基于惯性微流控的无标记原代心肌细胞分离与单细胞生物物理表型分析。

Label-Free Isolation and Single Cell Biophysical Phenotyping Analysis of Primary Cardiomyocytes Using Inertial Microfluidics.

机构信息

Department of Telecommunications, Electrical, Robotics and Biomedical Engineering, Swinburne University of Technology, Hawthorn, Victoria, 3122, Australia.

Department of Pathology, School of Medical Sciences, University of New South Wales, Sydney, NSW, 2052, Australia.

出版信息

Small. 2021 Feb;17(8):e2006176. doi: 10.1002/smll.202006176. Epub 2020 Dec 28.

DOI:10.1002/smll.202006176

PMID:33369875

Abstract

To advance the understanding of cardiomyocyte (CM) identity and function, appropriate tools to isolate pure primary CMs are needed. A label-free method to purify viable CMs from mouse neonatal hearts is developed using a simple particle size-based inertial microfluidics biochip achieving purities of over 90%. Purified CMs are viable and retained their identity and function as depicted by the expression of cardiac-specific markers and contractility. The physico-mechanical properties of sorted cells are evaluated using downstream real-time deformability cytometry. CMs exhibited different physico-mechanical properties when compared with non-CMs. Taken together, this CM isolation and phenotyping method could serve as a valuable tool to progress the understanding of CM identity and function, and ultimately benefit cell therapy and diagnostic applications.

摘要

为了深入了解心肌细胞（CM）的特性和功能，我们需要合适的工具来分离纯净的原代 CM。本文开发了一种无标记的方法，利用基于粒径的简单惯性微流控生物芯片从新生鼠心脏中分离出活性良好的 CM，纯度超过 90%。分离得到的 CM 具有活性，并保留了其特性和功能，表现为心脏特异性标志物的表达和收缩性。通过下游实时变形细胞术评估分选细胞的物理力学特性。与非 CM 相比，CM 表现出不同的物理力学特性。综上所述，这种 CM 分离和表型分析方法可以作为深入了解 CM 特性和功能的有用工具，并最终有益于细胞治疗和诊断应用。

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基于惯性微流控的无标记原代心肌细胞分离与单细胞生物物理表型分析。

Label-Free Isolation and Single Cell Biophysical Phenotyping Analysis of Primary Cardiomyocytes Using Inertial Microfluidics.

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