Investigation of Large Strain Deformation Behavior of Soft Gels in Shear- And Cavitation Rheology

Hashemnejad, Seyedmeysam

11 August 2017

Gels and hydrogels have attracted a great attention for potential applications in tissue engineering, drug delivery, actuators, and soft robots. There has been a significant progress to engineer hydrogels from both synthetic and natural precursors to be as tough as a solid and as stretchable as a rubbery material while maintaining high water/solvent content. Despite considerable advances in rationally designing hydrogels, our understanding of their complex nonlinear mechanical deformation behavior is incomplete. This is partially due to the difficulty in conducting mechanical characterization on slippery, soft and swollen gels. Thus, it is required to develop new experimental techniques in order to better characterize them. Further, analyzing the experimental observations and link it with the molecular networks is an important factor. With this perspective, in this dissertation, nonlinear mechanical properties of different gel like materials have been investigated. We chose different gels with varied molecular structure, from molecular gel to self-assembled copolymer gels with flexible chains, to semiflexible polysaccharide based polymers. By developing suitable experimental protocols, strain-stiffening behavior of these materials, similar to that observed in biological materials, have been captured. Chain flexibility is a dominant factor in mechanical behavior of gels. For example, gels with flexible chains dilate orthogonal to an external shear load, whereas gels with semilexible chains contract similar to biological gel-like materials. In order to investigate the failure mechanism in our gels, cavitation rheology technique was also applied. We found that cavitation phenomenon in gels is related to the molecular architecture of the gels. The present work provides a better understanding of the deformation behavior of soft gels when subjected to a large load.

Alginate

Molecular gel

Strain Stiffening

Cavitation

Rheology

Gel

Polymer

Cell sensing on strain-stiffening substrates is not fully explained by the nonlinear mechanical property

Rudnicki, Mathilda Sophia

17 April 2012

Cells respond to their mechanical environment by changing shape and size, migrating, or even differentiating to a more specialized cell type. A better understanding of the response of cells to surrounding cues will allow for more targeted and effected designs for biomedical applications, such as disease treatment or cellular therapy. The spreading behavior of both human mesenchymal stem cells (hMSCs) and 3T3 fibroblasts is a function of substrate stiffness, and can be quantified to describe the most visible response to how a cell senses stiffness. The stiffness of the substrate material can be modulated by altering the substrate thickness, and this has been done with the commonly-used linearly elastic gel, polyacrylamide (PA). Though easy to produce and tune, PA gel does not exhibit strain-stiffening behavior, and thus is not as representative of biological tissue as fibrin or collagen gel. Fibroblasts on soft fibrin gel show spreading similar to much stiffer linear gels, indicating a difference in cell stiffness sensing on these two materials. We hypothesize cells can sense further into fibrin and collagen gels than linear materials due to the strain-stiffening material property. The goal of this work is to compare the material response of linear (PA) and strain-stiffening (fibrin, collagen gel) substrates through modulation of effective stiffness of the materials. The two-step approach is to first develop a finite element model to numerically simulate a cell contracting on substrates of different thicknesses, and then to validate the numerical model by quantifying fibroblast spreading on sloped fibrin and collagen gels. The finite element model shows that the effective stiffness of both linear and nonlinear materials sharply increases once the thickness is reduced below 10µm. Due to the strain-stiffening behavior, the nonlinear material experiences a more drastic increase in effective stiffness at these low thicknesses. Experimentally, the gradual response of cell area of HLF and 3T3 fibroblasts on fibrin and collagen gels is significantly different (p<0.05) from these cell types on PA gel. This gradual increase in area as substrate thickness decreases was not predicted by the finite element model. Therefore, cell spreading response to stiffness is not explained by just the nonlinearity of the material.

