Acoustofluidics for cell patterning and tissue engineering

Q1 Medicine

Engineered regeneration Pub Date : 2022-12-01 DOI:10.1016/j.engreg.2022.08.005

Zhuhao Wu , Meidie Pan , Jinglin Wang , Baojie Wen , Ling Lu , Haozhen Ren

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引用次数: 2

Abstract

Acoustofluidics has been a promising approach using sound waves to manipulate particles and actuate fluids in biomedical applications. It usually generates acoustic radiation force and acoustic streaming to initiate diffraction, reflection and interference, building up a pressure distribution to facilitate accurate manipulation of micro- or nano-scale particles and fluids. Owing to its remarkable contact-free and biocompatible advantages, acoustofluidics has been used in high-throughput cell analysis, size-controllable organoid structures, and functional tissue mimics. We enumerate the basic concepts and the sufficient research of acoustofluidics in precise patterning and tissue engineering in this review, including the design and function of four typical acoustofluidic devices, various forms of cell patterning and 3D tissue engineering. Meanwhile, we outlined current challenges and future directions of acoustofluidics in biomedicine and tissue engineering.

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细胞图像化和组织工程的声流体学

声流体学是一种很有前途的方法，利用声波来操纵粒子和驱动生物医学应用中的流体。它通常产生声辐射力和声流，引发衍射、反射和干涉，形成压力分布，便于对微纳米级颗粒和流体进行精确操作。由于其显著的无接触和生物相容性优势，声流体学已被用于高通量细胞分析、尺寸可控的类器官结构和功能组织模拟。本文综述了声流体学在精密成像和组织工程中的基本概念和研究现状，包括四种典型的声流体装置的设计和功能、各种形式的细胞成像和三维组织工程。同时，我们概述了声流体学在生物医学和组织工程中面临的挑战和未来的发展方向。

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