2016
DOI: 10.1039/c6lc00169f
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The physical origins of transit time measurements for rapid, single cell mechanotyping

Abstract: The mechanical phenotype or 'mechanotype' of cells is emerging as a potential biomarker for cell types ranging from pluripotent stem cells to cancer cells. Using a microfluidic device, cell mechanotype can be rapidly analyzed by measuring the time required for cells to deform as they flow through constricted channels. While cells typically exhibit deformation timescales, or transit times, on the order of milliseconds to tens of seconds, transit times can span several orders of magnitude and vary from day to da… Show more

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Cited by 63 publications
(82 citation statements)
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“…The retention of each sample, in which the final mass is expressed as a percentage of the initial mass of loaded cell suspension, reflects the number of cells that occlude the membrane pores: a higher retention indicates a larger volume of cell suspension retained in the top well, which results from a larger number of occluded pores. The probability of pore occlusion depends on the external applied pressure, cell-to-pore size ratio and cell-surface interactions, as well as the mechanical properties of cells, such as their elastic and viscous moduli (Nyberg et al, 2016;Qi et al, 2015). At a constant applied pressure and pore size, cell deformability is a major contributor to the transit of cells through pores (Shaw Bagnall et al, 2015), and thus the retention that we measure (Qi et al, 2015).…”
Section: Results βAr Signaling Reduces the Deformability Of Cancer Cellsmentioning
confidence: 99%
“…The retention of each sample, in which the final mass is expressed as a percentage of the initial mass of loaded cell suspension, reflects the number of cells that occlude the membrane pores: a higher retention indicates a larger volume of cell suspension retained in the top well, which results from a larger number of occluded pores. The probability of pore occlusion depends on the external applied pressure, cell-to-pore size ratio and cell-surface interactions, as well as the mechanical properties of cells, such as their elastic and viscous moduli (Nyberg et al, 2016;Qi et al, 2015). At a constant applied pressure and pore size, cell deformability is a major contributor to the transit of cells through pores (Shaw Bagnall et al, 2015), and thus the retention that we measure (Qi et al, 2015).…”
Section: Results βAr Signaling Reduces the Deformability Of Cancer Cellsmentioning
confidence: 99%
“…Cell physical properties, including the shape, size and resistance of cells to an applied load, stem from other structural and molecular cell properties in a complex manner that is not easily discerned [1][2][3][4] . Compared to the conventional molecular biomarkers, these physical properties integrate many molecular changes.…”
Section: Introductionmentioning
confidence: 99%
“…Finally, we investigated cells relaxation time τ as a biomarker. It has been shown in literature [5] that 1/τ increases linearly with the cell velocity. Figure 3b represents the slopes α of 1/τ = f(V3) curves (see insert) for both populations flowing in the two geometries.…”
Section: The Potential Distinction Parametersmentioning
confidence: 99%
“…Various techniques have been reported in literature to evaluate RBC mechanical properties through the measurement of different parameters, i.e., the cortical tension [1], flowing speed through a network of constrictions [2], the time necessary to reach a steady state starting from rest [3], as well as their maximal deformability and their shape relaxation time (τ) [4]. Passive microfluidic techniques have emerged as powerful, label free, high throughput methods to assay those mechanical characteristics, using specific geometries [5]. In the present work, we used a passive microfluidic approach to differentiate mechanically impaired from healthy RBCs.…”
Section: Introductionmentioning
confidence: 99%