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

Kane, K. I. W.; Moreno, Edinson Lucumi; Lehr, Claudius Moritz; Hachi, Siham; Dannert, Rick; Sanctuary, Roland; Wagner, Christian; Fleming, Ronan M. T.; Baller, Jörg

doi:10.1063/1.5067382

Cited by 29 publications

(21 citation statements)

References 20 publications

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“…Considering the effect of temperature on Matrigel ® crosslinking, the first step was the investigation of the effects of the thermal history the material undergoes before bioprinting. By increasing temperature from 2 to 37 °C at 5 °C/min, we identified the gelation point, as point of crossover between the conservative (G’) and dissipative (G”) components of the complex shear modulus around 6 °C, which is in line with the work of Kane et al [ 25 ]. Below this value, Matrigel ® is in liquid-state, while above it, it starts exhibiting a solid-like behaviour.…”

Section: Resultssupporting

confidence: 88%

Bioprinting of Matrigel Scaffolds for Cancer Research

et al. 2021

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Cancer is one of the most life-threatening diseases worldwide. Despite the huge efforts, the failure rate of therapies remains high due to cells heterogeneity, so physiologically relevant models are strictly necessary. Bioprinting is a technology able to form highly complex 3D tissue models and enables the creation of large-scale constructs. In cancer research, Matrigel® is the most widely used matrix, but it is hardly bioprinted pure, without the use of any other bioink as reinforcement. Its complex rheological behavior makes the control with a standard bioprinting process nearly impossible. In this work, we present a customized bioprinting strategy to produce pure Matrigel® scaffolds with good shape fidelity. To this aim, we realized a custom-made volumetric dispensing system and performed printability evaluations. To determine optimal printing parameters, we analyzed fibers spreading ratio on simple serpentines. After identifying an optimal flow rate of 86.68 ± 5.77 µL/min and a printing speed of 10 mm/min, we moved forward to evaluate printing accuracy, structural integrity and other key parameters on single and multi-layer grids. Results demonstrated that Matrigel® was able to maintain its structure in both simple and complex designs, as well as in single and multilayer structures, even if it does not possess high mechanical strength. In conclusion, the use of volumetric dispensing allowed printing pure Matrigel® constructs with a certain degree of shape fidelity on both single and multiple layers.

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Section: Resultssupporting

confidence: 88%

Bioprinting of Matrigel Scaffolds for Cancer Research

et al. 2021

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“…Various hydrogel matrices have been used as a substrate for cell migration. The rheological behavior of hydrogels frequently corresponds to a poroviscoelasticity [35]. The matrix stress relaxation phenomena caused by cell tractions include (1) the hydrogel viscoelastic relaxation and (2) poroelastic relaxation caused by solvent diffusion.…”

Section: Viscoelasticity Of An Extracellular Matrixmentioning

confidence: 99%

“…Polyacrylamide gel coated by collagen has been a widely used matrix for 2D cellular systems [1][2][3]. Hydrogels of natural origins are basement membrane-based gel preparations; some examples include fibrin gel, collagen gel, alginate gel, chitosan gel, and Matrigel [15,30,35,36]. Matrigel is a commercially available basement membrane based gel.…”

Section: Viscoelasticity Of An Extracellular Matrixmentioning

confidence: 99%

Mechanical Oscillations in 2D Collective Cell Migration: The Elastic Turbulence

Pajić‐Lijaković

Milivojević

2020

Front. Phys.

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Various types of mechanical waves, such as propagative waves and standing waves, are observed during 2D collective cell migration. Propagative waves are generated during monolayer free expansion, whereas standing waves are generated during swirling motion of a confluent monolayer. Significant attempts have been made to describe the main characteristics of mechanical waves obtained within various experimental systems. However, much less attention is paid to correlate the viscoelasticity with the generated oscillatory instabilities. Mechanical waves have recognized during flow of various viscoelastic systems under low Reynolds number and called "the elastic turbulence." In addition to Reynolds number, Weissenberg number is needed for characterizing the elastic turbulence. The viscoelastic resistive force generated during collective cell migration caused by a residual stress accumulation is capable of inducing apparent inertial effects by balancing with other forces such as the surface tension force, the traction force, and the resultant force responsible for cell migration. The resultant force represents a product of various biochemical processes such as cell signaling and gene expression. The force balance induces (1) forward flow and backward flow in the direction of cell migration as characteristics of the propagative waves and (2) inflow and outflow perpendicular to the direction of migration as characteristics of the standing waves. The apparent inertial effects are essential for appearing the elastic turbulence and represent the characteristic of (1) the backward flow during the monolayer free expansion and (2) the inflow during the cell swirling motion within a confluent monolayer.

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“…The 12-well culture plate is prepared before transfection. Aliquots of Matrigel® (250 µl) and DMEM (200 µl) are brought to -4°C [22,23]. The -4°C is an optimal temperature for the miscibility of the Matrigel and DMEM.…”

Section: Transfection and Analysis Of Mrna Containing Hek 293 Cellsmentioning

confidence: 99%

“…The Matrigel forms the basement membrane needed to support the mammalian (culture) cells. It serves as a surrogate extracellular matrix, which forms the micro-environment for growing and studying the culture cells [22,23].…”

Section: Matrigelmentioning

confidence: 99%

Generation of mRNA Vaccine: An Analysis of Two Types of Vectors

Ohanube¹,

Uchejeso²

2021

Int j pharm phytopharm res

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In this research, the messenger ribonucleic acid vaccine has proven to be the best vaccine among all others against the Coronavirus disease of 2019, such that the Food and Drug Administration recently gave it full approval. This approval is made possible due to its clinical efficacy, the rare occasion of insertional mutagenesis associated with it, and the absence of anti-vector immunity. Also, its rapid production process gives it an added advantage over conventional DNA vaccines. A literature review was carried out based on available literature online. This review elaborates on the steps involved in the in vitro generation of the messenger ribonucleic acid vaccine. An example is made using a plasmid that contains both the receptor-binding domain found in the spike protein of the Coronavirus and the super folder green fluorescent protein. The use of a viral vector in making these vaccines is also added as a note for additional knowledge.

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

Cited by 29 publications

References 20 publications

Bioprinting of Matrigel Scaffolds for Cancer Research

Bioprinting of Matrigel Scaffolds for Cancer Research

Mechanical Oscillations in 2D Collective Cell Migration: The Elastic Turbulence

Generation of mRNA Vaccine: An Analysis of Two Types of Vectors

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