Long-range ordered vorticity patterns in living tissue induced by cell division

Ninna Struck Rossen; Jens Magelund Tarp; Joachim Mathiesen; Mogens Høgh Jensen; Lene Broeng Oddershede

doi:10.1038/ncomms6720

Long-range ordered vorticity patterns in living tissue induced by cell division

Ninna Struck Rossen, Jens Magelund Tarp, Joachim Mathiesen, Mogens Høgh Jensen, Lene Broeng Oddershede

Biocomplexity

32 Citations (Scopus)

Abstract

In healthy blood vessels with a laminar blood flow, the endothelial cell division rate is low, only sufficient to replace apoptotic cells. The division rate significantly increases during embryonic development and under halted or turbulent flow. Cells in barrier tissue are connected and their motility is highly correlated. Here we investigate the long-range dynamics induced by cell division in an endothelial monolayer under non-flow conditions, mimicking the conditions during vessel formation or around blood clots. Cell divisions induce long-range, well-ordered vortex patterns extending several cell diameters away from the division site, in spite of the system's low Reynolds number. Our experimental results are reproduced by a hydrodynamic continuum model simulating division as a local pressure increase corresponding to a local tension decrease. Such long-range physical communication may be crucial for embryonic development and for healing tissue, for instance around blood clots.

Original language	English
Article number	5720
Journal	Nature Communications
Volume	5
ISSN	2041-1723
DOIs	https://doi.org/10.1038/ncomms6720
Publication status	Published - 8 Dec 2014

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title = "Long-range ordered vorticity patterns in living tissue induced by cell division",

abstract = "In healthy blood vessels with a laminar blood flow, the endothelial cell division rate is low, only sufficient to replace apoptotic cells. The division rate significantly increases during embryonic development and under halted or turbulent flow. Cells in barrier tissue are connected and their motility is highly correlated. Here we investigate the long-range dynamics induced by cell division in an endothelial monolayer under non-flow conditions, mimicking the conditions during vessel formation or around blood clots. Cell divisions induce long-range, well-ordered vortex patterns extending several cell diameters away from the division site, in spite of the system's low Reynolds number. Our experimental results are reproduced by a hydrodynamic continuum model simulating division as a local pressure increase corresponding to a local tension decrease. Such long-range physical communication may be crucial for embryonic development and for healing tissue, for instance around blood clots.",

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T1 - Long-range ordered vorticity patterns in living tissue induced by cell division

AU - Rossen, Ninna Struck

AU - Tarp, Jens Magelund

AU - Mathiesen, Joachim

AU - Jensen, Mogens Høgh

AU - Oddershede, Lene Broeng

PY - 2014/12/8

Y1 - 2014/12/8

N2 - In healthy blood vessels with a laminar blood flow, the endothelial cell division rate is low, only sufficient to replace apoptotic cells. The division rate significantly increases during embryonic development and under halted or turbulent flow. Cells in barrier tissue are connected and their motility is highly correlated. Here we investigate the long-range dynamics induced by cell division in an endothelial monolayer under non-flow conditions, mimicking the conditions during vessel formation or around blood clots. Cell divisions induce long-range, well-ordered vortex patterns extending several cell diameters away from the division site, in spite of the system's low Reynolds number. Our experimental results are reproduced by a hydrodynamic continuum model simulating division as a local pressure increase corresponding to a local tension decrease. Such long-range physical communication may be crucial for embryonic development and for healing tissue, for instance around blood clots.

AB - In healthy blood vessels with a laminar blood flow, the endothelial cell division rate is low, only sufficient to replace apoptotic cells. The division rate significantly increases during embryonic development and under halted or turbulent flow. Cells in barrier tissue are connected and their motility is highly correlated. Here we investigate the long-range dynamics induced by cell division in an endothelial monolayer under non-flow conditions, mimicking the conditions during vessel formation or around blood clots. Cell divisions induce long-range, well-ordered vortex patterns extending several cell diameters away from the division site, in spite of the system's low Reynolds number. Our experimental results are reproduced by a hydrodynamic continuum model simulating division as a local pressure increase corresponding to a local tension decrease. Such long-range physical communication may be crucial for embryonic development and for healing tissue, for instance around blood clots.

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DO - 10.1038/ncomms6720

M3 - Journal article

C2 - 25483750

SN - 2041-1723

VL - 5

JO - Nature Communications

JF - Nature Communications

M1 - 5720

ER -

Long-range ordered vorticity patterns in living tissue induced by cell division

Abstract

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