Issue 18, 2022

Hydrodynamic dissection of Stentor coeruleus in a microfluidic cross junction

Abstract

Stentor coeruleus, a single-cell ciliated protozoan, is a model organism for wound healing and regeneration studies. Despite Stentor's large size (up to 2 mm in extended state), microdissection of Stentor remains challenging. In this work, we describe a hydrodynamic cell splitter, consisting of a microfluidic cross junction, capable of splitting Stentor cells in a non-contact manner at a high throughput of ∼500 cells per minute under continuous operation. Introduction of asymmetry in the flow field at the cross junction leads to asymmetric splitting of the cells to generate cell fragments as small as ∼8.5 times the original cell size. Characterization of cell fragment viability shows reduced 5-day survival as fragment size decreases and as the extent of hydrodynamic stress imposed on the fragments increases. Our results suggest that cell fragment size and composition, as well as mechanical stress, play important roles in the long-term repair of Stentor cells and warrant further investigations. Nevertheless, the hydrodynamic splitter can be useful for studying phenomena immediately after cell splitting, such as the closure of wounds in the plasma membrane which occurs on the order of 100–1000 seconds in Stentor.

Graphical abstract: Hydrodynamic dissection of Stentor coeruleus in a microfluidic cross junction

Supplementary files

Article information

Article type
Paper
Submitted
10 Jun 2022
Accepted
05 Aug 2022
First published
08 Aug 2022

Lab Chip, 2022,22, 3508-3520

Author version available

Hydrodynamic dissection of Stentor coeruleus in a microfluidic cross junction

R. Paul, K. S. Zhang, M. Kurosu Jalil, N. Castaño, S. Kim and S. K. Y. Tang, Lab Chip, 2022, 22, 3508 DOI: 10.1039/D2LC00527A

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