Sugat Ratna Tuladhar scite author profile

Xenogeneic pericardium-based substitutes are employed for several surgical indications after chemical shielding, limiting their biocompatibility and therapeutic durability. Adverse responses to these replacements might be prevented by tissue decellularization, ideally removing cells and preserving the original extracellular matrix (ECM). The aim of this study was to compare the mostly applied pericardia in clinics, i.e., bovine and porcine tissues, after their decellularization, and obtain new insights for their possible surgical use. Bovine and porcine pericardia were submitted to TRICOL decellularization, based on osmotic shock, detergents and nuclease treatment. TRICOL procedure resulted in being effective in cell removal and preservation of ECM architecture of both species’ scaffolds. Collagen and elastin were retained but glycosaminoglycans were reduced, significantly for bovine scaffolds. Tissue hydration was varied by decellularization, with a rise for bovine pericardia and a decrease for porcine ones. TRICOL significantly increased porcine pericardial thickness, while a non-significant reduction was observed for the bovine counterpart. The protein secondary structure and thermal denaturation profile of both species’ scaffolds were unaltered. Both pericardial tissues showed augmented biomechanical compliance after decellularization. The ECM bioactivity of bovine and porcine pericardia was unaffected by decellularization, sustaining viability and proliferation of human mesenchymal stem cells and endothelial cells. In conclusion, decellularized bovine and porcine pericardia demonstrate possessing the characteristics that are suitable for the creation of novel scaffolds for reconstruction or replacement: differences in water content, thickness and glycosaminoglycans might influence some of their biomechanical properties and, hence, their indication for surgical use.

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Bioengineered percutaneous heart valves for transcatheter aortic valve replacement: a comparative evaluation of decellularised bovine and porcine pericardia

Tuladhar

Mulderrig

Barbera

et al. 2021

Materials Science and Engineering: C

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Genetic knockout of porcine GGTA1 or CMAH/GGTA1 is associated with the emergence of neo‐glycans

Morticelli

Rossdam

Cajic

et al. 2023

Xenotransplantation

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BackgroundPig‐derived tissues could overcome the shortage of human donor organs in transplantation. However, the glycans with terminal α‐Gal and Neu5Gc, which are synthesized by enzymes, encoded by the genes GGTA1 and CMAH, are known to play a major role in immunogenicity of porcine tissue, ultimately leading to xenograft rejection.MethodsThe N‐glycome and glycosphingolipidome of native and decellularized porcine pericardia from wildtype (WT), GGTA1‐KO and GGTA1/CMAH‐KO pigs were analyzed by multiplexed capillary gel electrophoresis coupled to laser‐induced fluorescence detection.ResultsWe identified biantennary and core‐fucosylated N‐glycans terminating with immunogenic α‐Gal‐ and α‐Gal‐/Neu5Gc‐epitopes on pericardium of WT pigs that were absent in GGTA1 and GGTA1/CMAH‐KO pigs, respectively. Levels of N‐glycans terminating with galactose bound in β(1‐4)‐linkage to N‐acetylglucosamine and their derivatives elongated by Neu5Ac were increased in both KO groups. N‐glycans capped with Neu5Gc were increased in GGTA1‐KO pigs compared to WT, but were not detected in GGTA1/CMAH‐KO pigs. Similarly, the ganglioside Neu5Gc‐GM3 was found in WT and GGTA1‐KO but not in GGTA1/CMAH‐KO pigs. The applied detergent based decellularization efficiently removed GSL glycans.ConclusionGenetic deletion of GGTA1 or GGTA1/CMAH removes specific epitopes providing a more human‐like glycosylation pattern, but at the same time changes distribution and levels of other porcine glycans that are potentially immunogenic.

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Cell colonization potential of thermoplastic silicone-based polyurethane nonwovens for novel heart valve prosthesis

Tuladhar

Teske

Oschatz

et al. 2021

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Heart valve tissue engineering aims at creating living valves through colonization of scaffolds with patient’s own cells. Various cell sources have been explored focusing mainly on endothelialization of the scaffold surface. Endothelial like cells, such as endothelial progenitor cells (EPCs), which can be isolated from peripheral blood or bone marrow could be a suitable option. In this study we investigated cell colonization potential of ovine EPCs (OEPCs) on thermoplastic silicone-based polyurethane (TSPU) polymer scaffolds. TSPU nonwovens with and without vascular endothelial growth factor (VEGF) functionalization were used. SEM images showed that by day 3 the cells were growing as patches on the surface of both polymer groups. The cell patches continued growing and started covering more of the nonwoven surface. On day 7 the cells had almost covered the scaffold surface. The cells were more uniformly distributed as monolayer on the functionalized TSPU compared to the non-functionalized nonwovens. Live/Dead staining provided bright green fluorescence on the samples, indicating metabolically active alive cells. These static cell seeding experiments demonstrated that functionalized TPSU nonwovens support endothelialization. The feasibility of TPSU nonwovens as heart valve prosthesis scaffold could be further explored with animal studies in an ovine model.

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