Lip Ket Chin scite author profile

Cell refractive index is a key biophysical parameter, which has been extensively studied. It is correlated with other cell biophysical properties including mechanical, electrical and optical properties, and not only represents the intracellular mass and concentration of a cell, but also provides important insight for various biological models. Measurement techniques developed earlier only measure the effective refractive index of a cell or a cell suspension, providing only limited information on cell refractive index and hence hindering its in-depth analysis and correlation. Recently, the emergence of microfluidic, photonic and imaging technologies has enabled the manipulation of a single cell and the 3D refractive index of a single cell down to sub-micron resolution, providing powerful tools to study cells based on refractive index. In this review, we provide an overview of cell refractive index models and measurement techniques including microfluidic chip-based techniques for the last 50 years, present the applications and significance of cell refractive index in cell biology, hematology, and pathology, and discuss future research trends in the field, including 3D imaging methods, integration with microfluidics and potential applications in new and breakthrough research areas.

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Nanometer-precision linear sorting with synchronized optofluidic dual barriers

Shi

et al. 2018

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Nuclear deformation during breast cancer cell transmigration

Chin

Bourouina³

et al. 2012

Lab Chip

107

103

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Metastasis is the main cause of cancer mortality. During this process, cancer cells dislodge from a primary tumor, enter the circulation and form secondary tumors in distal organs. It is poorly understood how these cells manage to cross the tight syncytium of endothelial cells that lines the capillaries. Such capillary transmigration would require a drastic change in cell shape. We have therefore developed a microfluidic platform to study the transmigration of cancer cells. The device consists of an array of microchannels mimicking the confined spaces encountered. A thin glass coverslip bottom allows high resolution imaging of cell dynamics. We show that nuclear deformation is a critical and rate-limiting step for transmigration of highly metastatic human breast cancer cells. Transmigration was significantly reduced following the treatment with a protein methyltransferase inhibitor, suggesting that chromatin condensation might play an important role. Since transmigration is critical for cancer metastasis, this new platform may be useful for developing improved cancer therapies.

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A Flat Lens with Tunable Phase Gradient by Using Random Access Reconfigurable Metamaterial

et al. 2015

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Stirring in Suspension: Nanometer‐Sized Magnetic Stir Bars

et al. 2013

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Lip Ket Chin

Cell refractive index for cell biology and disease diagnosis: past, present and future

Nanometer-precision linear sorting with synchronized optofluidic dual barriers

Nuclear deformation during breast cancer cell transmigration

A Flat Lens with Tunable Phase Gradient by Using Random Access Reconfigurable Metamaterial

Stirring in Suspension: Nanometer‐Sized Magnetic Stir Bars

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