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. 1987 Jun;14(2):119–126.

Endothelialization of Artificial Surfaces: Does Surface Tension Determine in vitro Growth of Human Saphenous Vein Endothelial Cells?

Roland Fasol 1, Peter Zilla 1, Manfred Deutsch 1, Teddy Fischlein 1, Margit Kadletz 1, Andrea Griesmacher 1, Mathias M Müller 1
PMCID: PMC324709  PMID: 15229730

Abstract

To evaluate the possibility of providing, in vitro, an endothelial lining for artificial hearts, we cultivated adult autologous endothelial cells on two polyurethane and two silicone rubber surfaces. Over the ensuing 11-day period, we investigated the resulting cell proliferation and morphology by means of scanning electron and light microscopy. On the silicone rubber surfaces, seeding of 200,000 human saphenous vein endothelial cells per cm2 produced an ideal cobblestone monolayer within a single day. In contrast, the polyurethane surfaces displayed an uneven, patchy distribution of endothelial cells. Scanning electron microscopy revealed microvilli and marginal overlapping in both groups. After the first day, the cell count on the polyurethane surfaces increased, whereas the count on the silicone rubber surfaces decreased. Morphologic investigations revealed that the ideally shaped cells initially on the silicone rubber had begun to overspread and subsequently to become detached, leaving denuded spheroid areas. Moreover, cultivation for 11 days on the polyurethane surfaces resulted in an unevenness of cell distribution that far exceeded the unevenness seen on the first day. Thus, despite the fact that materials with a high surface tension (such as silicone rubbers) seem to be ideal for initial cell spreading, subsequent cultivation results in cell detachment and death. On materials with a lower surface tension (such as polyurethanes), the less differentiated monolayers do at least proliferate, although their morphology remains unsatisfactory. Even if adult human endothelial cells should prove shear-stress-resistant, a minimum of 6 to 8 weeks would be required to establish autologous endothelial cell monolayers on the inner surface. Therefore, the endothelialization of artificial hearts is not possible when such hearts are used for urgent “bridging” before cardiac transplantation. (Texas Heart Institute Journal 1987; 14:119-126)

Keywords: Cells, cultured

Keywords: heart, artificial

Keywords: polyurethanes

Keywords: silicones

Keywords: endothelialization

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Selected References

These references are in PubMed. This may not be the complete list of references from this article.

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