Bioactive coating of decellularized vascular grafts with a temperature-sensitive VEGF-conjugated hydrogel accelerates autologous endothelialization in vivo.

No ideal small-diameter vascular graft for widespread clinical application has yet been developed and current approaches still suffer from graft failure because of thrombosis or degeneration. Decellularized vascular grafts are a promising strategy as they preserve native vessel architecture while eliminating cell-based antigens and allow for autologous recellularization. In the present study, a functional in vivo rodent aortic transplantation model was used in order to evaluate the benefit of bioactive coating of decellularized vascular grafts with vascular endothelial growth factor (VEGF) conjugated to a temperature-sensitive aliphatic polyester hydrogel (HG). Luminal HG-VEGF coating persistence up to 4 weeks was confirmed in vivo by rhodamine-labelling. Doppler-sonography showed that the grafts were functional for up to 8 weeks in vivo. Histological and immunohistochemical analysis of the explanted grafts after 4 weeks and 8 weeks in vivo demonstrated significantly increased endothelium formation in the HG-VEGF group compared with the control group (luminal surface covered with single-layered endothelium, 4 weeks: 64.8 ± 7.6% vs. 40.4 ± 8.3%, p = 0.025) as well as enhanced media recellularization (absolute cell count, 8 weeks: 22.1 ± 13.0 vs. 3.2 ± 3.6, p = 0.0039). However, HG-VEGF coating also led to increased neo-intimal hyperplasia, resulting in a significantly increased intima-to-media ratio in the perianastomotic regions (intima-to-media ratio, 8 weeks: 1.61 ± 0.17 vs. 0.93 ± 0.09, p = 0.008; HG-VEGF vs. control). The findings indicate that HG-VEGF coating has potential for the development of engineered small-diameter artificial grafts, although further research is needed to prevent neo-intimal hyperplasia. Copyright © 2016 John Wiley & Sons, Ltd.

Improvement of the in vivo cellular repopulation of decellularized cardiovascular tissues by a detergent-free, non-proteolytic, actin-disassembling regimen.

Low immunogenicity and high repopulation capacity are crucial determinants for the functional and structural performance of acellular cardiovascular implants. The present study evaluates a detergent-free, non-proteolytic, actin-disassembling regimen (BIO) for decellularization of heart valve and vessel grafts, particularly focusing on their bio-functionality. Rat aortic conduits (rAoC; n = 89) and porcine aortic valve samples (n = 106) are decellularized using detergents (group DET) or the BIO regimen. BIO decellularization results in effective elimination of cellular proteins and significantly improves removal of DNA as compared with group DET, while the extracellular matrix (ECM) structure as well as mechanical properties are preserved. The architecture of rAoC in group BIO allows for improved bio-functionalization with fibronectin (FN) in a standardized rat implantation model: BIO treatment significantly increases speed and amount of autologous medial cellular repopulation in vivo (p < 0.001) and decreases the formation of hyperplastic intima (p < 0.001) as compared with FN-coated DET-decellularized grafts. Moreover, there are no signs of infiltration with inflammatory cells. The present biological, detergent-free, non-proteolytic regimen balances effective decellularization and ECM preservation in cardiovascular grafts, and provides optimized bio-functionality. Additionally, this study implies that the actin-disassembling regimen may be a promising approach for bioengineering of acellular scaffolds from other muscular tissues, as for example myocardium or intestine. Copyright © 2017 John Wiley & Sons, Ltd.

The degeneration of biological cardiovascular prostheses under pro-calcific metabolic conditions in a small animal model.

In order to allow for a comparative evaluation of the in vivo degeneration of biological and tissue-engineered heart valves and vascular grafts, a small animal model of accelerated cardiovascular calcification is desired. Wistar rats (n = 102; 6 groups) were fed ad libitum with regular chow and 5 different regimens of pro-calcific diet supplemented with combinations of vitamin D (VD), cholesterol (CH) and dicalcium phosphate (PH). Moreover, cryopreserved (n = 7) or detergent-decellularized rat aortic conduit grafts (n = 6) were infrarenally implanted in Wistar rats under severely pro-calcific conditions. The follow-up lasted up to 12 weeks. High-dose application of VD (300,000 IU/kg), CH (2%) and PH (1.5%) resulted in elevated serum calcium and cholesterol levels as well as LDL/HDL ratio. It increased the tissue MMP activity visualized by in situ zymography and caused significantly aggravated calcification of the native aortic valve as well as the aortic wall as assessed by histology and micro-computed tomography. (Immuno)histology and quantitative real-time PCR revealed chondro-osteogenic cell transformation, lipid deposition, nitrosative stress and low-level inflammation to be involved in the formation of calcific lesions. Despite pro-calcific in vivo conditions, decellularization significantly reduced calcification, inflammation and intimal hyperplasia in aortic conduit implants. A well balanced dietary trigger for pathologic metabolic conditions may represent an appropriate mid-term treatment to induce calcifying degeneration of aortic valves as well as vascular structures in the systemic circulation in rats. With respect to experimental investigation focusing on calcifying degeneration of native or prosthetic tissue, this regimen may serve as a valuable tool with a rapid onset and multi-facetted character of cardiovascular degeneration.

