Spelling suggestions: "subject:"well stretching"" "subject:"cell stretching""
1 |
Stress in a Microgravity BioreactorKramarenko, George, 0000-0002-6990-5620 January 2021 (has links)
This project involves the design and development of a cell stretching bioreactor device that can work in conjunction with a Random Positioning Machine (RPM) apparatus. Microgravity environments, such as in space, have been shown to induce alterations in cellular development due to inadequate mechanical loading of biological tissue. Because of this, long-term spaceflight has led to many health concerns, including osteoporosis and muscle atrophy. Space travel is rare and costly, making this research difficult to conduct, however; techniques to simulate microgravity on Earth can be achieved by using a Random Positioning Machine. This device has been a beneficial tool used to study the effect gravity has on cellular growth, yet certain tissues in the body, such as bone and muscle, require mechanical stress, strain, and mechanical loading to develop properly. Because of this, a device that can induce strain on cells while subjected to microgravity conditions is needed to further improve cellular research for space exploration. The constructed bioreactor consists of 3D printed and custom-made components that can induce uniaxial cyclic strain on cells adhered to an elastic membrane. Validation and testing of the device have shown that this bioreactor is suitable for cellular experimentation to work in conjunction with an RPM to deliver a controlled amount of strain while under microgravity conditions. / Bioengineering
|
2 |
Effect of PAK Inhibition on Cell Mechanics Depends on Rac1Mierke, Claudia Tanja, Puder, Stefanie, Aermes, Christian, Fischer, Tony, Kunschmann, Tom 03 April 2023 (has links)
Besides biochemical and molecular regulation, the migration and invasion of cells
is controlled by the environmental mechanics and cellular mechanics. Hence, the
mechanical phenotype of cells, such as fibroblasts, seems to be crucial for the
migratory capacity in confined 3D extracellular matrices. Recently, we have shown
that the migratory and invasive capacity of mouse embryonic fibroblasts depends on
the expression of the Rho-GTPase Rac1, similarly it has been demonstrated that the
Rho-GTPase Cdc42 affects cell motility. The p21-activated kinase (PAK) is an effector
down-stream target of both Rho-GTPases Rac1 and Cdc42, and it can activate via the
LIM kinase-1 its down-stream target cofilin and subsequently support the cell migration
and invasion through the polymerization of actin filaments. Since Rac1 deficient cells
become mechanically softer than controls, we investigated the effect of group I PAKs
and PAK1 inhibition on cell mechanics in the presence and absence of Rac1. Therefore,
we determined whether mouse embryonic fibroblasts, in which Rac1 was knockedout,
and control cells, displayed cell mechanical alterations after treatment with group I
PAKs or PAK1 inhibitors using a magnetic tweezer (adhesive cell state) and an optical
cell stretcher (non-adhesive cell state). In fact, we found that group I PAKs and Pak1
inhibition decreased the stiffness and the Young’s modulus of fibroblasts in the presence
of Rac1 independent of their adhesive state. However, in the absence of Rac1 the
effect was abolished in the adhesive cell state for both inhibitors and in their nonadhesive
state, the effect was abolished for the FRAX597 inhibitor, but not for the IPA3
inhibitor. The migration and invasion were additionally reduced by both PAK inhibitors
in the presence of Rac1. In the absence of Rac1, only FRAX597 inhibitor reduced their
invasiveness, whereas IPA3 had no effect. These findings indicate that group I PAKs
and PAK1 inhibition is solely possible in the presence of Rac1 highlighting Rac1/PAK I
(PAK1, 2, and 3) as major players in cell mechanics.
|
3 |
The Development and Application of Tools to Study the Multiscale Biomechanics of the Aortic ValveZhao, Ruogang 06 December 2012 (has links)
Calcific aortic valve disease (CAVD) is one of the most common causes of cardiovascular disease in North America. Mechanical factors have been closely linked to the pathogenesis of CAVD and may contribute to the disease by actively regulating the mechanobiology of valve interstitial cells (VICs). Mechanical forces affect VIC function through interactions between the VIC and the extracellular matrix (ECM). Studies have shown that the transfer of mechanical stimulus during cell-ECM interaction depends on the local material properties at hierarchical length scales encompassing tissue, cell and cytoskeleton.
