内皮祖细胞和去细胞猪主动脉瓣构建组织工程瓣膜的研究

目的将内皮祖细胞(EPCs)诱导分化为内皮细胞后种植在去细胞猪主动脉瓣膜(APV)上,以期为组织工程瓣膜(TEHV)的研制提供一个新的思路。方法采用去垢剂联合胰蛋白酶法去除猪主动脉瓣膜细胞。采用密度梯度离心法从羊骨髓中分离出EPCs,并诱导分化后,免疫组织化学染色鉴定。将诱导分化得到内皮细胞种植到APV上。采用光镜和电镜检测猪主动脉瓣膜的去细胞效果。对内皮细胞在APV上的生长效果进行观察。结果猪主动脉瓣内的细胞完全去除。EPCs经定向诱导后,具有表达CD-31,CD-34,von Willebrand因子等内皮细胞特征。诱导分化后的EPCs可以在APV表面黏附生长,并且表达CD-31和yon Willebrand因子。结论EPCs可以定向诱导分化为内皮细胞并可以在APV上种植生长。     

Study on decellularized porcine aortic valve/poly (3-hydroxybutyrate-co-3-hydroxyhexanoate) hybrid heart valve in sheep model

To overcome shortcomings of current heart valve prostheses, novel hybrid valves were fabricated from decellularized porcine aortic valves coated with poly (3-hydroxybutyrate-co-3-hydroxyhexanoate [PHBHHx]). In the mechanical test in vitro, the biomechanical performance of hybrid valve was investigated. In an in vivo study, hybrid valve conduits were implanted in pulmonary position in sheep without cardiopulmonary bypass. Uncoated grafts were used as control. The valves were explanted and examined histologically and biochemically 16 weeks after surgery. The hybrid valve conduits maintained original shapes, were covered by a confluent layer of cells, and had less calcification than uncoated control. The mechanical test in vitro revealed that PHBHHx coating improved tensile strength. The results in vivo indicated that PHBHHx coating reduced calcification and promoted the repopulation of hybrid valve with the recipient's cells resembling native valve tissue. The hybrid valve may provide superior valve replacement with current techniques.     

Evaluation of kangaroo aortic valved conduits in a juvenile sheep model: preliminary findings

BACKGROUND: Biological heart valve substitutes, manufactured from either porcine or bovine tissue, have been in use for more than 30 years. Despite low thrombogenicity and excellent performance, bioprosthetic heart valves tend to degenerate and calcify early in young patients because of patient and valve related factors. The aim of this study was to examine the calcification behavior of glutaraldehyde-preserved kangaroo heart valves in a juvenile sheep model. METHODS: Porcine (n = 10) and kangaroo (n = 10) valved conduits were implanted in the descending aortic position of juvenile sheep and retrieved after 6, 8, and 12 months. Retrieved valved conduits were examined for morphological changes and calcification of the valve tissue, using Von Kossa's stain technique and atomic absorption spectrophotometry. RESULTS: Structural valve deterioration, characterized by increased stiffness and severe calcification, occurred in 100% of the porcine conduits within 4 months. Kangaroo valve leaflets were significantly (p < 0.001) less calcified at 6 months (3.39+/-1.80 microg/mg), 8 months (5.86+/-4.57 microg/mg), and at 12 months (14.38+/-6.72 microg/mg), compared to porcine valves at 3 months (176.45+/-42.88 microg/mg ) and at 4 months (154.67+/-52.67 microg/mg ). Porcine aortic wall tissue was more calcified (118.24+/-42.86 microg/mg) than kangaroo aortic wall tissue (79.55+/-26.40 microg/mg). CONCLUSIONS: Kangaroo heart valves calcify less than porcine heart valves. These findings suggest that a different donor valve tissue has a lower calcification potential probably due to a difference in the morphological ultrastructure. This could result in improved long-term durability of kangaroo heart valves.     

