The physical origins of transit time measurements for rapid, single cell mechanotyping. Issue 17 (20th July 2016)
- Record Type:
- Journal Article
- Title:
- The physical origins of transit time measurements for rapid, single cell mechanotyping. Issue 17 (20th July 2016)
- Main Title:
- The physical origins of transit time measurements for rapid, single cell mechanotyping
- Authors:
- Nyberg, Kendra D.
Scott, Michael B.
Bruce, Samuel L.
Gopinath, Ajay B.
Bikos, Dimitri
Mason, Thomas G.
Kim, Jin Woong
Choi, Hong Sung
Rowat, Amy C. - Abstract:
- Abstract : Major physical contributors to cell transit times through microfluidic constrictions are identified with the goal of facilitating more precise 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 day within a population of single cells; this makes it challenging to characterize different cell samples based on transit time data. Here we investigate how variability in transit time measurements depends on both experimental factors and heterogeneity in physical properties across a population of single cells. We find that simultaneous transit events that occur across neighboring constrictions can alter transit time, but only significantly when more than 65% of channels in the parallel array are occluded. Variability in transit time measurements is also affected by the age of the device following plasma treatment, which could be attributed to changes in channel surface properties. We additionally investigate the role of variability in cell physical properties. Transit time depends on cellAbstract : Major physical contributors to cell transit times through microfluidic constrictions are identified with the goal of facilitating more precise 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 day within a population of single cells; this makes it challenging to characterize different cell samples based on transit time data. Here we investigate how variability in transit time measurements depends on both experimental factors and heterogeneity in physical properties across a population of single cells. We find that simultaneous transit events that occur across neighboring constrictions can alter transit time, but only significantly when more than 65% of channels in the parallel array are occluded. Variability in transit time measurements is also affected by the age of the device following plasma treatment, which could be attributed to changes in channel surface properties. We additionally investigate the role of variability in cell physical properties. Transit time depends on cell size; by binning transit time data for cells of similar diameters, we reduce measurement variability by 20%. To gain further insight into the effects of cell-to-cell differences in physical properties, we fabricate a panel of gel particles and oil droplets with tunable mechanical properties. We demonstrate that particles with homogeneous composition exhibit a marked reduction in transit time variability, suggesting that the width of transit time distributions reflects the degree of heterogeneity in subcellular structure and mechanical properties within a cell population. Our results also provide fundamental insight into the physical underpinnings of transit measurements: transit time depends strongly on particle elastic modulus, and weakly on viscosity and surface tension. Based on our findings, we present a comprehensive methodology for designing, analyzing, and reducing variability in transit time measurements; this should facilitate broader implementation of transit experiments for rapid mechanical phenotyping in basic research and clinical settings. … (more)
- Is Part Of:
- Lab on a chip. Volume 16:Issue 17(2016)
- Journal:
- Lab on a chip
- Issue:
- Volume 16:Issue 17(2016)
- Issue Display:
- Volume 16, Issue 17 (2016)
- Year:
- 2016
- Volume:
- 16
- Issue:
- 17
- Issue Sort Value:
- 2016-0016-0017-0000
- Page Start:
- 3330
- Page End:
- 3339
- Publication Date:
- 2016-07-20
- Subjects:
- Miniature electronic equipment -- Periodicals
Combinatorial chemistry -- Periodicals
Biotechnology -- Periodicals
543.0813 - Journal URLs:
- http://pubs.rsc.org/en/journals/journalissues/lc#!recentarticles&adv ↗
http://www.rsc.org/ ↗ - DOI:
- 10.1039/c6lc00169f ↗
- Languages:
- English
- ISSNs:
- 1473-0197
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 5137.730000
British Library DSC - BLDSS-3PM
British Library STI - ELD Digital store - Ingest File:
- 2551.xml