Issue 14, 2017

A high throughput microfluidic platform for size-selective enrichment of cell populations in tissue and blood samples

Abstract

Numerous applications in biology and medicine require the efficient and reliable separation of cells for disease diagnosis, genetic analysis, drug screening, and therapeutics. In this work, we demonstrate a novel technology that integrates a passive and an active device to separate, enrich and release cells on-demand from a complex blood sample, or cancer cells derived from a tissue biopsy. We exploit the high throughput (>1 mL min−1), size-based sorting capability of the passive spiral inertial microfluidic (iMF) device to focus particles/cells towards an active lateral cavity acoustic transducer (LCAT) device for size-selective enrichment. We demonstrate that this platform is capable of efficiently (>90%) removing smaller cells, such as RBCs in a blood sample or smaller cancer cells in a heterogeneous cell line, and providing 44 000× enrichment from the remaining sample within 5 min of device operation. Finally, we use this platform for two applications: selective enrichment of the side-population of DU-145 cells from tissue biopsy and isolation of larger monocytes from blood. Our platform integrates the high throughput (processing rate) capacity of spiral iMF with the high selectivity of LCAT, thereby offering a unique route for highly-selective, label-free particle/cell sorting, with potential application in lab-on-chip platforms for liquid biopsy and diagnostics applications.

Graphical abstract: A high throughput microfluidic platform for size-selective enrichment of cell populations in tissue and blood samples

Supplementary files

Article information

Article type
Paper
Submitted
18 Feb 2017
Accepted
14 May 2017
First published
21 Jun 2017

Analyst, 2017,142, 2558-2569

A high throughput microfluidic platform for size-selective enrichment of cell populations in tissue and blood samples

N. Nivedita, N. Garg, A. P. Lee and I. Papautsky, Analyst, 2017, 142, 2558 DOI: 10.1039/C7AN00290D

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