Valved jugular vein segments for right ventricular outflow tract reconstruction in young sheep

OBJECTIVE: This study was undertaken to investigate the degeneration and calcification of valved bovine jugular vein segments for right ventricular outflow tract reconstruction in juvenile sheep. METHODS: Seven valved bovine jugular vein conduits (Contegra model 220; VenPro Corporation, Irvine, Calif) and 3 control conduits (MH100; Medtronic, Inc, Minneapolis, Minn) were implanted in the pulmonary artery in young sheep. After 20 weeks the conduits were explanted and qualitatively analyzed by epicardial echocardiography, gross examination, x-ray analysis, light microscopy, and transmission electron microscopy. Calcification was determined quantitatively by flame atomic absorption spectrometry. RESULTS: Two Contegra conduits could not be analyzed because of endocarditis. All other Contegra conduits functioned well, with preserved structure and minimal calcification. The control MH100 conduits exhibited extensive fibrous sheathing, with calcification of the aortic wall portion and the commissural part of the Hancock valve. CONCLUSIONS: The Contegra conduit's performance was clearly superior to that of the control MH100 conduit when implanted in the pulmonary artery position in juvenile sheep for 5 months.     

Tissue-engineered bioprosthetic venous valve: a long-term study in sheep.

OBJECTIVE: to develop a graft bearing an immunologically tolerated tissue-engineered venous valve (TE graft) that will be incorporated into a native vessel, and restore normal valve function for the treatment of chronic venous insufficiency. METHODS: twenty-four TE grafts were grown using decellularised allogeneic ovine veins as donor matrix, which was subsequently repopulated with the future recipient's myofibroblasts (MFB) and endothelial cells (EC). TE grafts were implanted into the external jugular vein. Animals were sacrificed at 1, 6, and 12 weeks (n=4, each). Autografts served as controls (1 week, n=4; 6 weeks, n=4). Specimen for histology and immunohistochemistry were taken. RESULTS: the matrix was successfully repopulated with MFB and EC (n=8). Patency on venography in the TE graft-group was44,44, and 34 at 1, 6, and 12 weeks, and44 (44) in autografts at 1 (6) weeks, respectively. Except for 2 TE grafts after 12 weeks, valves were competent (duplex ultrasound). Patent TE grafts were merely distinguishable from autografts with minor inflammatory reactions. Reflux was caused by neo-intima formation related to the basis of the TE graft. CONCLUSION: acellularisation and consecutive in vitro autogeneic re-seeding of valved venous conduits can lead to immunologically acceptable, patent, and competent implants in sheep.     

去细胞猪主动脉瓣叶的获取和内皮细胞的种植

目的　探讨猪主动脉瓣叶去细胞后作为组织工程心脏瓣膜支架的可行性。　方法　经胰酶 - EDTA、表面活性剂和核酸酶处理 ,去除猪主动脉瓣叶的细胞成分 ,测定瓣叶去细胞前、后的生物力学特性 ,并在其表面种植新生牛主动脉内皮细胞 (BAECs) ;分别行大鼠皮下包埋实验。　结果　猪主动脉瓣叶中的细胞成分能完全去除 ,获得完整无细胞的纤维网状支架 ,断裂强度和断裂伸长率无明显变化 ;种植的 BAECs在去细胞瓣叶表面可形成一层连续的细胞层 ,其分泌前列环素 (PGI2 )的能力同直接种植在 2 4孔板中的比较 ,差异无统计学意义 (P>0 .0 5 )。　结论　猪主动脉瓣去细胞后获得的纤维支架可以用来构建组织工程瓣膜 ,适宜于血管内皮细胞的生长。     

Ross operation with a tissue-engineered heart valve

BACKGROUND: The Ross procedure has gained increasing acceptance due to excellent hemodynamic results by replacing the diseased aortic valve with the viable autologous pulmonary valve. Consequently, the right ventricular outflow tract (RVOT) has to be reconstructed. In this report a viable heart valve was created from decellularized cryopreserved pulmonary allograft that was seeded with viable autologous vascular endothelial cells (AVEC). METHODS: A 43-year-old patient suffering from aortic valve stenosis underwent a Ross operation on May 20, 2000, using a tissue engineered (TE) pulmonary allograft to reconstruct the RVOT. Four weeks before the operation a piece of forearm vein was harvested to separate, culture, and characterize AVEC. Follow-up was completed at discharge, 3, 6, and 12 months postoperatively by clinical evaluation, transthoracic echocardiography (TTE), and magnetic resonance imaging (MRI). Additionally, at 1-year follow-up a multislice computed tomographic scan was performed. RESULTS: After four weeks of culturing 8.34 x 10(6) AVEC were available to seed a 27-mm decellularized pulmonary allograft. Trypan blue staining confirmed 96.0% viability. Reendothelialization rate after seeding was 9.0 x 10(5) cells/cm2. TTE and MRI revealed excellent hemodynamic function of the TE heart valve and the neoaortic valve as well. Multislice computed tomography revealed no evidence of valvular calcification. CONCLUSIONS: After 1 year of follow-up the patient is in excellent condition without limitation and exhibits normal aortic and pulmonary valve function.     

