微流控
微加工
材料科学
纳米技术
结构完整性
药物输送
涂层
制作
结构工程
工程类
医学
病理
替代医学
作者
Rujie Sun,Xin Song,Kun Zhou,Yuyang Zuo,Richard Wang,Omar Rifaie‐Graham,David J. Peeler,Ruoxiao Xie,Yixuan Leng,Hongya Geng,Giulia Brachi,Yun Ma,Yutong Liu,Lorna Barron,Molly M. Stevens
标识
DOI:10.1002/adma.202207791
摘要
Microrobots can provide spatiotemporally well-controlled cargo delivery that can improve therapeutic efficiency compared to conventional drug delivery strategies. Robust microfabrication methods to expand the variety of materials or cargoes that can be incorporated into microrobots can greatly broaden the scope of their functions. However, current surface coating or direct blending techniques used for cargo loading result in inefficient loading and poor cargo protection during transportation, which leads to cargo waste, degradation and non-specific release. Herein, a versatile platform to fabricate fillable microrobots using microfluidic loading and dip sealing (MLDS) is presented. MLDS enables the encapsulation of different types of cargoes within hollow microrobots and protection of cargo integrity. The technique is supported by high-resolution 3D printing with an integrated microfluidic loading system, which realizes a highly precise loading process and improves cargo loading capacity. A corresponding dip sealing strategy is developed to encase and protect the loaded cargo whilst maintaining the geometric and structural integrity of the loaded microrobots. This dip sealing technique is suitable for different materials, including thermal and light-responsive materials. The MLDS platform provides new opportunities for microrobotic systems in targeted drug delivery, environmental sensing, and chemically powered micromotor applications.
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