不同浓度GO对GelMA机械性能及生物相容性的影响

doi:10.19439/j.sjos.2022.05.008

上海口腔医学 ›› 2022, Vol. 31 ›› Issue (5): 491-496.doi: 10.19439/j.sjos.2022.05.008

不同浓度GO对GelMA机械性能及生物相容性的影响

鲍菁^1,*, 秦尉^2,*, 朱青^3#, 钱文昊^1#

1.上海市徐汇区牙病防治所,上海 200032;
2.上海交通大学附属第九人民医院口腔修复科,上海交通大学口腔医学院,国家口腔医学中心, 国家口腔疾病临床医学研究中心,上海市口腔医学重点实验室,上海 200011;
3.上海和睦家医院,上海 200336

收稿日期:2021-02-25 修回日期:2021-05-11 出版日期:2022-10-25 发布日期:2022-11-01
通讯作者: 朱青,E-mail: jane_zhu1988@126.com;钱文昊,E-mail：pingyanlaoto@163.com。^#共同通信作者
作者简介:鲍菁(1990-),女,硕士,主治医师,E-mail：baojing9523@163.com;秦尉(1989-),女,博士,E-mail：827946040@qq.com。^*并列第一作者
基金资助:
徐汇区医学科研项目（SHXH201739）

Enhanced mechanical properties, cytocompatibility of GelMA hydrogels by incorporating graphene oxide

BAO Jing¹, QIN Wei², ZHU Qing³, QIAN Wen-hao¹

1. Shanghai Xuhui District Dental Center. Shanghai 200032;
2. Department of Prosthodontics, Shanghai Ninth People's Hospital, Shanghai Jiao Tong University School of Medicine; National Center for Stomatology; College of Stomatology, Shanghai Jiao Tong University; National Clinical Research Center for Oral Diseases; Shanghai Key Laboratory of Stomatology. Shanghai 200011;
3. Shanghai United Family Hospital. Shanghai 200336, China

Received:2021-02-25 Revised:2021-05-11 Online:2022-10-25 Published:2022-11-01

摘要/Abstract

摘要： 目的: 采用光固化技术合成掺杂氧化石墨烯（graphene oxide, GO）的甲基丙烯酸化明胶（methacrylated gelatin,GelMA）3D凝胶,评价其机械强度和生物相容性。方法: 将GelMA和50、100、200 μg/mL GO混合后紫外光(ultravioletray, UV)固化,使用扫描电镜(scanning electron microscope,SEM)观察水凝胶结构,万能测试仪压力实验计算弹性模量,CCK-8及死/活细胞染色检测大鼠骨髓源性间充质干细胞（rat bone marrow-derived mesenchymal stem cells, rBMSC）的增殖活性。采用SPSS 23.0软件包对数据进行统计学分析。结果: GelMA/GO复合凝胶具有高度多孔结构。加入GO可提高GelMA的机械性能,GelMA/100 μg组及GelMA/200 μg 组弹性模量显著增强, GelMA/100 μg组吸水率增加,GelMA/200 μg组体积膨胀率减小。当GO浓度为50 μg/mL时,rBMSCs黏附与增殖能力最强（P<0.05）;当GO浓度≥100 μg/mL时,rBMSCs的活性降低。结论: 合适浓度的GO可提高GelMA的机械性能和生物相容性。鉴于优先考虑生物性,建议50 μg/mL GO/GelMA 用于骨组织工程。

关键词: 光固化水凝胶, 纳米材料, 机械性能, 生物相容性

Abstract: PURPOSE: To construct graphene oxide/methacrylated gelatin(GO/GelMA) hydrogel and to investigate its mechanical property and biocompatibility. METHODS: 50, 100, 200 μg/mL GO was added to GelMA and mixed thoroughly. The micromorphology of hydrogels was observed under scanning electron microscope(SEM). Compression text was used to assess lastic modulus, CCK-8 and live/dead cell staining was conducted to assess the viability of rat bone marrow-derived mesenchymal stem cells (rBMSCs). The data were analyzed using SPSS 23.0 software package. RESULTS: SEM showed a highly porous structure of the hydrogel. After adding GO, the elastic modulous increased (100, 200 μg/mL), swelling ratio increased(100 μg/mL) and expansion ratio decreased(200 μg/mL). The viability increased in 50 μg/mL GO and decreased in 100 and 200 μg/mL GO. CONCLUSIONS: Proper concentration of GO can increase the mechanical property and biocompatibility. 50 μg/mL GO/GelMA was suggested in bone tissue engineering given priority to biocompatibility.

Key words: Phote-cure hydrogel, Nanomaterial, Mechanical property, Biocompatibility

中图分类号:

R783.1

鲍菁, 秦尉, 朱青, 钱文昊. 不同浓度GO对GelMA机械性能及生物相容性的影响[J]. 上海口腔医学, 2022, 31(5): 491-496.

BAO Jing, QIN Wei, ZHU Qing, QIAN Wen-hao. Enhanced mechanical properties, cytocompatibility of GelMA hydrogels by incorporating graphene oxide[J]. Shanghai Journal of Stomatology, 2022, 31(5): 491-496.