Biomatrix/polymer composite material for heart valve tissue engineering

Background

Decellularized extracellular matrix has been suggested as a scaffold for heart valve tissue engineering or direct implantation. However, cell removal impairs the physical properties of the valve structure and exposes bare collagen fibers that are highly thrombogenic. Matrix/polymer hybrid valves with improved biological and mechanical characteristics may be advantageous.

Methods

Porcine aortic valves were decellularized enzymatically and impregnated with biodegradable poly(hydroxybutyrate) by a stepwise solvent exchange process. Biocompatibility was tested in vitro using cell proliferation and coagulation assays. Proinflammatory activity was assessed in vivo by implantation of matrix/polymer patches in the rabbit aorta. Biomechanic valve properties and fluid dynamics were tested in a pressure/flow-controlled pulse duplicating system. Matrix/polymer hybrid valves were implanted in pulmonary and aortic position in sheep.

Results

Biocompatibility assays indicated that human blood vessel cells survive and proliferate on matrix/polymer hybrid tissue. In vitro activation of cellular and plasmatic coagulation cascades was lower than with uncoated control tissue. After implantation in the rabbit aorta, matrix/polymer hybrid patches healed well, with complete endothelialization, mild leukocyte infiltration, and less calcification than control tissue. Matrix/polymer hybrid tissue had superior tensile strength and suture retention strength, and hybrid valves showed good fluid dynamic performance. The two valves in aortic position performed well, with complete endothelialization and limited inflammatory cell invasion after 12 weeks. Of the two valves in pulmonary position, one failed.

Conclusions

Matrix/polymer hybrid tissue valves have good biological and biomechanic characteristics and may provide superior replacement valves.     

Clinical pulmonary autograft valves: pathologic evidence of adaptive remodeling in the aortic site

OBJECTIVE: We studied the pathologic features, cellular phenotypes, and matrix remodeling of clinical pulmonary-to-aortic valve transplants functioning up to 6 years. METHODS: Nine autografts and associated vascular walls early (2-10 weeks) and late (3-6 years) postoperatively were examined by using routine morphologic methods and immunohistochemistry. In 4 cases autograft and homograft cusps were obtained from the same patients. RESULTS: Autografts had near-normal trilaminar cuspal structure and collagen architecture and viable valvular interstitial and endothelial cells throughout the time course. In contrast, cusps of homografts used to replace the pulmonary valves in the same patients were devitalized. In early autograft explants, 19.3% +/- 2.4% of cuspal interstitial cells were myofibroblasts expressing alpha-actin. In contrast, myofibroblasts comprised only 6.0% +/- 1.1% of cells in late explants and 2.5% +/- 0.4% and 4.6% +/- 0.8% of cells in normal pulmonary and aortic valves, respectively (P <.05). In early autografts only 12.0% +/- 4.6% of endothelial cells expressed the systemic arterial endothelial cell marker EphrinB2, whereas later explants had 85.6% +/- 5.4% of endothelial cells expressing EphrinB2 (P <.05). In early autografts 43.8% +/- 8.8% of interstitial cells expressed metalloproteinase 13, whereas late autografts had 11.4% +/- 2.7% of interstitial cells expressing matrix metalloproteinase 13 (P <.05). Collagen content in autografts was comparable with that of normal valves and was higher than that seen in homograft valves (P <.005). However, autograft walls were damaged, with granulation tissue (early) and scarring, with focal loss of normal smooth muscle cells, elastin, and collagen (late). CONCLUSIONS: The structure of pulmonary valves transplanted to the systemic circulation evolved toward that of normal aortic valves. Key processes in this remodeling included onset of a systemic endothelial cell phenotype and reversible plasticity of fibroblast-like valvular interstitial cells to myofibroblasts.     

