材料科学
3D打印
微尺度化学
自愈水凝胶
制作
纳米技术
微流控
减色
数字光处理
激光器
光子学
计算机科学
光电子学
复合材料
光学
医学
数学教育
数学
替代医学
物理
投影机
病理
高分子化学
计算机视觉
作者
Puskal Kunwar,Zheng Xiong,Yin Zhu,Haiyan Li,Alex Filip,Pranav Soman
标识
DOI:10.1002/adom.201900656
摘要
Abstract Fabrication of multiscale, multimaterial 3D structures at high resolution is difficult using current technologies. This is especially significant when working with mechanically weak hydrogels. Here, a new hybrid laser printing (HLP) technology is reported to print complex, multiscale, multimaterial, 3D hydrogel structures with microscale resolution. This technique utilizes sequential additive and subtractive modes of fabrication, that are typically considered as mutually exclusive due to differences in their material processing conditions. Further, compared to current laser writing systems that enforce stringent processing depth limits, HLP is shown to fabricate structures at any depth inside the material. As a proof‐of‐principle, a Mayan pyramid with embedded cube frame is printed using synthetic polyethylene glycol diacrylate (PEGDA) hydrogel. Printing of ready‐to‐use open‐well chips with embedded microchannels is also demonstrated using PEGDA and gelatin methacrylate (GelMA) hydrogels for potential applications in biomedical sciences. Next, HLP is used in additive–additive modes to print multiscale 3D structures spanning in size from centimeter to micrometers within minutes, which is followed by printing of 3D, multimaterial, multiscale structures using this technology. Overall, this work demonstrates that HLP's fabrication versatility can potentially offer a unique opportunity for a range of applications in optics and photonics, biomedical sciences, microfluidics, etc.
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