Cells in 3D matrices under interstitial flow: Effects of extracellular matrix alignment on cell shear stress and drag forces

Pedersen, John A.; Lichter, Seth; Swartz, Melody A.

doi:10.1016/j.jbiomech.2009.11.007

Cited by 85 publications

(75 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Flow-induced stresses on a cell are a function of flow rate and, in contrast to an autocrine or paracrine signaling stimulus, independent of cell density. Shear stress has long been known to play a role in EC migration (3,(33)(34)(35)(36); however, in our system, cells are suspended in a 3D matrix, and the presence of this porous medium causes the force due to fluid pressure gradient across the cell to dominate the fluid shear force (37). By modeling a cell as a sphere embedded in a porous medium, we found the force due to the pressure drop across the cell (F pm ) relative to the shear stress imparted by the fluid (F s ) scales as…”

Section: Discussionmentioning

confidence: 99%

“…Pressure forces from flow past a cell in a 3D matrix lead to a transcellular stress gradient (37), and this stress results in asymmetric force in cell-matrix interactions-e.g., tensile force on the upstream side and compressive force on the downstream side. Previous work demonstrates that FAK colocalizes with activated integrins and activates Src kinase (28,29), which modulates traction forces important for tumor cell migration (43,44).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Interstitial flow influences direction of tumor cell migration through competing mechanisms

Polacheck¹,

Charest

Kamm

2011

Proc. Natl. Acad. Sci. U.S.A.

424

434

View full text Add to dashboard Cite

Interstitial flow is the convective transport of fluid through tissue extracellular matrix. This creeping fluid flow has been shown to affect the morphology and migration of cells such as fibroblasts, cancer cells, endothelial cells, and mesenchymal stem cells. A microfluidic cell culture system was designed to apply stable pressure gradients and fluid flow and allow direct visualization of transient responses of cells seeded in a 3D collagen type I scaffold. We used this system to examine the effects of interstitial flow on cancer cell morphology and migration and to extend previous studies showing that interstitial flow increases the metastatic potential of MDA-MB-435S melanoma cells [Shields J, et al. (2007) Cancer Cell 11:526-538]. Using a breast carcinoma line (MDA-MB-231) we also observed cell migration along streamlines in the presence of flow; however, we further demonstrated that the strength of the flow as well as the cell density determined directional bias of migration along the streamline. In particular, we found that cells either at high seeding density or with the CCR-7 receptor inhibited migration against, rather than with the flow. We provide further evidence that CCR7-dependent autologous chemotaxis is the mechanism that leads to migration with the flow, but also demonstrate a competing CCR7-independent mechanism that causes migration against the flow. Data from experiments investigating the effects of cell concentration, interstitial flow rate, receptor activity, and focal adhesion kinase phosphorylation support our hypothesis that the competing stimulus is integrin mediated. This mechanism may play an important role in development of metastatic disease. mechanobiology | computational model | signaling | cell mechanics T issues are composed of cells residing in an extracellular matrix (ECM) containing interstitial fluid that transports nutrients and signaling molecules (1, 2). Osmotic and hydrostatic pressure gradients across tissues resulting from physiologic processes such as drainage toward lymphatics, inflammation, locally elevated pressures due to tumor growth or leaky microvessels, and muscle contraction each drive fluid flow through the ECM (2, 3). This fluid flow is termed interstitial flow and has long been recognized to be instrumental in tissue transport and physiology (1, 4, 5). Chary and Jain used fluorescence recovery after photobleaching to directly observe fluid flow in the tissue interstitium and determined typical flow velocities to be on the order of 0.1-2.0 μm/s, and more recent studies have demonstrated that flow can reach velocities as high as 4.0 μm/s (6, 7).Interstitial flow is particularly important in driving transport in the vicinity of tumors, as neoplastic tissue is often characterized by localized increases in interstitial pressure, leading to high interstitial pressure gradients at the tumor margin (8). Interstitial flow has hence emerged as a possible stimulus for guiding tumor cell migration in the formation of metastases (9-12).Shields et al. observed increase...

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Interstitial flow influences direction of tumor cell migration through competing mechanisms

Polacheck¹,

Charest

Kamm

2011

Proc. Natl. Acad. Sci. U.S.A.

424

434

View full text Add to dashboard Cite

show abstract

“…Fluid flow is known to enhance matrix synthesis within TE constructs during perfusion culture. 19,40,50 Furthermore, differences in fibrillar collagen organization of the ECM, which are flow dependent, 51 could also explain the ECM differences that were observed by PTA staining as the ECM morphology could influence the binding mechanism of PTA to the ECM proteins. In Figure 5, it may also be observed that the difference in collagen content, as determined by Picrosirius Red staining, for the different flow rates is less pronounced than the one observed with the PTA staining.…”

Section: Papantoniou Et Almentioning

confidence: 99%

Three-Dimensional Characterization of Tissue-Engineered Constructs by Contrast-Enhanced Nanofocus Computed Tomography