Cell characterization of porcine aortic valve and decellularized leaflets repopulated with aortic valve interstitial cells: the VESALIO Project (Vitalitate Exornatum Succedaneum Aorticum Labore Ingenioso Obtenibitur)

BACKGROUND: Heart valve bioprostheses for cardiac valve replacement are fabricated by xeno- or allograft tissues. Decellularization techniques and tissue engineering technologies applied to these tissues might contribute to the reduction in risk of calcification and immune response. Surprisingly, there are few data on the cell phenotypes obtained after cellularizing these naturally-derived biomaterials in comparison to those expressed in the intact valve. METHODS: Aortic valve interstitial cells (VIC) were used to repopulate the corresponding valve leaflets after a novel decellularization procedure based on the use of ionic and nonionic detergents. VIC from leaflet microexplants at the third passage were utilized to repopulate the decellularized leaflets. Intact, decellularized and repopulated valve leaflets and cultured VIC were examined by immunocytochemical procedures with a panel of antibodies to smooth muscle and nonmuscle differentiation antigens. Intact and cellularized leaflets were also investigated with Western blotting and transmission electron microscopy, respectively. RESULTS: Myofibroblasts and smooth muscle cells (SMC) were mostly localized to the ventricularis of the leaflet whereas fibroblasts were dispersed unevenly. Cultured VIC were comprised of myofibroblasts and fibroblasts with no evidence of endothelial cells and SMC. Two weeks after VIC seeding into decellularized leaflets, grafted cells were found penetrating the bioscaffold. The immunophenotypic and ultrastructural properties of the grafted cells indicated that a VIC heterogeneous mesenchymal cell population was present: fibroblasts, myofibroblasts, SMC, and endothelial cells. CONCLUSIONS: VIC seeding on detergent-treated valve bioscaffolds has the cellular potential to reconstruct a viable aortic valve.     

Glutaraldehyde-Fixed Bovine Iliac Veins Used as Bioprosthetic Conduits: An Experimental Animal Study

The ideal prosthetic conduit for surgical repair of complex congenital heart disease has yet to be found. Twenty conduits were implanted between the right ventricle and pulmonary artery in growing sheep as follows: four Dacron porcine valve conduits (mean time in place, 142 days); four avalved glutaraldehyde-fixed bovine iliac veins (mean 132 days); and 12 glutaraldehyde-fixed bovine iliac veins containing a porcine valve (mean 180 days). Fifteen conduits were left in place from 167 to 244 days (mean 204 days), and five were explanted earlier (mean 54 days). Pathological study included gross, x-ray, histological, and ultrastructural investigation. Five conduits failed because of infective endocarditis. The valved Dacron conduits showed significant tissue ingrowth and calcification of the valve graft. The valved bovine iliac veins presented calcification at the valve level and vein wall, as well as a valvelike calcific fibrous ridge at the proximal anastomosis with the right ventricle. The avalved bovine iliac veins also presented calcific deposits along the wall and a valvelike calcific ridge at the ventricular anastomosis. Histological and ultrastructural studies of the vein tunica media revealed the phenomena of inflammatory rejection and foreign body reaction with loss of smooth muscle cells (medionecrosis) and fibrotic replacement. In conclusion, bovine iliac veins undergo inflammation with medionecrosis indicating that smooth muscle cell antigenicity is not attenuated by glutaraldehyde fixation.     

Tissue engineering of heart valves in vivo using bone marrow-derived cells

In this study, we tissue-engineered heart valves in vivo using autologous bone marrow-derived cells (BMCs). Canine BMCs were differentiated into endothelial cell (EC)-like cells and myofibroblast (MF)-like cells. Decellularized porcine pulmonary valves were seeded with BMCs and implanted to abdominal aorta and pulmonary valve of bone marrow donor dogs. Histological examination of the explants identified the regeneration of valvular structures expressing CD31 and smooth muscle alpha-actin, indicating the presence of EC-like and MF-like cells in the grafts at 3 and 1 week, respectively, after implantation. Fluorescent microscopic examinations identified the presence of fluorescently labeled cells in the explants, indicating that the implanted BMCs survived and participated in the heart valve reconstitution. This study reports, for the first time, on tissue engineering of heart valve in vivo using BMCs.     

