Decellularized Porcine Heart Valve Research Articles

Strengthened Decellularized Porcine Valves via Polyvinyl Alcohol as a Template Improving Processability.

The heart valve is crucial for the human body, which directly affects the efficiency of blood transport and the normal functioning of all organs. Generally, decellularization is one method of tissue-engineered heart valve (TEHV), which can deteriorate the mechanical properties and eliminate allograft immunogenicity. In this study, removable polyvinyl alcohol (PVA) is used to encapsulate decellularized porcine heart valves (DHVs) as a dynamic template to improve the processability of DHVs, such as suturing. Mechanical tests show that the strength and elastic modulus of DHVs treated with different concentrations of PVA significantly improve. Without the PVA layer, the valve would shift during suture puncture and not achieve the desired suture result. The in vitro results indicate that decellularized valves treated with PVA can sustain the adhesion and growth of human umbilical vein endothelial cells (HUVECs). All results above show that the DHVs treated with water-soluble PVA have good mechanical properties and cytocompatibility to ensure post-treatment. On this basis, the improved processability of DHV treated with PVA enables a new paradigm for the manufacturing of scaffolds, making it easy to apply.

Hybrid heart valves with VEGF-loaded zwitterionic hydrogel coating for improved anti-calcification and re-endothelialization.

With the aging of the population in worldwide, valvular heart disease has become one of the most prominent life-threatening diseases in human health, and heart valve replacement surgery is one of the therapeutic methods for valvular heart disease. Currently, commercial bioprosthetic heart valves (BHVs) for clinical application are prepared with xenograft heart valves or pericardium crosslinked by glutaraldehyde. Due to the residual cell toxicity from glutaraldehyde, heterologous antigens, and immune response, there are still some drawbacks related to the limited lifespan of bioprosthetic heart valves, such as thrombosis, calcification, degeneration, and defectiveness of re-endothelialization. Therefore, the problems of calcification, defectiveness of re-endothelialization, and poor biocompatibility from the use of bioprosthetic heart valve need to be solved. In this study, hydrogel hybrid heart valves with improved anti-calcification and re-endothelialization were prepared by taking decellularized porcine heart valves as scaffolds following grafting with double bonds. Then, the anti-biofouling zwitterionic monomers 2-methacryloyloxyethyl phosphorylcholine (MPC) and vascular endothelial growth factor (VEGF) were utilized to obtain a hydrogel-coated hybrid heart valve (PEGDA-MPC-DHVs@VEGF). The results showed that fewer platelets and thrombi were observed on the surface of the PEGDA-MPC-DHVs@VEGF. Additionally, the PEGDA-MPC-DHVs@VEGF exhibited excellent collagen stability, biocompatibility and re-endothelialization potential. Moreover, less calcification deposition and a lower immune response were observed in the PEGDA-MPC-DHVs@VEGF compared to the glutaraldehyde-crosslinked DHVs (Glu-DHVs) after subcutaneous implantation in rats for 30 days. These studies demonstrated that the strategy of zwitterionic hydrogels loaded with VEGF may be an effective approach to improving the biocompatibility, anti-calcification and re-endothelialization of bioprosthetic heart valves.

Chemokine-Induced PBMC and Subsequent MSC Migration Toward Decellularized Heart Valve Tissue.

Enhancing the recellularization of a decellularized heart valve in situ may lead to an improved or ideal heart valve replacement. A promising approach is leveraging the immune response for inflammation-mediated recellularization. However, this mechanism has not been previously demonstrated in vitro. This study investigated loading the chemokine MCP-1 into decellularized porcine heart valve tissue and measured the migration of human peripheral blood mononuclear cells (PBMCs) and mesenchymal stem cells (MSCs) toward the chemokine loaded valve tissue. The results of this study demonstrate that MCP-1-loaded tissues increase PBMC migration compared to non-loaded tissues. Additionally, we demonstrate MCP-1-loaded tissues that have recruited PBMCs lead to increased migration of MSCs compared to decellularized tissue alone. The results of this study provide evidence for the inflammation-mediated recellularization mechanism. Furthermore, the results support the use of such an approach for enhancing the recellularization of a decellularized heart valve.

