性 制作 纳米技术 高分子化学 冶金 医学 替代医学 病理
作者
Shang Lv,Jing Nie,Qing Gao,Chaoqi Xie,Luyu Zhou,Jingjiang Qiu,Jianzhong Fu,Xin Zhao,Yong He
出处
期刊:Biofabrication [IOP Publishing]
卷期号:12 (2): 025015-025015 被引量:46
标识
DOI:10.1088/1758-5090/ab57d8
摘要

Hydrogels are very popular in biomedical areas for their extraordinary biocompatibility.However, most bio-hydrogels are too brittle to perform micro/nanofabrication.An effective method is cast molding; yet during this process, many defects occur as the excessive demolding stress damages the brittle hydrogels.Here, we propose a brand-new damage-free demolding method and a soft ultrafine fiber mold (SUFM) to replace the traditional mold.Both mechanical and finite element analysis (FEA) reveal that SUFMs have obvious advantages especially when the contact area between hydrogel and mold gets larger.By means of a high-resolution 3D printing called electrohydrodynamic (EHD) printing, SUFMs with various topological structures can be achieved with the fiber diameter ranging from 500 nm to 100 μm at a low cost.Microfluidics and cell patterns are implemented as the demonstration for potential applications.Owing to the tiny scale of microstructures and the hydrophilicity of hydrogels, significant capillary effect occurs which can be utilized to deliver liquid and cells autonomously and to seed cells into those ultrafine channels evenly.The results open up a new avenue for a wider use of hydrogels in biomedical devices, tissue engineering, microfluidics and wearable electronics; the proposed fabrication method also has the potential to become a universal technique for micro/nanofabrication of brittle materials.

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