去细胞猪主动脉瓣移植于犬腹主动脉内构建组织工程瓣

目的 探讨在犬腹主动脉内构建组织工程心脏瓣膜的实验方法。方法 将预种犬血管间质细胞和内皮细胞的去细胞猪主动脉瓣叶(猪瓣),移植于6条犬的腹主动脉内,于术后4,6,8和10周对移植瓣叶进行形态、组织结构及免疫组化染色观察。结果 (1)移植术后4周时瓣叶周边有多层细胞长入,新细胞外基质形成,原支架组织部分吸收。(2)10周末猪瓣组织完全吸收,为宿主细胞及新合成的细胞外基质取代。基质中间质细胞主要为成纤维细胞和肌纤维母细胞。细胞外基质成分主要为Ⅰ、Ⅲ型胶原和少量弹力纤维,并含有中性和酸性黏多糖。(3)内皮细胞覆盖于瓣叶表面。结论 (1)移植于犬腹主动脉内的去细胞猪瓣于移植术后10周末基本构成组织工程瓣叶;(2)腹主动脉内异位移植是一种可供选择的实验研究方法。     

Progression of aortic valve stenosis: TGF-beta1 is present in calcified aortic valve cusps and promotes aortic valve interstitial cell calcification via apoptosis

BACKGROUND: Aortic valve stenosis characteristically progresses due to cuspal calcification, often necessitating valve replacement surgery. The present study investigated the hypothesis that TGF-beta1, a cytokine that causes calcification of vascular smooth muscle cells in culture, initiates apoptosis of valvular interstitial cells as a mechanistic event in cuspal calcification. METHODS: Noncalcified and calcified human aortic valve cusps were obtained at autopsy or at the time of cardiac surgery. The distributions within cusps of TGF-beta1, latent-TGF-beta1-associated peptide, and TGF-beta receptors were studied using immunohistochemistry. The effects of TGF-beta1 on mechanistic events contributing to aortic valve calcification were also investigated using sheep aortic valve interstitial cell (SAVIC) cultures. RESULTS: Immunohistochemistry studies revealed that calcific aortic stenosis cusps characteristically contained within the extracellular matrix qualitatively higher levels of TGF-beta1 than noncalcified cusps. Noncalcified normal valves demonstrated only focal intracellular TGF-beta1. Addition of TGF-beta1 to SAVIC cultures led to a cascade of events, including: cellular migration, aggregation, formation of apoptotic-alkaline phosphatase enriched nodules, and calcification of these nodules. The time course of these events in the SAVIC culture system was rapid with nodule formation with apoptosis by 72 hours, and calcification after 7 days. Furthermore, ZVAD-FMK, an antiapoptosis agent (caspase inhibitor), significantly inhibited calcification and apoptosis induced by TGF-beta1, but had no effect on nodule formation. However, cytochalasin D, an actin-depolymerizing agent, inhibited nodule formation, but not calcification. CONCLUSIONS: TGF-beta1 is characteristically present within calcific aortic stenosis cusps, and mediates the calcification of aortic valve interstitial cells in culture through mechanisms involving apoptosis.     

Is there a possibility for a glutaraldehyde-free porcine heart valve to grow?