In this thesis, biomechanical tools were developed and applied to investigate hierarchical cell-ECM interactions, using VICs and valve tissue as a model system. Four topics of critical importance to understanding VIC-ECM interactions were studied: focal biomechanical material properties of aortic valve tissue; viscoelastic properties of VICs; transduction of mechanical deformation from the ECM to the cytoskeletal network; and the impact of altered cell-ECM interactions on VIC survival.
To measure focal valve tissue properties, a micropipette aspiration (MA) method was implemented and validated. It was found that nonlinear elastic properties of the top layer of a multilayered biomaterial can be estimated by MA by using a pipette with a diameter smaller than the top layer thickness. Using this approach, it was shown that the effective stiffness of the fibrosa layer is greater than that of the ventricularis layer in intact aortic valve leaflets (p<0.01). To characterize the viscoelastic properties of VICs, an inverse FE method of single cell MA was developed and compared with the analytical half-space model. It was found that inherent differences in the half-space and FE models of single cell MA yield different cell viscoelastic material parameters. However, under particular experimental conditions, the parameters estimated by the half-space model are statistically indistinguishable from those predicted by the FE model. To study strain transduction from the ECM to cytoskeleton, an improved texture correlation algorithm and a uniaxial tension release device were developed. It was found that substrate strain fully transfers to the cytoskeletal network via focal adhesions in live VICs under large strain tension release. To study the effects of cell-ECM interactions on VIC survival, two mechanical stimulus systems that can simulate the separate effects of cell contraction and cell monolayer detachment were developed. It was found that cell sheet detachment and disrupted cell-ECM signaling is likely responsible for the apoptosis of VICs grown in culture on thin collagen matrices, leading to calcification.
The studies presented in this thesis refine existing biomechanical tools and provide new experimental and analytical tools with which to study cell-ECM interactions. Their application resulted in an improved understanding of hierarchical valve biomechanics, mechanotransduction, and mechanobiology.
|
4 |
The Development and Application of Tools to Study the Multiscale Biomechanics of the Aortic ValveZhao, Ruogang 06 December 2012 (has links)
Calcific aortic valve disease (CAVD) is one of the most common causes of cardiovascular disease in North America. Mechanical factors have been closely linked to the pathogenesis of CAVD and may contribute to the disease by actively regulating the mechanobiology of valve interstitial cells (VICs). Mechanical forces affect VIC function through interactions between the VIC and the extracellular matrix (ECM). Studies have shown that the transfer of mechanical stimulus during cell-ECM interaction depends on the local material properties at hierarchical length scales encompassing tissue, cell and cytoskeleton.
In this thesis, biomechanical tools were developed and applied to investigate hierarchical cell-ECM interactions, using VICs and valve tissue as a model system. Four topics of critical importance to understanding VIC-ECM interactions were studied: focal biomechanical material properties of aortic valve tissue; viscoelastic properties of VICs; transduction of mechanical deformation from the ECM to the cytoskeletal network; and the impact of altered cell-ECM interactions on VIC survival.
To measure focal valve tissue properties, a micropipette aspiration (MA) method was implemented and validated. It was found that nonlinear elastic properties of the top layer of a multilayered biomaterial can be estimated by MA by using a pipette with a diameter smaller than the top layer thickness. Using this approach, it was shown that the effective stiffness of the fibrosa layer is greater than that of the ventricularis layer in intact aortic valve leaflets (p<0.01). To characterize the viscoelastic properties of VICs, an inverse FE method of single cell MA was developed and compared with the analytical half-space model. It was found that inherent differences in the half-space and FE models of single cell MA yield different cell viscoelastic material parameters. However, under particular experimental conditions, the parameters estimated by the half-space model are statistically indistinguishable from those predicted by the FE model. To study strain transduction from the ECM to cytoskeleton, an improved texture correlation algorithm and a uniaxial tension release device were developed. It was found that substrate strain fully transfers to the cytoskeletal network via focal adhesions in live VICs under large strain tension release. To study the effects of cell-ECM interactions on VIC survival, two mechanical stimulus systems that can simulate the separate effects of cell contraction and cell monolayer detachment were developed. It was found that cell sheet detachment and disrupted cell-ECM signaling is likely responsible for the apoptosis of VICs grown in culture on thin collagen matrices, leading to calcification.
The studies presented in this thesis refine existing biomechanical tools and provide new experimental and analytical tools with which to study cell-ECM interactions. Their application resulted in an improved understanding of hierarchical valve biomechanics, mechanotransduction, and mechanobiology.
|
Page generated in 0.0719 seconds