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Literature DB >> 23090158

Full range physiological mass transport control in 3D tissue cultures.

Yu-Hsiang Hsu¹, Monica L Moya, Parinaz Abiri, Christopher C W Hughes, Steven C George, Abraham P Lee.

Abstract

We report the first demonstration of a microfluidic platform that captures the full physiological range of mass transport in 3-D tissue culture. The basis of our method used long microfluidic channels connected to both sides of a central microtissue chamber at different downstream positions to control the mass transport distribution within the chamber. Precise control of the Péclet number (Pe), defined as the ratio of convective to diffusive transport, over nearly five orders of magnitude (0.0056 to 160) was achieved. The platform was used to systematically investigate the role of physiological mass transport on vasculogenesis. We demonstrate, for the first time, that vasculogenesis can be independently stimulated by interstitial flow (Pe > 10) or hypoxic conditions (Pe < 0.1), and not by the intermediate state (normal living tissue). This simple platform can be applied to physiological and biological studies of 3D living tissue followed by pathological disease studies, such as cancer research and drug screening.

Entities: Chemical Disease Gene Species

Mesh：

Year: 2012 PMID： 23090158 PMCID： PMC3510322 DOI： 10.1039/c2lc40787f

Source DB: PubMed Journal: Lab Chip ISSN： 1473-0189 Impact factor: 6.799

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7. Interstitial fluid flow induces myofibroblast differentiation and collagen alignment in vitro.

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8. Diffusion limits of an in vitro thick prevascularized tissue.

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9. Effect of the glycocalyx layer on transmission of interstitial flow shear stress to embedded cells.

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10. Bulk transfer of fluid in the interstitial compartment of mammary tumors.

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2. 3D Anastomosed Microvascular Network Model with Living Capillary Networks and Endothelial Cell-Lined Microfluidic Channels.

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5. Transient Support from Fibroblasts is Sufficient to Drive Functional Vascularization in Engineered Tissues.

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6. In vitro perfused human capillary networks.

Authors: Monica L Moya; Yu-Hsiang Hsu; Abraham P Lee; Christopher C W Hughes; Steven C George
Journal: Tissue Eng Part C Methods Date: 2013-02-21 Impact factor: 3.056

7. Engineering challenges for instrumenting and controlling integrated organ-on-chip systems.

Authors: John P Wikswo; Frank E Block; David E Cliffel; Cody R Goodwin; Christina C Marasco; Dmitry A Markov; David L McLean; John A McLean; Jennifer R McKenzie; Ronald S Reiserer; Philip C Samson; David K Schaffer; Kevin T Seale; Stacy D Sherrod
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