Simvastatin does not diminish the in vivo degeneration of decellularized aortic conduits.

BACKGROUND: All present biological cardiovascular prostheses are prone to progressive in vivo degeneration, which can be partially impaired by decellularization. The administration of statins may provide an additional beneficial effect. We provide the first in vivo data on the effect of statins on decellularized cardiovascular implants. METHODS: Wistar rats with aortic valve insufficiency (day 14) were fed either with a pro-calcific diet (group C; n = 17), or the same diet additionally supplemented with simvastatin (group S; n = 16). Aortic conduits from Sprague-Dawley rats were detergent-decellularized, infrarenally implanted (day 0) in all recipients and explanted at day 28 or day 84. RESULTS: Sonographic competence of the conduit perfusion was 100%, and overall survival amounted to 97%. Simvastatin decreased the low-density lipoprotein cholesterol serum levels; however, it did not affect the calcification of the implants. Histology revealed alpha-smooth muscle actin-positive intima hyperplasia in both groups. Extensive matrix metalloproteinase activity was observed in calcified areas, especially in group S. Quantitative RNA analysis resulted in no differences with regard to several markers of calcifying degeneration (alkaline phosphatase, osteopontin, osteocalcin, osteoprotegerin, bone morphogenetic protein-2, runt-related transcription factor-2) and inflammation (tumor necrosis factor α, interleukin 1ß, receptor for advanced glycation end products, CD39, CD73), but significantly lower levels of interleukin-6 in group S. CONCLUSIONS: In a standardized small animal model of accelerated cardiovascular calcification, simvastatin failed to diminish the calcification of decellularized aortic conduit implants. This finding confirms the observations of recent clinical trials. However, further experiments are warranted to elucidate the value of partial benefits associated with lower circulating lipid and proinflammatory cytokine levels.

Acceleration of autologous in vivo recellularization of decellularized aortic conduits by fibronectin surface coating.

Decellularization is a promising option to diminish immune and inflammatory response against donor grafts. In order to accelerate the autologous in vivo recellularization of aortic conduits for an enhanced biocompatibility, we tested fibronectin surface coating in a standardized rat implantation model. Detergent-decellularized rat aortic conduits (n = 36) were surface-coated with covalently Alexa488-labeled fibronectin (50 µg/ml, 24 h) and implanted into the systemic circulation of Wistar rats for up to 8 weeks (group FN; n = 18). Uncoated implants served as controls (group C; n = 18). Fibronectin-bound fluorescence on both surfaces of the aortic conduits was persistent for at least 8 weeks. Cellular repopulation was examined by histology and immunofluorescence (n = 24). Luminal endothelialization was significantly accelerated in group FN (p = 0.006 after 8 weeks), however, local myofibroblast hyperplasia with significantly increased ratio of intima-to-media thickness occurred (p = 0.0002 after 8 weeks). Originating from the adventitial surface, alpha-smooth muscle actin and desmin positive cell invasion into the media of fibronectin-coated conduits was significantly increased as compared to group C (p < 0.0001). In these medial areas, in situ zymography revealed enhanced matrix metalloproteinase activity. In both groups, inflammatory cell markers (CD3 and CD68) and signs of thrombosis proved negative. With regard to several markers of cell adhesion, inflammation and calcification, quantitative real-time PCR (n = 12) revealed no significant inter-group differences. Fibronectin surface coating of decellularized cardiovascular implants proved feasible and persistent for at least 8 weeks in the systemic circulation. Biofunctional protein coating accelerated the autologous in vivo endothelialization and induced a significantly increased medial recellularization. Therefore, this strategy may contribute to the improvement of current clinically applied bioprostheses.