Directed Three-Dimensional Growth of Microvascular Cells and Isolated Microvessel Fragments

Tissue engineering has promise as a means for repairing diseased and damaged tissues. A significant challenge in tissue construction relates to the constraints placed on tissue geometries resulting from diffusion limitations. An ability to incorporate a premade vasculature would overcome these diffi...

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Bibliographic Details
Published in:Cell transplantation 2006-01, Vol.15 (6), p.533-540
Main Authors: Chang, Carlos C., Hoying, James B.
Format: Article
Language:English
Subjects:
Animals
Blood Vessels - growth & development
Cell Survival
Collagen - metabolism
Dimethylpolysiloxanes - metabolism
Endothelial Cells - cytology
Microfluidics
Rats
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Summary:Tissue engineering has promise as a means for repairing diseased and damaged tissues. A significant challenge in tissue construction relates to the constraints placed on tissue geometries resulting from diffusion limitations. An ability to incorporate a premade vasculature would overcome these difficulties and promote construct viability once implanted. Most in vitro microvascular fabrication strategies rely on surface-associated cell growth, manipulated cell monolayers, or random arrangement of cells within matrix materials. In contrast, we successfully suspended microvascular cells and isolated microvessel fragments within collagen and then microfluidically drove the mixtures into microfabricated network topologies. Developing within the 3D collagen matrix, patterned cells progressed into cord-like morphologies. These geometries were directed by the surrounding elastomer mold. With similar techniques, suspended fragments formed endothelial sprouts. By avoiding the addition of exogenous growth factors, we allowed constituent cells and fragments to autonomously develop within the constructs, providing a more physiologically relevant system for in vitro microvascular development. In addition, we present the first examples of directed endothelial cell sprouting from parent microvessel fragments. We believe this system may serve as a foundation for future in vivo fabrication of microvascular networks for tissue engineering applications.
ISSN:0963-6897
1555-3892
DOI:10.3727/000000006783981693