Zixian Liu, Meng Li, Rong Cheng, Lijing Wang, Peiyi Hou, Lu Han, Shengbo Sang
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引用次数: 0
摘要
血管化是构建功能三维组织所面临的关键问题,对组织构建移植的长期存活和稳定性至关重要。本研究成功制备了一种可光固化的水凝胶材料羧甲基壳聚糖(CHIMA),并与甲基丙烯酰明胶(GelMA)结合构建了生物链接凝胶/CHIMA,随后利用3D打印技术制备了具有诱导血管生成功能的生物活性支架。结果表明,交联的GelMA/ china生物链具有支持细胞生长和代谢的多孔结构。掺入china可显著提高生物链的亲水性、溶胀率、耐压性和机械强度。GelMA/ china bioink支持支架中人脐静脉内皮细胞(HUVECs)的存活和持续增殖。其中,由8 wt% GelMA和2 wt% china组成的生物链接可以刺激血管生成基因的表达。3D打印的生物活性支架支持HUVECs的存活,并且具有丰富的CD31和VEGF蛋白沉积。因此,本研究构建了具有血管生成诱导功能的生物活性支架,为构建血管化复杂组织提供了一种可行的策略。
3D Printed GelMA/CHIMA Cross-Linked Network Hydrogel for Angiogenesis
Vascularization is a key issue facing the construction of functional three-dimensional (3D) tissues, which is critical for the long-term survival and stability of tissue construct transplantation. In this study, a photocurable hydrogel material carboxymethyl chitosan (CHIMA) was successfully prepared and integrated with methacryloyl gelatin (GelMA) to construct the bioink GelMA/CHIMA, which was subsequently used 3D printing technology to prepared a bioactive scaffold with angiogenesis-inducing functionality. The results showed that the cross-linked GelMA/CHIMA bioink had a porous structure that supported cell growth and metabolism. The incorporation of CHIMA could significantly improve the hydrophilicity, swelling rate, pressure resistance and mechanical strength of the bioink. GelMA/CHIMA bioink supported the survival and continued proliferation of human umbilical vein endothelial cells (HUVECs) in the scaffold. In particular, the bioink composed of 8 wt% GelMA and 2 wt% CHIMA could stimulate the expression of angiogenesis genes. 3D printed bioactive scaffolds supported the survival of HUVECs and had abundant protein deposition including CD31 and VEGF. Therefore, this study constructed a bioactive scaffold with angiogenesis induction function, which provides a feasible strategy for the construction of vascularized complex tissues.
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