Title :
Vascularization of capillary-scale channels in type I collagen gels
Author :
Boland, Nelson F. ; Linville, Raleigh M. ; Covarrubias, Gil ; Tien, Joe
Author_Institution :
Dept. of Biomed. Eng., Boston Univ., Boston, MA, USA
Abstract :
This work examines physical and chemical signals that promote in vitro vascularization of capillary-scale channels in type I collagen gels. We show that retrograde pressure induces endothelial migration and cyclic AMP promotes endothelial stability. Together, these signals enabled vascularization of microchannels as narrow as 11 μm, matching the size scale of capillaries. Further optimization of these signals may allow the formation of perfused, functional capillary-scale vessels. Such engineered capillaries may assist studies of normal and pathological vascularization, and may provide building blocks to create clinically viable vascularized tissue constructs.
Keywords :
biochemistry; biomechanics; blood vessels; cell motility; diseases; materials preparation; molecular biophysics; polymer gels; proteins; tissue engineering; capillary engineering; capillary-scale channel vascularization; chemical signal; clinically viable vascularized tissue construct; cyclic AMP; endothelial migration; endothelial stability promotion; functional capillary-scale vessel formation; in vitro vascularization; microchannel vascularization; normal vascularization; pathological vascularization; perfused capillary-scale vessel formation; physical signal; retrograde pressure effect; signal optimization; size 11 mum; type I collagen gel; Delamination; Electron tubes; In vitro; Microchannels; Pathology; Tissue engineering;
Conference_Titel :
Biomedical Engineering Conference (NEBEC), 2015 41st Annual Northeast
Conference_Location :
Troy, NY
Print_ISBN :
978-1-4799-8358-2
DOI :
10.1109/NEBEC.2015.7117067
