Tissue Engineering Group, Department of Materials Engineering, Islamic Azad University Najafabad Branch, Isfahan, Iran.
Biomaterials Nanotechnology and Tissue Engineering faculty, School of Advanced Medical Technology, Isfahan University of Medical Sciences, Isfahan, Iran.
J Biomed Mater Res A. 2021 Dec;109(12):2673-2684. doi: 10.1002/jbm.a.37259. Epub 2021 Jul 6.
Plasma surface modification is one of the new methods for improving the surface properties of the scaffold and accelerating tissue regeneration. The aim of this study was to create poly glycerol sebacate/poly lactic acid (PGS/PLA) composite scaffold by electrospun method and modified the scaffold by oxygen plasma for use as a vascular graft. Plasma surface modified PGS/PLA scaffold morphology study showed relatively uniform fibers with an average diameter of 637 ± 149.4 nm and porosity of 82%. The mechanical evaluation of the PGS/PLA scaffold showed properties close to the natural vessels. Atomic force microscopy images exhibited an increase in the roughness of the scaffold after plasma surface modification; however, hemocompatibility studies revealed that it had no adverse effect on blood compatibility. Wettability studies revealed the superhydrophilic property of the modified scaffold (contact angle near to zero). Besides, the human umbilical vein endothelial cells proliferation and adhesion were improved significantly. Obtaining mechanical properties near to the natural vessels due to the suitable composition and significant improvement in blood compatibility and cell growth make the modified PGS/PLA composite a suitable candidate for vascular tissue regeneration.
等离子体表面改性是改善支架表面性能和加速组织再生的新方法之一。本研究旨在通过静电纺丝法制备聚甘油癸二酸酯/聚乳酸(PGS/PLA)复合支架,并通过氧等离子体对支架进行改性,用作血管移植物。等离子体表面改性的 PGS/PLA 支架形态研究表明,纤维相对均匀,平均直径为 637±149.4nm,孔隙率为 82%。PGS/PLA 支架的力学评价表明其性能接近天然血管。原子力显微镜图像显示,等离子体表面改性后支架的粗糙度增加;然而,血液相容性研究表明,它对血液相容性没有不良影响。润湿性研究表明,改性支架具有超亲水性(接触角接近零)。此外,人脐静脉内皮细胞的增殖和黏附明显改善。由于合适的组成和血液相容性以及细胞生长的显著改善,获得了接近天然血管的力学性能,使得改性 PGS/PLA 复合材料成为血管组织再生的合适候选材料。
