Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures

Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures

Hydrogels are increasingly used as a surrogate extracellular matrix in three-dimensional cell culture systems, including microfluidic cell culture. Matrigel is a hydrogel of natural origin widely used in cell culture, particularly in the culture of stem cell-derived cell lines. The use of Matrigel a...

Full description

Bibliographic Details
Main Authors: K. I. W. Kane, E. Lucumi Moreno, C. M. Lehr, S. Hachi, R. Dannert, R. Sanctuary, C. Wagner, R. M. T. Fleming, J. Baller
Format: Article
Language:English
Published: AIP Publishing LLC 2018-12-01
Series:AIP Advances
Online Access:http://dx.doi.org/10.1063/1.5067382
id doaj-a2b3cf3394664bf6b5217d3afc89ab1d
record_format Article
spelling doaj-a2b3cf3394664bf6b5217d3afc89ab1d2020-11-24T21:52:50ZengAIP Publishing LLCAIP Advances2158-32262018-12-01812125332125332-1110.1063/1.5067382096812ADVDetermination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell culturesK. I. W. Kane0E. Lucumi Moreno1C. M. Lehr2S. Hachi3R. Dannert4R. Sanctuary5C. Wagner6R. M. T. Fleming7J. Baller8Luxembourg Centre for Systems Biomedicine, University of Luxembourg, 7 avenue des Hauts-Fourneaux, L-4362 Esch-sur-Alzette, Grand-Duchy of LuxembourgLuxembourg Centre for Systems Biomedicine, University of Luxembourg, 7 avenue des Hauts-Fourneaux, L-4362 Esch-sur-Alzette, Grand-Duchy of LuxembourgPhysics and Materials Science Research Unit, Laboratory for the Physics of Advanced Materials, University of Luxembourg, 162A avenue de la Faïencerie, L-1511 Luxembourg, Grand-Duchy of LuxembourgLuxembourg Centre for Systems Biomedicine, University of Luxembourg, 7 avenue des Hauts-Fourneaux, L-4362 Esch-sur-Alzette, Grand-Duchy of LuxembourgPhysics and Materials Science Research Unit, Laboratory for the Physics of Advanced Materials, University of Luxembourg, 162A avenue de la Faïencerie, L-1511 Luxembourg, Grand-Duchy of LuxembourgPhysics and Materials Science Research Unit, Laboratory for the Physics of Advanced Materials, University of Luxembourg, 162A avenue de la Faïencerie, L-1511 Luxembourg, Grand-Duchy of LuxembourgPhysics and Materials Science Research Unit, Laboratory for the Physics of Advanced Materials, University of Luxembourg, 162A avenue de la Faïencerie, L-1511 Luxembourg, Grand-Duchy of LuxembourgLuxembourg Centre for Systems Biomedicine, University of Luxembourg, 7 avenue des Hauts-Fourneaux, L-4362 Esch-sur-Alzette, Grand-Duchy of LuxembourgPhysics and Materials Science Research Unit, Laboratory for the Physics of Advanced Materials, University of Luxembourg, 162A avenue de la Faïencerie, L-1511 Luxembourg, Grand-Duchy of LuxembourgHydrogels are increasingly used as a surrogate extracellular matrix in three-dimensional cell culture systems, including microfluidic cell culture. Matrigel is a hydrogel of natural origin widely used in cell culture, particularly in the culture of stem cell-derived cell lines. The use of Matrigel as a surrogate extracellular matrix in microfluidic systems is challenging due to its biochemical, biophysical, and biomechanical properties. Therefore, understanding and characterising these properties is a prerequisite for optimal use of Matrigel in microfluidic systems. We used rheological measurements and particle image velocimetry to characterise the fluid flow dynamics of liquefied Matrigel during loading into a three-dimensional microfluidic cell culture device. Using fluorescence microscopy and fluorescent beads for particle image velocimetry measurements (velocity profiles) in combination with classical rheological measurements of Matrigel (viscosity versus shear rate), we characterised the shear rates experienced by cells in a microfluidic device for three-dimensional cell culture. This study provides a better understanding of the mechanical stress experienced by cells, during seeding of a mixture of hydrogel and cells, into three-dimensional microfluidic cell culture devices.http://dx.doi.org/10.1063/1.5067382
collection DOAJ
language English
format Article
sources DOAJ
author K. I. W. Kane
E. Lucumi Moreno
C. M. Lehr
S. Hachi
R. Dannert
R. Sanctuary
C. Wagner
R. M. T. Fleming
J. Baller
spellingShingle K. I. W. Kane
E. Lucumi Moreno
C. M. Lehr
S. Hachi
R. Dannert
R. Sanctuary
C. Wagner
R. M. T. Fleming
J. Baller
Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
AIP Advances
author_facet K. I. W. Kane
E. Lucumi Moreno
C. M. Lehr
S. Hachi
R. Dannert
R. Sanctuary
C. Wagner
R. M. T. Fleming
J. Baller
author_sort K. I. W. Kane
title Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
title_short Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
title_full Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
title_fullStr Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
title_full_unstemmed Determination of the rheological properties of Matrigel for optimum seeding conditions in microfluidic cell cultures
title_sort determination of the rheological properties of matrigel for optimum seeding conditions in microfluidic cell cultures
publisher AIP Publishing LLC
series AIP Advances
issn 2158-3226
publishDate 2018-12-01
description Hydrogels are increasingly used as a surrogate extracellular matrix in three-dimensional cell culture systems, including microfluidic cell culture. Matrigel is a hydrogel of natural origin widely used in cell culture, particularly in the culture of stem cell-derived cell lines. The use of Matrigel as a surrogate extracellular matrix in microfluidic systems is challenging due to its biochemical, biophysical, and biomechanical properties. Therefore, understanding and characterising these properties is a prerequisite for optimal use of Matrigel in microfluidic systems. We used rheological measurements and particle image velocimetry to characterise the fluid flow dynamics of liquefied Matrigel during loading into a three-dimensional microfluidic cell culture device. Using fluorescence microscopy and fluorescent beads for particle image velocimetry measurements (velocity profiles) in combination with classical rheological measurements of Matrigel (viscosity versus shear rate), we characterised the shear rates experienced by cells in a microfluidic device for three-dimensional cell culture. This study provides a better understanding of the mechanical stress experienced by cells, during seeding of a mixture of hydrogel and cells, into three-dimensional microfluidic cell culture devices.
url http://dx.doi.org/10.1063/1.5067382
work_keys_str_mv AT kiwkane determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT elucumimoreno determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT cmlehr determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT shachi determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT rdannert determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT rsanctuary determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT cwagner determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT rmtfleming determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
AT jballer determinationoftherheologicalpropertiesofmatrigelforoptimumseedingconditionsinmicrofluidiccellcultures
_version_ 1725874598495387648

Similar Items