参考文献

[1] Young S, Wong M, Tabata Y, et al.Gelatin as a delivery vehicle for the controlled release of bioactive molecules[J]. J Control Release, 2005, 109(1-3): 256-274.
[2] Van Den Bulcke AI, Bogdanov B, De Rooze N, et al. Structural and rheological properties of methacrylamide modified gelatin hydrogels[J]. Biomacromolecules, 2000, 1(1): 31-38.
[3] Sun M, Sun X, Wang Z, et al. Synthesis and properties of gelatin methacryloyl (GelMA) hydrogels and their recent applications in load-bearing tissue[J]. Polymers (Basel), 2018, 10(11): 1290.e1-1290.e20.
[4] Schuurman W, Levett PA, Pot MW, et al.Gelatin-methacrylamide hydrogels as potential biomaterials for fabrication of tissue-engineered cartilage constructs[J]. Macromol Biosci, 2013, 13(5): 551-561.
[5] Lee BH, Lum N, Seow LY, et al. Synthesis and characterization of types A and B gelatin methacryloyl for bioink applications[J]. Materials (Basel), 2016, 9(10): 797.e1-797.e13.
[6] Pepelanova I, Kruppa K, Scheper T, et al.Gelatin-methacryloyl (GelMA) hydrogels with defined degree of functionalization as a versatile toolkit for 3D cell culture and extrusion bioprinting[J]. Bioengineering (Basel), 2018, 5(3): 55-70.
[7] Celikkin N, Mastrogiacomo S, Jaroszewicz J, et al.Gelatin methacrylate scaffold for bone tissue engineering: the influence of polymer concentration[J]. J Biomed Mater Res A, 2018, 106(1): 201-209.
[8] Shadjou N, Hasanzadeh M, Khalilzadeh B.Graphene based scaffolds on bone tissue engineering[J]. Bioengineered, 2018, 9(1): 38-47.
[9] Compton OC, Nguyen ST.Graphene oxide, highly reduced graphene oxide, and graphene: versatile building blocks for carbon-based materials[J]. Small, 2010, 6(6): 711-723.
[10] Cha C, Shin SR, Gao X, et al.Controlling mechanical properties of cell-laden hydrogels by covalent incorporation of graphene oxide[J]. Small, 2014, 10(3): 514-523.
[11] Mamaghani KR, Naghib SM, Zahedi A, et al.GelMa/PEGDA containing graphene oxide as an IPN hydrogel with superior mechanical performance[J]. Mater Today Proc, 2018, 5(7): 15790-15799.
[12] Wei C, Liu Z, Jiang F, et al.Cellular behaviours of bone marrow-derived mesenchymal stem cells towards pristine graphene oxide nanosheets[J]. Cell Prolif, 2017, 50(5): e12367.
[13] Kang S, Park JB, Lee TJ, et al.Covalent conjugation of mechanically stiff graphene oxide flakes to three-dimensional collagen scaffolds for osteogenic differentiation of human mesenchymal stem cells[J]. Carbon, 2015,83: 162-172.
[14] Qin W, Wang C, Jiang C, et al.Graphene oxide enables the reosteogenesis of previously contaminated titanium in vitro[J]. J Dent Res, 2020, 99(8): 922-929.
[15] Shirahama H, Lee BH, Tan LP, et al. Precise tuning of facile one-pot gelatin methacryloyl (GelMA) synthesis[J]. Sci Rep, 2016, 6: 31036.e1-31036.e11.
[16] Shin SR, Bae H, Cha JM, et al.Carbon nanotube reinforced hybrid microgels as scaffold materials for cell encapsulation[J]. ACS Nano, 2012, 6(1): 362-372.
[17] Engler AJ, Sen S, Sweeney HL, et al.Matrix elasticity directs stem cell lineage specification[J]. Cell, 2006,126(4): 677-689.
[18] Purohit SD, Bhaskar R, Singh H, et al.Development of a nanocomposite scaffold of gelatin-alginate-graphene oxide for bone tissue engineering[J]. Int J Biol Macromol, 2019, 133: 592-602.
[19] Kim J, Kim YR, Kim Y, et al.Graphene-incorporated chitosan substrata for adhesion and differentiation of human mesenchymal stem cells[J]. J Mater Chem B, 2013, 1(7): 933-938.
[20] Qiu Y, Wang Z, Owens AC, et al.Antioxidant chemistry of graphene-based materials and its role in oxidation protection technology[J]. Nanoscale, 2014, 6(20): 11744-11755.
[21] Zhang W, Yan L, Li M, et al.Deciphering the underlying mechanisms of oxidation-state dependent cytotoxicity of graphene oxide on mammalian cells[J]. Toxicol Lett, 2015, 237(2): 61-71.
[22] Choe G, Oh S, Seok JM, et al.Graphene oxide/alginate composites as novel bioinks for three-dimensional mesenchymal stem cell printing and bone regeneration applications[J]. Nanoscale, 2019, 11(48): 23275-23285.

不同浓度GO对GelMA机械性能及生物相容性的影响

Enhanced mechanical properties, cytocompatibility of GelMA hydrogels by incorporating graphene oxide

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 5

编辑推荐

Metrics

本文评价

[1]	张耀升, 张锴, 陈欣慰, 牟海彰, 丁旺旺, 秦明礼, 张善勇, 龚勤林, 陈刚, 徐伟峰, 虞科恩, 姜艳梅. 3D打印个体化钛网的机械力学性能及生物相容性分析[J]. 上海口腔医学, 2020, 29(3): 250-256.
[2]	林瑞, 郁春华, 孙健. 用于三维打印咬合板的聚碳酸酯材料性能研究[J]. 上海口腔医学, 2019, 28(5): 467-471.
[3]	陆小丽，缪惠灵，柳锋，高美琴. PLGA/鱼皮胶原共轭静电纺丝膜生物相容性分析[J]. 上海口腔医学, 2018, 27(3): 244-247.
[4]	吴金双, 邢鹤琳, 董超芳, 郭天文, 杨瑟飞. 使用FUS-invest锆系牙科纯钛包埋料提高铸件的物理机械性能及精度[J]. 上海口腔医学, 2017, 26(2): 139-145.
[5]	陈武, 王韦玮, 时新站, 陈宁. 脱细胞真皮基质作为屏障膜的细胞相容性及细胞封闭性的体外研究[J]. 上海口腔医学, 2013, 22(3): 260-264.