Litcius/Paper detail

Microfluidic Impedance‐Deformability Cytometry for Label‐Free Single Neutrophil Mechanophenotyping

Chayakorn Petchakup, Haoning Yang, Lingyan Gong, Linwei He, Hui Min Tay, Rinkoo Dalan, Aram J. Chung, King Ho Holden Li, Han Wei Hou

2022Small69 citationsDOI

Abstract

Abstract The intrinsic biophysical states of neutrophils are associated with immune dysfunctions in diseases. While advanced image‐based biophysical flow cytometers can probe cell deformability at high throughput, it is nontrivial to couple different sensing modalities (e.g., electrical) to measure other critical cell attributes including cell viability and membrane integrity. Herein, an “optics‐free” impedance‐deformability cytometer for multiparametric single cell mechanophenotyping is reported. The microfluidic platform integrates hydrodynamic cell pinching, and multifrequency impedance quantification of cell size, deformability, and membrane impedance (indicative of cell viability and activation). A newly‐defined “electrical deformability index” is validated by numerical simulations, and shows strong correlations with the optical cell deformability index of HL‐60 experimentally. Human neutrophils treated with various biochemical stimul are further profiled, and distinct differences in multimodal impedance signatures and UMAP analysis are observed. Overall, the integrated cytometer enables label‐free cell profiling at throughput of >1000 cells min −1 without any antibodies labeling to facilitate clinical diagnostics.

Topics & Concepts

MicrofluidicsCytometryFlow cytometryElectrical impedanceCellViability assayMaterials scienceBiomedical engineeringNanotechnologySingle-cell analysisBiophysicsCell membraneMembraneChemistryImmunologyBiologyBiochemistryMedicineElectrical engineeringEngineeringMicrofluidic and Bio-sensing TechnologiesMicrofluidic and Capillary Electrophoresis ApplicationsBiosensors and Analytical Detection