Off-the-Shelf Synthetic Biodegradable Grafts Transform In Situ into a Living Arteriovenous Fistula in a Large Animal Model

Publication date

2024-07

Authors

Besseling, Paul JISNI 0000000023537725
Szymczyk, Wojciech
Teraa, MartinORCID 0000-0002-6751-6752ISNI 0000000395201798
Toorop, R. J.ISNI 0000000392335889
Wu, Dan Jing
Driessen, Rob C H
Lichauco, Arturo M
Janssen, Henk M
van de Kaa, Melanie
den Ouden, Krista

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Article

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Abstract

Current vascular access options require frequent interventions. In situ tissue engineering (TE) may overcome these limitations by combining the initial success of synthetic grafts with long-term advantages of autologous vessels by using biodegradable grafts that transform into autologous vascular tissue at the site of implantation. Scaffolds (6 mm-Ø) made of supramolecular polycarbonate-bisurea (PC-BU), with a polycaprolactone (PCL) anti-kinking-coil, are implanted between the carotid artery and jugular vein in goats. A subset is bio-functionalized using bisurea-modified-Stromal cell-derived factor-1α (SDF1α) derived peptides and ePTFE grafts as controls. Grafts are explanted after 1 and 3 months, and evaluated for material degradation, tissue formation, compliance, and patency. At 3 months, the scaffold is resorbed and replaced by vascular neo-tissue, including elastin, contractile markers, and endothelial lining. No dilations, ruptures, or aneurysms are observed and grafts are successfully cannulated at termination. SDF-1α-peptide-biofunctionalization does not influence outcomes. Patency is lower in TE grafts (50%) compared to controls (100% patency), predominantly caused by intimal hyperplasia. Rapid remodeling of a synthetic, biodegradable vascular scaffold into a living, compliant arteriovenous fistula is demonstrated in a large animal model. Despite lower patency compared to ePTFE, transformation into autologous and compliant living tissue with self-healing capacity may have long-term advantages.

Keywords

AV shunt, biodegradable supramolecular material, biofunctionalization, goat model, in situ tissue engineering, vascular dialysis access, Biomedical Engineering, Biomaterials, Pharmaceutical Science, Journal Article

Citation

Besseling, P J, Szymczyk, W, Teraa, M, Toorop, R J, Wu, D J, Driessen, R C H, Lichauco, A M, Janssen, H M, van de Kaa, M, den Ouden, K, de Bree, P M, Fledderus, J O, Bouten, C V C, de Borst, G J, Dankers, P Y W & Verhaar, M C 2024, 'Off-the-Shelf Synthetic Biodegradable Grafts Transform In Situ into a Living Arteriovenous Fistula in a Large Animal Model', Advanced Healthcare Materials, vol. 13, no. 17, e2303888. https://doi.org/10.1002/adhm.202303888