Ghazanfari Samaneh, Driessen-Mol Anita, Sanders Bart, Dijkman Petra E, Hoerstrup Simon P, Baaijens Frank P T, Bouten Carlijn V C
1 Department of Biomedical Engineering, Eindhoven University of Technology , Eindhoven, The Netherlands .
2 Clinics for Cardiovascular Surgery and Swiss Centre for Regenerative Medicine, University and University Hospital Zürich , Zürich, Switzerland .
Tissue Eng Part A. 2015 Aug;21(15-16):2206-15. doi: 10.1089/ten.TEA.2014.0417. Epub 2015 Jul 14.
Decellularized tissue-engineered heart valves (TEHVs) are under investigation as alternative for current heart valve prostheses with the potential to rapidly repopulate with cells within the body. Ideally, these valves are stented for transapical or minimally invasive delivery. It is unclear if and how the matrix of these valves remodels under in vivo hemodynamic loading conditions and in the presence of a stent. Here, we study the evolution of collagen orientation and tissue maturation in the wall of stented decellularized TEHVs with time after implantation.
In a previous study, stented TEHVs based on rapidly degrading scaffolds were cultured in bioreactors, decellularized, and transapically implanted as pulmonary valve replacement in sheep. In the present study, collagen (re)orientation in the initially isotropic valvular wall was assessed using a fluorescent collagen probe combined with confocal imaging and image analysis of explanted tissue at 8, 16, and 24 weeks following implantation. Collagen tortuosity or waviness in the explants, as a measure of matrix maturity, was quantified using a Gabor wavelet method and compared with tortuosity in native sheep vascular wall tissue. Results indicate that on the luminal side of the valvular wall, fibers became aligned in circumferential direction, while tortuosity increased with implantation time, showing striking similarities with the native collagen structure after 24 weeks. On the outside of the wall, where the engineered tissue touches the stent, collagen fibers in the vicinity of the struts aligned along the struts, whereas collagen fibers in between struts were randomly oriented. Immunohistochemistry was performed to evaluate the presence of elastin and collagen type I and III. After 8 weeks, collagen types I and III were mostly present at the luminal side of the wall, whereas at 16 and 24 weeks, a homogenous distribution of collagen I and III was observed throughout the wall. Elastin was mostly expressed at the luminal side after 24 weeks. Biochemical assays showed that the amount of DNA (as a measure of cell number) increased significantly after 8 and 24 weeks, glycosaminoglycans increased significantly after 8, 16, and 24 weeks, and hydroxyproline, as a measure of collagen amount, increased significantly after 24 weeks compared to the controls.
The collagen matrix in the wall of decellularized TEHVs shows clear structural remodeling and maturation with time. While collagen orientation rapidly remodels toward a native anisotropic architecture on the luminal side of the engineered valvular wall, it is dominated and guided by stent geometry on the outer side of the wall. Collagen tortuosity was increased with implantation time and was accompanied by an increase in elastin, especially on the luminal side of the vessel.
去细胞组织工程心脏瓣膜(TEHV)正在作为当前心脏瓣膜假体的替代品进行研究,其有可能在体内迅速重新填充细胞。理想情况下,这些瓣膜带有支架,可经心尖或微创方式输送。目前尚不清楚这些瓣膜的基质在体内血流动力学负荷条件下以及存在支架的情况下是否会发生重塑以及如何重塑。在此,我们研究植入后带支架的去细胞TEHV壁中胶原蛋白取向和组织成熟度随时间的演变。
在先前的一项研究中,基于快速降解支架的带支架TEHV在生物反应器中培养、去细胞,然后经心尖植入绵羊体内作为肺动脉瓣置换物。在本研究中,使用荧光胶原蛋白探针结合共聚焦成像和对植入后8周、16周和24周时取出组织的图像分析,评估初始各向同性瓣膜壁中胶原蛋白的(重新)取向。使用Gabor小波方法对取出物中的胶原蛋白曲折度或波纹度进行量化,作为基质成熟度的指标,并与天然绵羊血管壁组织中的曲折度进行比较。结果表明,在瓣膜壁的腔面,纤维沿圆周方向排列,而曲折度随植入时间增加,在24周后与天然胶原蛋白结构显示出惊人的相似性。在壁的外侧,即工程组织与支架接触处,支柱附近的胶原蛋白纤维沿支柱排列,而支柱之间的胶原蛋白纤维随机取向。进行免疫组织化学以评估弹性蛋白以及I型和III型胶原蛋白的存在情况。8周后,I型和III型胶原蛋白主要存在于壁的腔面,而在16周和24周时,观察到I型和III型胶原蛋白在整个壁中均匀分布。24周后弹性蛋白主要在腔面表达。生化分析表明,DNA量(作为细胞数量的指标)在8周和24周后显著增加,糖胺聚糖在8周、16周和24周后显著增加,与对照组相比,作为胶原蛋白量指标的羟脯氨酸在24周后显著增加。
去细胞TEHV壁中的胶原蛋白基质随时间显示出明显的结构重塑和成熟。虽然工程瓣膜壁腔面的胶原蛋白取向迅速重塑为天然各向异性结构,但在壁的外侧,它受支架几何形状的主导和引导。胶原蛋白曲折度随植入时间增加,并伴随着弹性蛋白的增加,尤其是在血管腔面。