Human Heart Explant-Derived Extracellular Vesicles: Characterization and Effects on the In Vitro Recellularization of Decellularized Heart Valves.

Extracellular vesicles (EVs) are particles released from different cell types and represent key components of paracrine secretion. Accumulating evidence supports the beneficial effects of EVs for tissue regeneration. In this study, discarded human heart tissues were used to isolate human heart-derived extracellular vesicles (hH-EVs). We used nanoparticle tracking analysis (NTA) and transmission electron microscopy (TEM) to physically characterize hH-EVs and mass spectrometry (MS) to profile the protein content in these particles. The MS analysis identified a total of 1248 proteins. Gene ontology (GO) enrichment analysis in hH-EVs revealed the proteins involved in processes, such as the regulation of cell death and response to wounding. The potential of hH-EVs to induce proliferation, adhesion, angiogenesis and wound healing was investigated in vitro. Our findings demonstrate that hH-EVs have the potential to induce proliferation and angiogenesis in endothelial cells, improve wound healing and reduce mesenchymal stem-cell adhesion. Last, we showed that hH-EVs were able to significantly promote mesenchymal stem-cell recellularization of decellularized porcine heart valve leaflets. Altogether our data confirmed that hH-EVs modulate cellular processes, shedding light on the potential of these particles for tissue regeneration and for scaffold recellularization.

Structural assessments in decellularized extracellular matrix of porcine semilunar heart valves: Evaluation of cell niches.

Tissue-engineered heart valves aim to reproduce the biological properties of natural valves with anatomically correct structure and physiological performance. The closest alternative to creating an ideal heart valve substitute is to use decellularized porcine heart valves, due to their anatomy and availability. However, the immunological barrier and the structural maintenance limit the long-term physiological performance of decellularized porcine heart valves. This study investigated the extracellular matrix (ECM) structure of aortic and pulmonary porcine valves decellularized by a low concentration sodium dodecyl sulfate (SDS)-based method in order to determine the ECM scaffold (ECMS) conditions related to remodeling potential. To assess the structures of the leaflets and conduits of the heart valves, ECM components and their organization were evaluated by histology, biochemical analysis (BC), scanning electron microscopy, multiphoton microscopy, tensile test, immunofluorescence labeling (IF), and Raman microspectroscopy used to draw a profile of the cell niches. Histology and multiphoton imaging of decellularized aortic and pulmonary leaflets and conduits revealed a collagen and elastin histoarchitecture with rearrangement, loosening fibers, and glycosaminoglycan depletion confirmed by biochemistry quantification. The potential cytotoxicity of SDS residues was eliminated after 10 wash cycles. The mechanical properties of the structure of the valve indicated a functional resistance of decellularized ECM. The IF demonstrated the presence of basement membrane, suggesting a potential structure for host cell attachment. The RM analysis showed evidence of molecular interactions, suggesting conservation of the chemical composition, particularly among the protein molecular structures. The structural analyses performed in the semilunar porcine heart valves demonstrate that decellularized ECMS has structural properties that support physiological performance and potential host tissue integration. In fact, decellularized leaflet scaffolds were prone to cell interaction after human adipose-derived stromal cell seeding and culturing. Further analysis of biocompatibility, particularly the ECM-cell interaction, can elucidate the remodeling process, in preserved decellularized heart valve scaffold.

Spectral fingerprinting of decellularized heart valve scaffolds.

Decellularized heart valves hold promise for their use as bioscaffolds in cardiovascular surgery. Quality assessment of heart valves after decellularization processing and/or storage is time consuming and destructive. Fourier transform infrared spectroscopy (FTIR) allows rapid non-invasive assessment of biomolecular structures in tissues. In this study, IR-spectra taken from different layers of the pulmonary artery trunk and leaflet tissues of decellularized porcine heart valves were compared with those of pure collagen and elastin, the main protein components in these tissues. In addition, spectral changes associated with aging and oxidative damage were investigated. Infrared absorbance spectra of the arteria intima and media layer were found to be very similar, whereas distinct differences were observed when compared with spectra of the externa layer. In the latter, the shape of the CH-stretching vibration region (3050-2800 cm-1) resembled that of pure collagen. Also, pronounced νCOOH and amide-II bands and a relatively high content of α-helical structures in the externa layer indicated the presence of collagen in this layer. The externa layer of the artery appeared to be sensitive to collagenase treatment, whereas the media and intima layer were particularly affected by elastase and not by collagenase treatment. Protein conformational changes after treatment with collagenase were observed in all three layers. Collagenase treatment completely degraded the leaflet tissue sections. Spectra were also collected from scaffolds after 2 and 12 weeks storage at 37 °C, and after induced oxidative damage. Spectral changes related to aging and oxidative damage were particularly evident in the CH-stretching region, whereas the shape of the amide-I band, reflecting the overall protein secondary structure, remained unaltered.

