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High-throughput and simultaneous inertial separation of tumor cells and clusters from malignant effusions using spiral-contraction-expansion channels

Medicine and Health

High-throughput and simultaneous inertial separation of tumor cells and clusters from malignant effusions using spiral-contraction-expansion channels

Z. Zhu, H. Ren, et al.

This innovative microfluidic method by Zhixian Zhu, Hui Ren, Dan Wu, Zhonghua Ni, and Nan Xiang revolutionizes the separation of tumor and white blood cells from malignant effusions, achieving over 97% recovery of vital tumor cells and impressive speed. Explore how this technology enhances cytological diagnosis!

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Playback language: English
Abstract
This paper presents a novel microfluidic approach for high-throughput, continuous-flow ternary separation of single tumor cells, tumor cell clusters, and white blood cells (WBCs) from malignant effusions. The method uses a spiral-contraction-expansion channel design to leverage inertial lift force, Dean drag force, and vortex-induced lift force for size-based separation. Experiments showed >97% recovery of MDA-MB-231 tumor cells and >90% preservation of tumor cell clusters, with 94% WBC removal at a high flow rate of 3500 µL/min. The device successfully separated cells from clinical samples, showing potential for cytological diagnosis.
Publisher
Microsystems & Nanoengineering
Published On
Jan 01, 2024
Authors
Zhixian Zhu, Hui Ren, Dan Wu, Zhonghua Ni, Nan Xiang
Tags
microfluidics
tumor cell separation
white blood cells
clinical samples
cytological diagnosis
high-throughput
inertial lift force

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