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对甲基丙烯酸化明胶和酪胺共轭八臂聚乙二醇的打印水凝胶进行酶促后交联,以制备互穿三维网络结构。

Enzymatic post-crosslinking of printed hydrogels of methacrylated gelatin and tyramine-conjugated 8-arm poly(ethylene glycol) to prepare interpenetrating 3D network structures.

作者信息

Liang Jia, Wang Zhule, Poot Andreas A, Grijpma Dirk W, Dijkstra Piet J, Wang Rong

机构信息

Department of Neurosurgery, Stroke Center, Henan Provincial People's Hospital, 450003, Henan, China.

Department of Biomaterials Science and Technology, University of Twente, Drienerlolaan 5, 7522 NB Enschede, The Netherlands.

出版信息

Int J Bioprint. 2023 May 11;9(5):750. doi: 10.18063/ijb.750. eCollection 2023.

DOI:10.18063/ijb.750
PMID:37457933
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10339421/
Abstract

Methacrylated gelatin (GelMA) has been intensively studied as a 3D printable scaffold material in tissue regeneration fields, which can be attributed to its well-known biological functions. However, the long-term stability of photo-crosslinked GelMA scaffolds is hampered by a combination of its fast degradation in the presence of collagenase and the loss of physical crosslinks at higher temperatures. To increase the longer-term shape stability of printed scaffolds, a mixture of GelMA and tyramine-conjugated 8-arm PEG (8PEGTA) was used to create filaments composed of an interpenetrating network (IPN). Photo-crosslinking during filament deposition of the GelMA and subsequent enzymatic crosslinking of the 8PEGTA were applied to the printed 3D scaffolds. Although both crosslinking mechanisms are radical based, they operate without interference of each other. Rheological data of bulk hydrogels showed that the IPN was an elastic hydrogel, having a storage modulus of 6 kPa, independent of temperature in the range of 10 - 40°C. Tensile and compression moduli were 110 kPa and 80 kPa, respectively. On enzymatic degradation in the presence of collagenase, the gelatin content of the IPN fully degraded in 7 days, leaving a stable secondary crosslinked 8PEGTA network. Using a BioMaker bioprinter, hydrogels without and with human osteosarcoma cells (hMG-63) were printed. On culturing for 21 days, hMG-63 in the GelMA/8PEGTA IPN showed a high cell viability (>90%). Thus, the presence of the photoinitiator, incubation with HO, and mechanical forces during printing did not hamper cell viability. This study shows that the GelMA/8PEGTA ink is a good candidate to generate cell-laden bioinks for extrusion-based printing of constructs for tissue engineering applications.

摘要

甲基丙烯酸化明胶(GelMA)作为一种可用于3D打印的支架材料,在组织再生领域受到了广泛研究,这得益于其众所周知的生物学功能。然而,光交联的GelMA支架的长期稳定性受到其在胶原酶存在下快速降解以及在较高温度下物理交联丧失的共同影响。为了提高打印支架的长期形状稳定性,将GelMA与酪胺共轭的8臂聚乙二醇(8PEGTA)混合,以制备由互穿网络(IPN)组成的细丝。在GelMA细丝沉积过程中进行光交联,随后对打印的3D支架进行8PEGTA的酶交联。尽管两种交联机制都是基于自由基的,但它们彼此之间互不干扰。本体水凝胶的流变学数据表明,IPN是一种弹性水凝胶,储能模量为6 kPa,在10 - 40°C范围内与温度无关。拉伸模量和压缩模量分别为110 kPa和80 kPa。在胶原酶存在下进行酶降解时,IPN中的明胶成分在7天内完全降解,留下稳定的二次交联8PEGTA网络。使用BioMaker生物打印机打印了不含和含有人类骨肉瘤细胞(hMG - 63)的水凝胶。培养21天后,GelMA/8PEGTA IPN中的hMG - 63显示出较高的细胞活力(>90%)。因此,光引发剂的存在、与HO的孵育以及打印过程中的机械力均未影响细胞活力。本研究表明,GelMA/8PEGTA墨水是一种很好的候选材料,可用于生成含细胞的生物墨水,用于基于挤出的组织工程应用构建体打印。

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