Endothelial committed oral stem cells as modelling in the relationship between periodontal and cardiovascular disease.

In the present study we have mimicked, in vitro, an inflammatory process using Lipopolysaccharide derived from Porphyromonas Gingivalis (LPS-G) and human Periodontal Ligament Stem Cells induced to endothelial differentiation (e-hPDLSCs). The research project has been organized into the three following steps: i) induction of hPDLSCs toward endothelial differentiation; ii) evaluation of the molecular signaling pathway involved in the response to the LPS-G, and iii) functional response evaluation of the living construct constituted by porcine decellularized valve/e-hPDLSCs treated with LPS-G. Obtained results showed that 5 μg/ml LPS-G stimulus provokes: a slowdown of cell growth starting from 24 hr and the release of IL6, IL8, and MCP1 molecules. Signaling network analyzed showed the activation of TLR4/ NFkB/ERK1/2/p-ERK1/2 signaling mediated by MyD88 in LPS-G stimulated e-hPDLSCs, moreover a time course put in evidence a nuclear traslocation of ERK1/2 and p-ERK1/2 in differentiated samples. Following, the ability of e-hPDLSCs to expand and colonize the decellularized porcine heart valves was appraised at ultrastructural level. Considering that, the Reactive Oxygen Species (ROS) play an important role in the progression and development of cardiovascular disease (CVD), in LPS-G living construct model e-hPDLSCs/decellularized porcine heart valves (dPHV), ROS production was assessed. Time lapse experiments evidenced that LPS-G provokes in e-hPDLSCs a rapid and sustained increase in ROS generation, negligible on undifferentiated cells. From obtained data, by multiparametric analyses, a reasonable conclusion may be that the inflammation process activated by LPS-G can affect endothelial cells and could represent in vivo a possible pathological and predictor state of CVD.

Fucoidan/VEGF-based surface modification of decellularized pulmonary heart valve improves the antithrombotic and re-endothelialization potential of bioprostheses

Decellularized porcine heart valves offer promising potential as biocompatible prostheses. However, this procedure alter matrix fibres and glycans, leading to lower biomechanical resistance and increased their thrombotic potential. Therefore, their durability is limited due to calcification and weak regeneration in vivo. Surface modifications are highly requested to improve the scaffolds re-endothelialization required to restore functional and haemocompatible heart valve. Fucoidan, a natural sulphated polysaccharide, carries antithrombotic and anti-inflammatory properties and is known to enhance endothelial adhesion and proliferation when associated with vascular endothelial growth factor (VEGF). Based on these features, we constructed fucoidan/VEGF polyelectrolyte multilayer film (PEM) coated valve scaffold in an attempt to develop functional heart valve bioprosthesis. We investigated the haemocompatibility of the PEM coated valve scaffolds, the adhesion and growth potential of endothelial cells (HUVECs) in flow, as well as long term culture with stem cells. Fucoidan/VEGF PEM coated scaffolds demonstrated antithrombotic and non-calcifying properties. The PEM application increased HUVECs adhesion in flow (6 h) and HUVECs viability over time (72 h). HUVECs were well spread and aligned in flow direction. Interestingly, stem cells infiltration was improved by the PEM coating at 21 days. Thus, the fucoidan/VEGF PEM is a promising surface modification to obtain valve bioprostheses for clinical applications with increased antithrombotic and re-endothelialization potential.

109 - Preliminary Studies on hmsc Engraftment in Decellularized Porcine Heart Valve

109 - Preliminary Studies on hmsc Engraftment in Decellularized Porcine Heart Valve

Decellularized GGTA1-KO pig heart valves do not bind preformed human xenoantibodies.

