Augustine Robin, Nethi Susheel Kumar, Kalarikkal Nandakumar, Thomas Sabu, Patra Chitta Ranjan
School of Nano Science and Technology, National Institute of Technology Calicut, Kozhikode, Kerala 673601, India.
J Mater Chem B. 2017 Jun 28;5(24):4660-4672. doi: 10.1039/c7tb00518k. Epub 2017 May 23.
Electrospun polycaprolactone (PCL) tissue engineering scaffolds have been developed and used for a wide range of tissue engineering applications, where successful incorporation and conservation of the therapeutic activity of the embedded nanoparticles into scaffolds is critically needed for effective tissue engineering. Incorporation of pro-angiogenic nanomaterials to promote vascularization is a novel approach. Our group has well-demonstrated the potent pro-angiogenic properties of europium hydroxide nanorods (EHNs) using in vitro and in vivo systems. In the present study, electrospun PCL tissue engineering scaffolds containing EHNs were fabricated and characterized for various morphological and physico-chemical properties. Furthermore, biological studies showed enhanced cell growth and a greater density of endothelial cells grown on the scaffolds incorporated with EHNs (PCL-EHNs). The PCL-EHNs also exhibited good hemo-compatibility towards blood cells. Fluorescence microscopy and SEM observations showed good endothelial cell adhesion over these scaffolds. The PCL-EHNs demonstrated augmented growth of blood vessels in an in vivo chick embryo angiogenesis model. Furthermore, protein expression studies illustrated promoted angiogenesis of HUVECs on scaffolds in a VEGFR2/Akt mediated signaling cascade. Together, the above observations strongly suggest potent applications of EHN-incorporated PCL scaffolds in promoting angiogenesis/vascularization and their effective use in tissue engineering and vascular disease therapy.
静电纺聚己内酯(PCL)组织工程支架已被开发并用于广泛的组织工程应用中,在这些应用中,为了实现有效的组织工程,迫切需要将嵌入的纳米颗粒的治疗活性成功整合并保留在支架中。掺入促血管生成纳米材料以促进血管化是一种新方法。我们的团队已经使用体外和体内系统充分证明了氢氧化铕纳米棒(EHNs)具有强大的促血管生成特性。在本研究中,制备了含有EHNs的静电纺PCL组织工程支架,并对其各种形态和物理化学性质进行了表征。此外,生物学研究表明,在掺入EHNs的支架(PCL-EHNs)上生长的细胞生长增强,内皮细胞密度更高。PCL-EHNs对血细胞也表现出良好的血液相容性。荧光显微镜和扫描电镜观察表明,这些支架上的内皮细胞粘附良好。PCL-EHNs在体内鸡胚血管生成模型中显示出血管生长增加。此外,蛋白质表达研究表明,在VEGFR2/Akt介导的信号级联反应中,支架上的人脐静脉内皮细胞(HUVECs)的血管生成得到促进。综上所述,上述观察结果强烈表明,掺入EHN的PCL支架在促进血管生成/血管化方面具有强大的应用潜力,并且在组织工程和血管疾病治疗中具有有效的用途。
