High-throughput physical phenotyping of cell differentiation

Lin, Jonathan; Kim, Donghyuk; Tse, Henry T. K.; Tseng, Peter; Peng, Lillian; Dhar, Manjima; Saravanan, Konda Mani; Carlo, Dino Di

doi:10.1038/micronano.2017.13

Cited by 69 publications

(70 citation statements)

References 51 publications

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“…Previous studies have shown that different microfluidic flow regimes can alter the mechanical response of cells. Gossett et al (14,17,18) developed the technique deformability cytometry (DC) (19,20) in which cells are hydrodynamically stretched at the stagnation point (SP) of an extensional flow device at rates up to 2000 cells/s. A compressional force (F C ) due to fluid inertia and a shear force (F S ) due to fluid viscosity act on the cells.…”

Section: Introductionmentioning

confidence: 99%

Cells Under Stress: An Inertial-Shear Microfluidic Determination of Cell Behavior

Armistead

Pablo

Gadêlha

et al. 2019

Biophysical Journal

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The deformability of a cell is the direct result of a complex interplay between the different constituent elements at the subcellular level, coupling a wide range of mechanical responses at different length scales. Changes to the structure of these components can also alter cell phenotype, which points to the critical importance of cell mechanoresponse for diagnostic applications. The response to mechanical stress depends strongly on the forces experienced by the cell. Here, we use cell deformability in both shear-dominant and inertia-dominant microfluidic flow regimes to probe different aspects of the cell structure. In the inertial regime, we follow cellular response from (visco-)elastic through plastic deformation to cell structural failure and show a significant drop in cell viability for shear stresses >11.8 kN/m 2 . Comparatively, a shear-dominant regime requires lower applied stresses to achieve higher cell strains. From this regime, deformation traces as a function of time contain a rich source of information including maximal strain, elastic modulus, and cell relaxation times and thus provide a number of markers for distinguishing cell types and potential disease progression. These results emphasize the benefit of multiple parameter determination for improving detection and will ultimately lead to improved accuracy for diagnosis. We present results for leukemia cells (HL60) as a model circulatory cell as well as for a colorectal cancer cell line, SW480, derived from primary adenocarcinoma (Dukes stage B). SW480 were also treated with the actin-disrupting drug latrunculin A to test the sensitivity of flow regimes to the cytoskeleton. We show that the shear regime is more sensitive to cytoskeletal changes and that large strains in the inertial regime cannot resolve changes to the actin cytoskeleton.

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Section: Introductionmentioning

confidence: 99%

Cells Under Stress: An Inertial-Shear Microfluidic Determination of Cell Behavior

Armistead

Pablo

Gadêlha

et al. 2019

Biophysical Journal

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“…The differentiation of progenitor cells is coupled to major changes in their mechanical properties. This is partially due to differences in intracellular organisation and composition [Yourek et al., ; Darling et al., ; Lin et al., ]. In some instances, progenitor mechanical properties can serve as predictive biomarkers for differentiation outcomes [González‐Cruz et al., ].…”

Section: Mechanical Evaluation Of Myeloid Cell Differentiationmentioning

confidence: 99%

The mechanics of myeloid cells

Bashant

Toepfner

Day

et al. 2020

Biology of the Cell

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The effects of cell size, shape and deformability on cellular function have long been a topic of interest. Recently, mechanical phenotyping technologies capable of analysing large numbers of cells in real time have become available. This has important implications for biology and medicine, especially haemato-oncology and immunology, as immune cell mechanical phenotyping, immunologic function, and malignant cell transformation are closely linked and potentially exploitable to develop new diagnostics and therapeutics. In this review, we introduce the technologies used to analyse cellular mechanical properties and review emerging findings following the advent of high throughput deformability cytometry. We largely focus on cells from the myeloid lineage, which are derived from the bone marrow and include macrophages, granulocytes and erythrocytes. We highlight advances in mechanical phenotyping of cells in suspension that are revealing novel signatures of human blood diseases and providing new insights into pathogenesis of these diseases. The contributions of mechanical phenotyping of cells in suspension to our understanding of drug mechanisms, identification of novel therapeutics and monitoring of treatment efficacy particularly in instances of haematologic diseases are reviewed, and we suggest emerging topics of study to explore as high throughput deformability cytometers become prevalent in laboratories across the globe.

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“…In addition, more improvements in the user interface of microfluidic devices and software are also important requirements for the usage in the clinical situations by clinical doctors, not only by engineers in laboratories. In this paradigm, automation of both the hardware and software is another important topic to be addressed, and has been intensively investigated [91][92][93][94][95]. For the on-chip cell manipulation, we are also developing the automation of the gain-tuning toward clinical usages [96].…”

Section: Medical Applicationsmentioning

confidence: 99%

On-chip cell manipulation and applications to deformability measurements

Ito

Kaneko

2020

Robomech J

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Active microfluidics for the applications to cellular deformability measurements is an emerging research field ranging from engineering to medicine. Here, we review conventional and microfluidic methods, and introduce an on-chip cell manipulation system with the design principle of fast and fine cell manipulation inside a microchannel. In the latter part of the review, we focus on the results of red blood cell (RBC) deformability measurements as one of the most frequently studied non-adherent cells by on-chip methods. The relationship between mechanical properties and biological structures/features, as well as medical/diagnostic applications, are also discussed.

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High-throughput physical phenotyping of cell differentiation

Cited by 69 publications

References 51 publications

Cells Under Stress: An Inertial-Shear Microfluidic Determination of Cell Behavior

Cells Under Stress: An Inertial-Shear Microfluidic Determination of Cell Behavior

The mechanics of myeloid cells

On-chip cell manipulation and applications to deformability measurements

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