Papantoniou

Sonnaert

Geris

et al. 2014

Tissue Engineering Part C: Methods

View full text Add to dashboard Cite

To successfully implement tissue-engineered (TE) constructs as part of a clinical therapy, it is necessary to develop quality control tools that will ensure accurate and consistent TE construct release specifications. Hence, advanced methods to monitor TE construct properties need to be further developed. In this study, we showed proof of concept for contrast-enhanced nanofocus computed tomography (CE-nano-CT) as a whole-construct imaging technique with a noninvasive potential that enables three-dimensional (3D) visualization and quantification of in vitro engineered extracellular matrix (ECM) in TE constructs. In particular, we performed a 3D qualitative and quantitative structural and spatial assessment of the in vitro engineered ECM, formed during static and perfusion bioreactor cell culture in 3D TE scaffolds, using two contrast agents, namely, Hexabrix Ò and phosphotungstic acid (PTA). To evaluate the potential of CE-nano-CT, a comparison was made to standardly used techniques such as Live/Dead viability/cytotoxicity, Picrosirius Red staining, and to net dry weight measurements of the TE constructs. When using Hexabrix as the contrast agent, the ECM volume fitted linearly with the net dry ECM weight independent from the flow rate used, thus suggesting that it stains most of the ECM. When using PTA as the contrast agent, comparing to net weight measurements showed that PTA only stains a part of the ECM. This was attributed to the binding specificity of this contrast agent. In addition, the PTA-stained CE-nano-CT data showed pronounced distinction between flow conditions when compared to Hexabrix, indicating culture-specific structural ECM differences. This novel type of information can contribute to optimize bioreactor culture conditions and potentially critical quality characteristics of TE constructs such as ECM quantity and homogeneity, facilitating the gradual transformation of TE constructs in well-characterized TE products.

show abstract

“…This elevated fluid pressure drives interstitial flow (IF) and alters chemical transport within the tumor (13), and IF influences tumor cell migration through the generation of autocrine chemokine gradients (14). Equally important, although not as well understood, is the physical drag imparted on the ECM and constitutive cells (15) by IF, which is analogous to the FA-activating shear stresses generated on endothelial cells by hemodynamic forces (16). With endothelial cells, shear stress can be the dominant mechanical stimulus that induces FAK activation and cytoskeletal remodeling; however, for cells embedded within a porous matrix scaffold, the ratio of the force due to the pressure drop across the cell to the total shear force is inversely proportional to hydrogel permeability (SI Appendix, Eq.…”

mentioning

confidence: 99%

Mechanotransduction of fluid stresses governs 3D cell migration

Polacheck

German

Mammoto

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

223

215

View full text Add to dashboard Cite

Solid tumors are characterized by high interstitial fluid pressure, which drives fluid efflux from the tumor core. Tumor-associated interstitial flow (IF) at a rate of ∼3 μm/s has been shown to induce cell migration in the upstream direction (rheotaxis). However, the molecular biophysical mechanism that underlies upstream cell polarization and rheotaxis remains unclear. We developed a microfluidic platform to investigate the effects of IF fluid stresses imparted on cells embedded within a collagen type I hydrogel, and we demonstrate that IF stresses result in a transcellular gradient in β1-integrin activation with vinculin, focal adhesion kinase (FAK), FAK PY397 , F actin, and paxillindependent protrusion formation localizing to the upstream side of the cell, where matrix adhesions are under maximum tension. This previously unknown mechanism is the result of a force balance between fluid drag on the cell and matrix adhesion tension and is therefore a fundamental, but previously unknown, stimulus for directing cell movement within porous extracellular matrix.mechanobiology | breast cancer | metastasis I ntegrins and associated focal adhesion (FA) proteins form a tension-sensitive mechanical link between the extracellular matrix (ECM) and the cytoskeleton, and serve as key components in the signaling cascade by which cells transduce mechanical signals into biological responses (mechanotransduction) (1, 2). Contractile stresses generated by the cell are balanced by tractions at cell-substrate adhesions, and the FA protein vinculin accumulates at regions of high substrate stress (3, 4). The FA protein paxillin colocalizes with vinculin (4) and mediates β1-integrin FA turnover through interaction with FA kinase (FAK) (5). The FAK-paxillin signaling axis recruits vinculin to β1 integrins at regions of high matrix adhesion tension (6), and paxillin-a key mechanosensor (7)-mediates protrusion formation at regions of high stress on 2D substrates (8), and FAK-paxillin-vinculin signaling is required for mechanosensing and durotaxis (9).The tumor microenvironment imparts mechanical and chemical signals on tumor and stromal cells (10), and advanced breast carcinomas are characterized by high interstitial fluid pressure (11), an indicator of poor prognosis (12). This elevated fluid pressure drives interstitial flow (IF) and alters chemical transport within the tumor (13), and IF influences tumor cell migration through the generation of autocrine chemokine gradients (14). Equally important, although not as well understood, is the physical drag imparted on the ECM and constitutive cells (15) by IF, which is analogous to the FA-activating shear stresses generated on endothelial cells by hemodynamic forces (16). With endothelial cells, shear stress can be the dominant mechanical stimulus that induces FAK activation and cytoskeletal remodeling; however, for cells embedded within a porous matrix scaffold, the ratio of the force due to the pressure drop across the cell to the total shear force is inversely proportional to hydrogel p...

show abstract

Cells in 3D matrices under interstitial flow: Effects of extracellular matrix alignment on cell shear stress and drag forces

Cited by 85 publications

References 50 publications

Interstitial flow influences direction of tumor cell migration through competing mechanisms

Interstitial flow influences direction of tumor cell migration through competing mechanisms

Three-Dimensional Characterization of Tissue-Engineered Constructs by Contrast-Enhanced Nanofocus Computed Tomography

Mechanotransduction of fluid stresses governs 3D cell migration

Contact Info

Product

Resources

About