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Microfluidic endothelium for studying the intravascular adhesion of metastatic breast cancer cells.


ABSTRACT:

Background

The ability to properly model intravascular steps in metastasis is essential in identifying key physical, cellular, and molecular determinants that can be targeted therapeutically to prevent metastatic disease. Research on the vascular microenvironment has been hindered by challenges in studying this compartment in metastasis under conditions that reproduce in vivo physiology while allowing facile experimental manipulation.

Methodology/principal findings

We present a microfluidic vasculature system to model interactions between circulating breast cancer cells with microvascular endothelium at potential sites of metastasis. The microfluidic vasculature produces spatially-restricted stimulation from the basal side of the endothelium that models both organ-specific localization and polarization of chemokines and many other signaling molecules under variable flow conditions. We used this microfluidic system to produce site-specific stimulation of microvascular endothelium with CXCL12, a chemokine strongly implicated in metastasis.

Conclusions/significance

When added from the basal side, CXCL12 acts through receptor CXCR4 on endothelium to promote adhesion of circulating breast cancer cells, independent of CXCL12 receptors CXCR4 or CXCR7 on tumor cells. These studies suggest that targeting CXCL12-CXCR4 signaling in endothelium may limit metastases in breast and other cancers and highlight the unique capabilities of our microfluidic device to advance studies of the intravascular microenvironment in metastasis.

SUBMITTER: Song JW 

PROVIDER: S-EPMC2684591 | biostudies-literature | 2009 Jun

REPOSITORIES: biostudies-literature

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Publications

Microfluidic endothelium for studying the intravascular adhesion of metastatic breast cancer cells.

Song Jonathan W JW   Cavnar Stephen P SP   Walker Ann C AC   Luker Kathryn E KE   Gupta Mudit M   Tung Yi-Chung YC   Luker Gary D GD   Takayama Shuichi S  

PloS one 20090601 6


<h4>Background</h4>The ability to properly model intravascular steps in metastasis is essential in identifying key physical, cellular, and molecular determinants that can be targeted therapeutically to prevent metastatic disease. Research on the vascular microenvironment has been hindered by challenges in studying this compartment in metastasis under conditions that reproduce in vivo physiology while allowing facile experimental manipulation.<h4>Methodology/principal findings</h4>We present a mi  ...[more]

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