Pre-clinical and clinical data have unequivocally demonstrated the usefulness of decellularized heart valve (HV) matrices implanted for HV replacement therapy. However, human donor valves applicable for decellularization are in short supply, which prompts the search for suitable alternatives, such as porcine grafts. Since decellularization might be insufficient to remove all xenoantigens, we analysed the interaction of human preformed antibodies with decellularized porcine HV in vitro to assess potential immune reactions upon implantation. Detergent-decellularized pulmonary HV from German Landrace wild-type (wt) or α1,3-galactosyltransferase knockout (GGTA1-KO) pigs were investigated by inhibition ELISA and GSL I-B4 staining to localize and quantify matrix-bound αGal epitopes, which represent the most prominent xenoantigen. Additionally, preformed human xenoantibodies were affinity purified by perfusing porcine kidneys. Binding of purified human antibodies to decellularized HV was investigated by inhibition ELISA. Furthermore, binding of human plasma proteins to decellularized matrices was determined by western blot. Decellularized human pulmonary artery served as controls. Decellularization of wt HV led to a reduction of αGal epitopes by 70%. Residual epitopes were associated with the subendothelial extracellular matrix. As expected, no αGal epitopes were found on decellularized GGTA1-KO matrix. The strongest binding of preformed human anti-pig antibodies was found on wt matrices, whereas GGTA1-KO matrices bound similar or even fewer xenoantibodies than human controls. These results demonstrate the suitability of GGTA1-KO pigs as donors for decellularized heart valves for human patients. Besides the presence of αGal antibodies on decellularized heart valves, no further preformed xenoantibodies against porcine matrix were detected in tested human sera.

Surface heparin treatment of the decellularized porcine heart valve: Effect on tissue calcification.

Tissue calcification is a major cause of failure of bioprosthetic heart valves. Aim of this study was to examine whether surface heparin treatment of the decellularized porcine heart valve reduces tissue calcification. Fresh porcine aortic heart valves were dissected as tissue discs and divided into four groups. Group A: controls without treatment, Group B: decellularization only, Group C: decellularization and glutaraldehyde cross-linking, Group D: decellularization and glutaraldehyde cross-linking followed by surface heparin treatment. After implantation in New Zealand White rabbits for 60 days, the explanted heart valve discs from the different study groups underwent a series of histological examinations as well as determination of calcium content by the methyl thyme phenol blue colorimetric method. Results of the explanted heart valve discs for the Von Kossa staining demonstrated that in Group A the heart valve tissue was the most severely stained with black color, whereas in Group D there was hardly any area that was stained black after implantation indicating the least tissue calcification. Furthermore, the inflammatory cells identified by the Hematoxylin-eosin staining appeared to be the least in Group D. The average tissue calcium content was highest in Group A (0.197 ± 0.115 μmolmg-1 ), modest in Group B (0.113 ± 0.041 μmolmg-1 ), and Group C (0.089 ± 0.049 μmolmg-1 ), and the lowest in Group D (0.019 ± 0.019 μmolmg-1 , p < 0.05). These results suggest that surface heparin treatment tends to reduce tissue calcification of the dellellularized porcine heart valve in a rabbit intramuscular implantation model. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 400-405, 2017.

Characterization of CD133 Antibody-Directed Recellularized Heart Valves.

CD133mAb conjugation (CD133-C) hastens in vivo recellularization of decellularized porcine heart valve scaffolds when placed in the pulmonary position of sheep. We now characterize this early cellularization process 4 h, 3, 7, 14, 30, or 90 days post-implantation. Quantitative immunohistochemistry identified cell types as well as changes in cell markers and developmental cues. CD133(+)/CD31(-) cells adhered to the leaflet surface of CD133-C leaflets by 3 days and transitioned to native leaflet-like CD133(-)/CD31(+) cells by 30 days. Leaflet interstitium became increasingly populated with both alpha-smooth muscle actin (αSMA) and vimentin(+) cells from 14 to 90 days post-implantation. Wnt3a, and beta-catenin proteins were expressed at early (3-14 days) but not later (30-90 days) time points. In contrast, matrix metalloproteinase-2 and periostin proteins were increasingly expressed over 90 days. Thus, early development of CD133-C constructs includes a fairly rapid transition from a precursor cell adhesion/migration/transdifferentiation phenotype to a more mature cell/native valve-like matrix metabolism phenotype.