OBJECTIVE: A challenging issue is to create a heart valve with growth and remodeling potential, which would be of great interest for congenital heart valve surgery. This study was performed to evaluate the growth and remodeling potentials of a decellularized heart valve. METHODS: In 4 juvenile sheep (age 12 +/- 1 weeks) with a weight of 24.3 +/- 4.4 kg, a 17-mm diameter decellularized porcine valve was implanted as pulmonary valve replacement. Valve growth was evaluated by transthoracic echocardiography. At explantation, valves were evaluated by gross examination, light microscopy (hematoxylin and eosin, von Kossa, Sirius red, Weigert and Gomori staining), electron microscopy and immunohistochemistry. Atomic absorption spectrometry was performed to evaluate calcium content. RESULTS: All animals showed fast recovery. The mean follow-up was 9.0 +/- 1.8 months. All sheep at least doubled their weight (54.3 +/- 9.2 kg). Echocardiography showed no regurgitation and a flow velocity of 0.7 +/- 0.1 m/s at the latest follow-up. The valve diameter increased from 17.6 +/- 0.5 to 27.5 +/- 2.1 mm (p < 0.018). Gross examination showed a similar wall thickness of the implanted valve and native pulmonary wall, with smooth and pliable leaflets. Histology showed a monolayer of endothelial cells, fibroblast ingrowth and production of new collagen. No calcification was seen at von Kossa staining, confirmed by low calcium content levels of the valve wall and leaflets at atomic absorption spectrometry. CONCLUSIONS: This glutaraldehyde-free heart valve showed not only the absence of calcification, but also remodeling and growth potential.     

Severe Covid-19 and acute pulmonary hypertension: 24-month follow-up regarding mortality and relationship to initial echocardiographic findings and biomarkers

Introduction

Critically ill Covid-19 patients are likely to develop the sequence of acute pulmonary hypertension (aPH), right ventricular strain, and eventually right ventricular failure due to currently known pathophysiology (endothelial inflammation plus thrombo-embolism) that promotes increased pulmonary vascular resistance and pulmonary artery pressure. Furthermore, an in-hospital trans-thoracic echocardiography (TTE) diagnosis of aPH is associated with a substantially increased risk of early mortality. The aim of this retrospective observational follow-up study was to explore the mortality during the 1–24-month period following the TTE diagnosis of aPH in the intensive care unit (ICU).

Methods

A previously reported cohort of 67 ICU-treated Covid-19 patients underwent an electronic medical chart-based follow-up 24 months after the ICU TTE. Apart from the influence of aPH versus non-aPH on mortality, several TTE parameters were analyzed by the Kaplan–Meier survival plot technique (K-M). The influence of biomarkers for heart failure (NTproBNP) and myocardial injury (Troponin-T), taken at the time of the ICU TTE investigation, was analyzed using receiver-operator characteristics curve (ROC) analysis.

Results

The overall mortality at the 24-month follow-up was 61.5% and 12.8% in group aPH and group non-aPH, respectively. An increased relative mortality risk continued to be present in aPH patients (14.3%) compared to non-aPH patients (5.6%) during the 1–24-month period. The easily determined parameter of a tricuspid valve regurgitation, allowing a measurement of a systolic pulmonary artery pressure (regardless of magnitude), was associated with a similar K-M outcome as the generally accepted diagnostic criteria for aPH (systolic pulmonary artery pressure >35 mmHg). The biomarker values of NTproBNP and Troponin-T at the time of the TTE did not result in any clinically useful ROC analysis data.

Conclusion

The mortality risk was increased up to 24 months after the initial examination in ICU-treated Covid-19 patients with a TTE diagnosis of aPH, compared to non-aPH patients. Certain individual TTE parameters were able to discriminate 24-month risk of morality.     

具有防移位设计的可压缩性肺动脉支架瓣膜动物置入手术及体内测试

目的 探讨具有防移位设计的可压缩性肺动脉支架瓣膜的防移位效果.方法 将带瓣牛颈静脉缝在3个"Z"字型镍钛合金支架上,制作成喇叭口型肺动脉支架瓣膜.非体外循环下用推送器将其经右心室置入羊肺动脉瓣位置(n=6),分别于术后早期、术后2个月采用右心导管、心脏彩超、血流动力学测定、大体病理等方法评价置入瓣膜的位置和功能.结果 6只羊支架瓣膜均在正确位置释放.超声、右心导管造影以及血流动力学检查显示,术后早期、术后2个月置入瓣膜支架固定好,无移位,1例瓣膜收缩期跨瓣压差24 mm Hg,1例瓣膜轻度关闭不全,其他瓣膜功能良好.结论 喇叭口型支架有助于防止瓣膜移位.