Direct dielectrophoretic characterization of particles in the high-density microwell array using optical tweezers

•Direct observation and measurement of dielectrophoresis of particle/cell.•Force balance system based on high-density microwell chip and optical tweezers.•Calibration of high reliability customized hologram optical tweezers system.•Contrast the influences of various factors on dielectrophoresis beha...

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Bibliographic Details
Published in:Optics and lasers in engineering 2024-03, Vol.174, p.107976, Article 107976
Main Authors: Luo, Xiao, Wu, Chunhui, Zhang, Jie, Xu, Junyan, Tan, Handong, Zhang, Beini, Xie, Jiesi, Tao, Chaoran, Huang, Kaicheng, Cheng, Xing, Wen, Weijia
Format: Article
Language:English
Subjects:
Dielectrophoresis
Microwell array chips
Optical sensing
Optical tweezers
Optomechanics
Single cell
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Summary:•Direct observation and measurement of dielectrophoresis of particle/cell.•Force balance system based on high-density microwell chip and optical tweezers.•Calibration of high reliability customized hologram optical tweezers system.•Contrast the influences of various factors on dielectrophoresis behaviors.•The system provides to study differentiation and diagnosis at the single-cell level. In this work, a quantitative and intuitive measurement of dielectrophoresis (DEP) behavior in a high-density dielectrophoretic microwell array chip was accomplished in assistance with the holographic optical tweezers. A one-dimensional force balance system with high reliability was achieved between the transverse optical trapping (TOT) force and the DEP force. The value of the DEP force was inferred by accurately calculating the TOT force, and the direction of the DEP force was observed with high-magnification microscopy. In order to estimate the availability and operability of the DEP force measurement system, we systematically investigated the influences of various external factors on the DEP behaviors of microspheres and live cells. All the quantitative measurement results, which agree well with the theory, showed that this system could serve as an accurate research tool for DEP behavior characterizations to optimize and improve the DEP-based manipulations of microparticles and live cells for a broad range of applications. The system also provides an approach to quantitatively obtain important parameters such as Clausius-Mossotti factors for cells in mediums, which could potentially be used to understand the dielectric properties of different types of cells for cell differentiation and diagnosis at the single-cell level. A quantitative and intuitive measurement of dielectrophoresis behavior was accomplished with assistance from the holographic optical tweezers. [Display omitted]
ISSN:0143-8166
1873-0302
DOI:10.1016/j.optlaseng.2023.107976