Freeze-drying of decellularized heart valve tissues.

Decellularized xeno-antigen-depleted porcine pulmonary heart valves tissues may be used as matrix implants for patients with malfunctioning heart valves. Decellularized tissues are biological scaffolds composed of extracellular matrix components. Biological scaffolds closely resemble properties of native tissue, but lack immunogenic factors of cellular components. Decellularized heart valve scaffolds need to be stored to be readily available whenever needed. Scaffolds can be stored at reduced supra-zero temperatures, cryopreserved or freeze-dried. The advantage of freeze-drying is that it allows long-term storage at room temperature. This chapter outlines the entire process from decellularization to freeze-drying to obtain dry decellularized porcine heart valve scaffolds.

After decellularization of porcine heart valves: no non‐Gal antigeneic epitopes detectable by non conditioned human sera

BackgroundPatients that undergo heart valve replacement surgery with glutaraldehyde fixated porcine grafts do not face acute rejection as recipients of native porcine organs and tissues do, however, grafts calcify over time and fail after 10–20 years in adults and 3–4 years in children. Responsible for hyperacute and acute rejection of unfixated tissue are preformed antibodies that recognize xenoantigens. Major targets are carbohydrates like the αGal epitope or Neu5Gc linked to proteins as well as to lipids on cells and extracellular matrix. To overcome the limited availability of decellularized allogeneic heart valve grafts, which show the ability to remodel and to grow by ingrowth of autologous cells, a characteristics lacking in glutaraldehyde fixated heart valve grafts, we want to develop a porcine derived decellularized matrix that is well tolerated in humans.MethodsThe generation of such optimal porcine heart valves matrices is dependent on a successful elimination of bound xenoantigens. To quantify the amount of xenoantigens present on decellularized matrix, we established an inhibition ELISA by exposing human IgG to crushed matrix and measuring unbound IgG in an ELISA set up. High levels of measured IgG means low levels of xenoantigens present on the decelllularized matrix. To enhance the specificity of IgG tested in the ELISA, human sera were perfused through porcine kidneys, followed by intensive washing and elution of bound xenoantibodies. Total amount of IgG and αGal specific antibodies was monitored to control the purification steps. Inhibition ELISA was performed with matrices derived from Landrace pigs, GalT‐KO pigs and humans. Binding of total IgG as well as αGal specific antibodies was assayed.ResultsThe amount of total IgG binding correlates with the amount of αGal specific antibodies binding to decellularized porcine matrix indicating the presence of remaining αGal epitopes on the porcine matrix after decellularization. However, decellularized GalT‐KO pig and decellularized human matrix showed no binding of αGal specific antibodies and comparable amounts of total IgG binding.ConclusionOur results indicate that only αGal epitopes present on decellularized porcine heart valve matrixes are recognized by preformed xenoantibodies while no other xenoantigens are detected. Therefore, further evaluation focusing on induction of immunogeneic reactions has to be conducted in an in vivo model like the humanized mouse utilizing decellularized heart valve material derived from GalT‐KO pigs.

Heart valve transplantation: the urgent need for non‐immunogenic porcine heart valve matrices

