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Functionality, growth and accelerated aging of tissue engineered living autologous vascular grafts

Kelm, Jens M; Emmert, Maximilian Y; Zürcher, Armin; Schmidt, Dörthe; Begus Nahrmann, Yvonne; Rudolph, Karl L; Weber, Benedikt; Brokopp, Chad E; Frauenfelder, Thomas; Leschka, Sebastian; Odermatt, Bernhard; Jenni, Rolf; Falk, Volkmar; Zünd, Gregor; Hoerstrup, Simon P (2012). Functionality, growth and accelerated aging of tissue engineered living autologous vascular grafts. Biomaterials, 33(33):8277-8285.

Abstract

Living autologous tissue engineered vascular-grafts (TEVGs) with growth-capacity may overcome the limitations of contemporary artificial-prostheses. However, the multi-step invitro production of TEVGs requires extensive exvivo cell-manipulations with unknown effects on functionality and quality of TEVGs due to an accelerated biological age of the cells. Here, the impact of biological cell-age and tissue-remodeling capacity of TEVGs in relation to their clinical long-term functionality are investigated. TEVGs were implanted as pulmonary-artery (PA) replacements in juvenile sheep and followed for up to 240 weeks (∼4.5years). Telomere length and telomerase activity were compared amongst TEVGs and adjacent native tissue. Telomerase-activity of invitro expanded autologous vascular-cells prior to seeding was <5% as compared to a leukemic cell line, indicating biological-aging associated with decreasing telomere-length with each cellular-doubling. Up to 100 weeks, the cells in the TEVGs had consistently shorter telomeres compared to the native counterpart, whereas no significant differences were detectable at 240 weeks. Computed tomography (CT) analysis demonstrated physiological wall-pressures, shear-stresses, and flow-pattern comparable to the native PA. There were no signs of degeneration detectable and continuous native-analogous growth was confirmed by vessel-volumetry. TEVGs exhibit a higher biological age compared to their native counterparts. However, despite of this tissue engineering technology related accelerated biological-aging, growth-capacity and long-term functionality was not compromised. To the contrary, extensive in-vivo remodeling processes with substantial endogenous cellular turnover appears to result in "TEVG rejuvenation" and excellent clinical performance. As these large-animal results can be extrapolated to approximately 20 human years, this study suggests long-term clinical-safety of cardiovascular in vitro tissue engineering and may contribute to safety-criteria as to first-in-man clinical-trials.

Additional indexing

Item Type:Journal Article, refereed, original work
Communities & Collections:04 Faculty of Medicine > University Hospital Zurich > Clinic for Cardiac Surgery
04 Faculty of Medicine > University Hospital Zurich > Division of Surgical Research
04 Faculty of Medicine > University Hospital Zurich > Clinic for Diagnostic and Interventional Radiology
04 Faculty of Medicine > Institute for Regenerative Medicine (IREM)
Dewey Decimal Classification:570 Life sciences; biology
610 Medicine & health
Scopus Subject Areas:Physical Sciences > Bioengineering
Physical Sciences > Ceramics and Composites
Life Sciences > Biophysics
Physical Sciences > Biomaterials
Physical Sciences > Mechanics of Materials
Language:English
Date:2012
Deposited On:17 Sep 2012 15:08
Last Modified:07 Sep 2024 01:38
Publisher:Elsevier
ISSN:0142-9612
OA Status:Closed
Publisher DOI:https://doi.org/10.1016/j.biomaterials.2012.07.049
PubMed ID:22906604

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