Preclinical Development of Tissue-Engineered Vein Valves and Venous Substitutes using Re-Endothelialised Human Vein Matrix

Abstract Objective The aim of the study was to evaluate the use of a decellularised scaffold and its re-endothelialisation in vitro in order to create human vascular substitutes containing venous valves. This research is clinically relevant particularly with regard to the development of venous (valv...

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Bibliographic Details
Published in:European journal of vascular and endovascular surgery 2009-01, Vol.37 (1), p.92-102
Main Authors: Teebken, O.E, Puschmann, C, Breitenbach, I, Rohde, B, Burgwitz, K, Haverich, A
Format: Article
Language:English
Subjects:
Artificial Organs
Bioprosthesis
Blood Vessel Prosthesis
Chronic Disease
Chronic venous insufficiency
Endothelial cell seeding
Endothelium, Vascular - physiology
Extracellular Matrix
Humans
Saphenous Vein
Small calibre graft
Surgery
Tissue Engineering
Tissue Scaffolds
Vein valve substitute
Venous Insufficiency - surgery
Venous Valves
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Summary:Abstract Objective The aim of the study was to evaluate the use of a decellularised scaffold and its re-endothelialisation in vitro in order to create human vascular substitutes containing venous valves. This research is clinically relevant particularly with regard to the development of venous (valve containing) transplants to replace a diseased femoral vein valve and/or obstructed veins. This technique may enable causal treatment of venous reflux and obstructions. Materials and methods Valve-bearing segments of human allogeneic great saphenous veins (GSVs) were decellularised using sodium deoxycholic acid (SD) and treated with DNase I. Human venous endothelial cells (ECs) were enzymatically harvested from the GSV, expanded up to the 3rd passage using FCS ( n = 20) or human AB serum (hABS; n = 8) supplemented media before used for re-seeding. In special bioreactors, 3D re-seeding of 28 decellularised GSV was performed with constant perfusion (A; n = 8), bidirectional perfusion (B; n = 8), bidirectional perfusion/reduced flow (C; n = 2), static conditions (D; n = 2), and bidirectional perfusion/reduced flow using hABS (E; n = 8) instead of FCS. Decellularised GSV, scaled-up EC and 3D-seeded tissue-engineered valve containing neo-veins underwent immunohistochemical and PCR characterisation. Results Intact collagen and elastin networks as well as complete acellularity were shown after GSV decellularisation. In EC culture, supplementation with hABS led to a significantly higher expression of vWF compared to FCS ( p = 0.025). Additional EC markers such as CD 31, FLK-1 and VE-Cadherin were not altered. EC re-seeding using hABS supplemented medium (E) led to a confluent monolayer of cells that were immunohistochemically positive for FLK-1, CD 31, vWF and VE-Cadherin and by means of PCR after RNA preparation in 7 of 8 cases but was unsuccessful if FCS was used (A–D). In A–D cells presented as conglomerates positive for CD 31 and VE-Cadherin, suggesting sufficient intercellular contact but not cell–matrix contact. Conclusions Treatment with SD and DNase enables complete decellularisation of human valve containing veins whereas 3D matrix components such as collagen and elastin remain preserved. The lumen of the scaffold including the valves can be successfully re-seeded with a human EC monolayer in a 3D bioreactor. There is substantial evidence that hABS and not FCS is essential for the completion of cell–matrix contacts in human veins.
ISSN:1078-5884
1532-2165
DOI:10.1016/j.ejvs.2008.10.012