Heart valve replacement is a life‐saving procedure conducted worldwide approximately 300 000 times per year. Used mechanical devices and bioprosthetic valves, however, exhibit severe drawbacks. They either request for lifelong anticoagulation therapy, or display an early failure due to calcification and stenosis. Furthermore, their use in pediatric surgery requests reoperations since these prosthesis lack the ability to grow. An optimal heart valve substitute that exhibits unlimited durability, perfect hemodynamics (no need for anticoagulation) and the capacity to grow has been identified by implantations of decellularized allogenic heart valve matrices. Such grafts are revitalized in vivo by cells of the recipient, which form a functional endothelium and a living interstitium. However, the remaining obstacle is the limited availability of human donor heart valves. Until now, xenogenic substitutes (porcine origin) failed due to acute or chronic rejection when implanted into humans as well as in the sheep model. Thus, we aim to generate a porcine derived decellularized matrix, free of immunogenic epitopes, for endogenous tissue regeneration and tissue engineering.In a first step, we developed analytical tests to quantify residual α(1,3)Gal epitopes, known to be responsible for hyper‐acute rejection reactions, and other xenoantigens detected by natural human anti‐pig antibodies, which are present on matrices treated by our standard decellularization protocol. Since extracellular matrix is insoluble with employed the inhibitory ELISA technique using the commercial available anti‐αGal antibody M86 and natural anti‐pig antibodies isolated from the serum of healthy volunteers. In brief, porcine kidneys were perfused with human plasma. Unbound antibodies were washed away and bound xenoantibodies were eluted using 3.5 M NaSCN. After dialysis against PBS antibodies were used to perform the inhibitory ELISA as follows. Native as well as decellularized heart valve tissue was crushed in liquid nitrogen and incubated with a defined amount of antibodies. Unbound antibodies were separated from matrix bound antibodies by centrifugation and quantified. M86 ELISA was performed using αGal‐BSA (Dextra) as solid antigen and HRP conjugated goat anti‐mouse IgM antibody as detection antibody. In the case of natural human anti‐pig antibodies, the total amount of human IgG was quantified using a human IgG ELISA (Mabtech).In our experiments comparing native and decellularized porcine heart valves, we found that standard decellularization removes already 70% of the αGal epitopes. In heart valves from α1,3‐galactosyltransferase KO (GalT‐KO) pigs the binding of M86 antibody is comparable to the extent as binding of M86 is found in human pulmonary artery tissue. In respect to general xenoantigens reduced binding of xenoantibodies after decellularization was detected. However, human as well as GalT‐KO pig derived tissue bind less xenoantibodies as tissue derived from normal pigs. Comparing only GalT‐KO and human tissue, the human tissue binds less xenoantibodies indicating the existence of non‐Gal antigens on GalT‐KO tissue.In conclusion, we found strong evidence that xenoantigens including αGal and non‐Gal xenoantigens are not only present on cells and cell debris but also on decellularized heart valve matrixes that are in fact insoluble extra cellular matrix proteins. Thus, decellularization causes a reduction of the antigenicity, however, the degree of this removal might be dependent on the decellularization protocol. Modification of the current decellularization protocol as well as enzymatic treatment against glycocalyx structures, which are believed to be hard candidates as xenoantigens may result in an additional reduction.

Fine structure of glycosaminoglycans from fresh and decellularized porcine cardiac valves and pericardium.

Cardiac valves are dynamic structures, exhibiting a highly specialized architecture consisting of cells and extracellular matrix with a relevant proteoglycan and glycosaminoglycan content, collagen and elastic fibers. Biological valve substitutes are obtained from xenogenic cardiac and pericardial tissues. To overcome the limits of such non viable substitutes, tissue engineering approaches emerged to create cell repopulated decellularized scaffolds. This study was performed to determine the glycosaminoglycans content, distribution, and disaccharides composition in porcine aortic and pulmonary valves and in pericardium before and after a detergent-based decellularization procedure. The fine structural characteristics of galactosaminoglycans chondroitin sulfate and dermatan sulfate were examined by FACE. Furthermore, the mechanical properties of decellularized pericardium and its propensity to be repopulated by in vitro seeded fibroblasts were investigated. Results show that galactosaminoglycans and hyaluronan are differently distributed between pericardium and valves and within heart valves themselves before and after decellularization. The distribution of glycosaminoglycans is also dependent from the vascular district and topographic localization. The decellularization protocol adopted resulted in a relevant but not selective depletion of galactosaminoglycans. As a whole, data suggest that both decellularized porcine heart valves and bovine pericardium represent promising materials bearing the potential for future development of tissue engineered heart valve scaffolds.