mechanosensing

effective stiffness

fibroblasts

strain-stiffening

extracellular matrix

linear

nonlinear

cell spreading

The Mechanics of Fibrin Networks and Their Alterations by Platelets

Jawerth, Louise Marie

04 September 2013

Fibrin is a biopolymer that assembles into a network during blood coagulation to become the structural scaffold of a blood clot. The precise mechanics of this network are crucial for a blood clot to properly stem the flow of blood at the site of vascular injury while still remaining pliable enough to avoid dislocation. A hallmark of fibrin's mechanical response is strain-stiffening: at small strains, its response is low and linear; while at high strains, its stiffness increases non-linearly with increasing strain. The physical origins of strain-stiffening have been studied for other biopolymer systems but have remained elusive for biopolymer networks composed of stiff filaments, such as fibrin. To understand the origins of this intriguing behavior, we directly observe and quantify the motion of all of the fibers in the fibrin networks as they undergo shear in 3D using confocal microscopy. We show that the strain-stiffening response of a clot is a result of the full network deformation rather than an intrinsic strain-stiffening response of the individual fibers. We observe a distinct transition from a linear, low-strain regime, where all fibers avoid any internal stretching, to a non-linear, high-strain regime, where an increasing number of fibers become stretched. This transition is characterized by a high degree of non-affine motion. Moreover, we are able to precisely calculate the non-linear stress-strain response of the network by using the strains on each fiber measured directly with confocal microscopy and by assuming the fibers behave like linearly elastic beams. This result confirms that it is the network deformation that causes the strain-stiffening behavior of fibrin clots. These data are consistent with predictions for low-connectivity networks with soft, bending, or floppy modes. Moreover, we show that the addition of small contractile cells, platelets, increases the low-strain stiffness of the network while the high-strain stiffness is independent of the presence of the platelets; this is also consistent with expectations for small contractile elements in a network with low connectivity. Our results elucidate the origins of strain-stiffening in fibrin networks as well as the mechanism underlying platelet-induced clot stiffening. / Physics

Physics

Biophysics

confocal microscopy

floppy modes

low-connectivity network

rheology

stiff biopolymer

strain stiffening

From Strain Stiffening to Softening—Rheological Characterization of Keratins 8 and 18 Networks Crosslinked via Electron Irradiation

Elbalasy, Iman, Wilharm, Nils, Herchenhahn, Erik, Konieczny, Robert, Mayr, Stefan G., Schnauß, Jörg

02 June 2023

Networks of crosslinked keratin filaments are abundant in epithelial cells and tissues, providing resilience against mechanical forces and ensuring cellular integrity. Although studies of in vitro models of reconstituted keratin networks have revealed important mechanical aspects, the mechanical properties of crosslinked keratin structures remain poorly understood. Here, we exploited the power of electron beam irradiation (EBI) to crosslink in vitro networks of soft epithelial keratins 8 and 18 (k8–k18) filaments with different irradiation doses (30 kGy, 50 kGy, 80 kGy, 100 kGy, and 150 kGy). We combined bulk shear rheology with confocal microscopy to investigate the impact of crosslinking on the mechanical and structural properties of the resultant keratin gels. We found that irradiated keratin gels display higher linear elastic modulus than the unirradiated, entangled networks at all doses tested. However, at the high doses (80 kGy, 100 kGy, and 150 kGy), we observed a remarkable drop in the elastic modulus compared to 50 kGy. Intriguingly, the irradiation drastically changed the behavior for large, nonlinear deformations. While untreated keratin networks displayed a strong strain stiffening, increasing irradiation doses shifted the system to a strain softening behavior. In agreement with the rheological behavior in the linear regime, the confocal microscopy images revealed fully isotropic networks with high percolation in 30 kGy and 50 kGy-treated keratin samples, while irradiation with 100 kGy induced the formation of thick bundles and clusters. Our results demonstrate the impact of permanent crosslinking on k8–k18 mechanics and provide new insights into the potential contribution of intracellular covalent crosslinking to the loss of mechanical resilience in some human keratin diseases. These insights will also provide inspiration for the synthesis of new keratin-based biomaterials.

info:eu-repo/classification/ddc/540

ddc:540