Recellularization of aortic valves in pigs

Decellularized porcine heart valves treated with deoxycholic acid (DOA) have demonstrated complete recellularization and absence of calcification when implanted into the pulmonary position in sheep. We studied recellularization and calcification in stented DOA-treated heart valves compared with conventional stented glutaraldehyde-treated valves in the aortic position in juvenile pigs 6 months after implantation. DOA heart valves (n=12) and glutaraldehyde-treated valves (Carpentier-Edwards) (n=15) were implanted into the aortic position in 8-month old 90 kg female pigs. Six months postoperatively, the valves were explanted and subjected to gross pathology examination, high-resolution (HR) X-ray imaging, and histological evaluation. Five DOA valves and five glutaraldehyde-treated valves were explanted after 6 months. Fourteen animals died before follow-up because of non-valve related causes and three because of infective endocarditis. Gross pathologic examination showed all DOA valves to be well functioning with only minor thrombotic depositions located mostly in the commissural area. Three glutaraldehyde valves had limited thrombosis and two had severe thrombosis. HR X-ray imaging demonstrated almost complete absence of cusp calcification in the DOA valves, but severe calcification in all glutaraldehyde valves. Overgrowth of endothelial cells and ingrowth of fibroblasts in the stent-adjacent area and basal part of the cusps were seen in all DOA valves, but not in glutaraldehyde valves. Immunohistochemistry revealed larger amounts of inflammatory cells in all glutaraldehyde valves compared with DOA valves. DOA-treated heart valves demonstrated greater recellularization and less calcification compared with standard glutaraldehyde-treated valves 6 months after implantation in the aortic position in pigs. DOA-treated heart valves demonstrated less calcification compared with standard glutaraldehyde-treated valves by qualitative analysis. Endothelial and fibroblast recellularization of the cusps was only observed in DOA-treated valves.

Quercetin-crosslinked porcine heart valve matrix: Mechanical properties, stability, anticalcification and cytocompatibility

Bioprosthetic heart valves, prepared by glutaraldehyde (GA) crosslinking, have some limitations due to poor durability, calcification and immunogenic reactions. The aim of this study was to evaluate the crosslinking effect of a natural product, quercetin, on decellularized porcine heart valve extracellular matrix (ECM). After crosslinking, the mechanical properties, stability, anticalcification and cytocompatibility were examined. The results showed that the tensile strength of quercetin-crosslinked ECM was higher than that of GA-crosslinked ECM. After crosslinking with quercetin, the thermal denaturation temperature of ECM was clearly increased. Quercetin-crosslinked ECM could be stored in D-Hanks solution for at least 30 days without any loss of ultimate tensile strength and elasticity. After soaking in D-Hanks solution for 36 days, there was only 11.55% non-crosslinked excess quercetin released and no further release thereafter. Cell culture study shows that no inhibition on proliferation of vascular endothelial cells occurred when the quercetin concentration was lower than 1 μg ml −1. This non-cytotoxic concentration was 100 times higher than that of GA. The resistibility of quercetin-crosslinked ECM to in vitro enzymatic hydrolysis was comparable to that of GA-crosslinked ECM. An in vitro anticalcification experiment showed that quercetin crosslinking could protect ECM from deposition of minerals in simulated body fluid. The present study demonstrated that quercetin can crosslink porcine heart valve ECM effectively, which suggests that quercetin might be a new crosslinking reagent for the preparation of bioprosthetic heart valve xenografts and scaffolds for heart valve tissue engineering.

IgG deposition and activation of the classical complement pathway involvement in the activation of human granulocytes by decellularized porcine heart valve tissue

Decellularization treatment of heart valves has been thought to eliminate tissue immunogenicity. Early failure of tissue-engineered xenogeneic heart valves was seen in children and has been a major drawback in this promising field of research. This study was designed to characterize the effects of acellular porcine heart valve tissue on immune activation in vitro. Incubation of decellularized porcine tissue with human plasma led to adsorption of IgG, activation of the classical complement pathway and adhesion of activated polymorphonuclear leukocytes (PMN). This inflammatory response was strongly inhibited by proteins extracted from native porcine tissue which might indicate that inhibitors of PMN activation present in the extracellular matrix (ECM) are lost during the decellularization process.

475: Treatment of Decellularized Porcine Heart Valve Tissue with Porcine Native Proteins Prevents Granulocyte Adhesion and Activation

This study was designed to investigate the activation of the complement system during contact with decellularized porcine heart valve tissue, its influence on neutrophil activation as well as the modulating effects of native porcine protein extracts.