[1]杜伟斌,沈福祥,杨亚冬,等.黄芪多糖-胶原-海藻酸钠-丝素蛋白3D打印支架的制备及其生物相容性研究[J].中国中医骨伤科杂志,2022,30(01):1-4.
 DU Weibin,SHEN Fuxiang,YANG Yadong,et al.Study of Preparation and Biocompatibility of Astragalus Polysaccharide-Collagen-Sodium Alginate-Silk Fibroin 3D Printing Scaffolds[J].Chinese Journal of Traditional Medical Traumatology & Orthopedics,2022,30(01):1-4.
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黄芪多糖-胶原-海藻酸钠-丝素蛋白3D打印支架的制备及其生物相容性研究()
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《中国中医骨伤科杂志》[ISSN:1005-0205/CN:42-1340/R]

卷:
第30卷
期数:
2022年01期
页码:
1-4
栏目:
实验研究
出版日期:
2022-01-15

文章信息/Info

Title:
Study of Preparation and Biocompatibility of Astragalus Polysaccharide-Collagen-Sodium Alginate-Silk Fibroin 3D Printing Scaffolds
文章编号:
1005-0205(2022)01-0001-04
作者:
杜伟斌1沈福祥1杨亚冬2陈荣良1华爱兰1王拓1曹国平1
1浙江中医药大学附属江南医院(杭州市萧山区中医院)骨科(杭州,311201) 2浙江省医学科学院组织工程研究所(杭州医学院)
Author(s):
DU Weibin1SHEN Fuxiang1YANG Yadong2CHEN Rongliang1HUA Ailan1WANG Tuo1CAO Guoping1
1Department of Orthopedics,Jiangnan Hospital Affiliated to Zhejiang Chinese Medical University,Hangzhou 311201,China; 2Institute of Tissue Engineering,Zhejiang Province Academy of Medical Sciences,Hangzhou 310013,China.
关键词:
黄芪多糖 胶原 海藻酸钠 丝素蛋白 支架材料 医用敷料
Keywords:
astragalus polysaccharide collagen sodium alginate silk fibroin protein scaffold material medical dressings
分类号:
R-3
文献标志码:
A
摘要:
目的:应用3D打印技术制备黄芪多糖-胶原-海藻酸钠-丝素蛋白复合支架,分析其生物相容性。方法:2020年8月至2020年12月,采用MTT法分析HeLa细胞增殖抑制率,选择黄芪多糖最适工作浓度区间; 制备黄芪多糖-胶原-海藻酸钠-丝素蛋白3D打印支架,进行形态学观察。通过细胞共培养显微镜观察、Calcein-AM/PI活死细胞双染、扫描电镜等比较,分析其生物相容性。结果:50 μg/mL浓度黄芪多糖对细胞增殖抑制程度较低,且可促进细胞增殖。3D打印支架孔径大小一致,间距统一,厚薄均匀。细胞共培养5 d后,向支架内部迁移,呈团簇状生长。染色可见细胞生长良好,无明显的细胞死亡现象。扫描电镜下可见丰富的细胞黏附在支架上,细胞间有突触相连。结论:胶原-海藻酸钠-丝素蛋白含黄芪多糖(工作浓度25~400 μg/mL)的3D打印支架性能最佳,可为创面修复、软组织退肿等医用敷料的应用提供新思路。
Abstract:
Objective:To prepare astragalus polysaccharide-collagen-sodium alginate-silk fibroin 3D printing scaffolds and study its biocompatibility.Methods:From August 2020 to December 2020,the proliferation inhibition rate of HeLa cells was analyzed by MTT assay to select the optimal working concentration range of APS.Astragalus polysaccharide-collagen-sodium alginate-silk fibroin 3D printing scaffolds were prepared for morphological observation,and the biocompatibility was analyzed by cell co-culture microscopy,double staining of dead cells with Calcein-AM/PI and scanning electron microscopy.Results:Astragalus polysaccharide(50 μg/mL)had a low inhibitory efficacy on cell proliferation and promoted cell proliferation.The 3D printing bracket had uniform aperture size,spacing and thickness.After 5 d later of co-culture,the cells migrated to the inside of the scaffold and grew in clusters.Staining showed that the cell growth was well,and there was no obvious cell death.Scanning electron microscopy showed there were abundant cells adhesion on the scaffold and synaptic connection between cells.Conclusion:The 3D printing scaffolds with collagen-alginate-silk fibroin protein containing astragalus polysaccharide(working concentration 25 to 400 μg/mL)had the best performance,which can provide a new idea for the application of medical dressings such as wound repair and soft tissue swelling reduction.

参考文献/References:

[1] DU W,HE L,WANG L,et al.Experimental vascular protective shield combined with vacuum sealing drainage prevents pressure on exposed vessels and accelerates wound repair[J].Ann Palliat Med,2020,9(5):3059-3069.
[2] SU L,ZHENG J,WANG Y,et al.Emerging progress on the mechanism and technology in wound repair[J].Biomed Pharmacother,2019,117:109191.
[3] DU W,BAO G,HU H,et al.An mRNA sequencing analysis of the healing-promoting role of electroacupuncture a in rat skin wound model[J].Ann Palliat Med,2020,9(4):1462-1475.
[4] LI X,QU L,DONG Y,et al.A review of recent research progress on the astragalus genus[J].Molecules,2014,19(11):18850-18880.
[5] HAN R,TANG F,LU M,et al.Astragalus polysaccharide ameliorates H2O2-induced human umbilical vein endothelial cell injury[J].Mol Med Rep,2017,15(6):4027-4034.
[6] 胡兴峰,李青松,季亮,等.Ⅰ型胶原蛋白生物膜在损伤肌腱内源性愈合过程中的作用[J].局解手术学杂志,2021,30(2):103-107.
[7] 徐海伦,满振涛,李伟.丝素蛋白生物支架在骨组织工程中的应用[J].中国矫形外科杂志,2020,28(23):2165-2169.
[8] 舒华金,吴春萱,杨康,等.快速膨胀海藻酸钠/二氧化硅纤维复合支架的制备及其快速止血功能的应用[J].材料工程,2019,47(12):124-129.
[9] 卞徽宁,孙传伟,陈华德,等.虎杖苷对成纤维细胞生物学特性的影响[J].中国组织工程研究,2012,16(33):6111-6115.
[10] OBAGI Z,DAMIANI G,GRADA A,et al.Principles of wound dressings:a review[J].Surg Technol Int,2019,35:50-57.
[11] CHADWICK P,OUSEY K.Bacterial-binding dressings in the management of wound healing and infection prevention:a narrative review[J].J Wound Care,2019,28(6):370-382.
[12] 刘嘉鑫,安丽萍,贾耀飞,等.壳聚糖表面改性钛合金材料的研究进展[J].中国骨伤,2020,33(12):1175-1178.
[13] 杨国辉,丁丽青,方艳,等.纳米银抗菌敷料治疗糖尿病足创面感染的效果[J].中华医院感染学杂志,2021,31(10):1562-1565.
[14] 邓金星,林君德,邓飞扬.纳米银医用抗菌敷料、康复新液与湿润烧伤膏联合应用治疗Ⅳ期压疮的疗效分析[J].中国烧伤创疡杂志,2020,32(4):245-247.
[15] WANG C,CAO X,ZHANG Y.A novel bioactive osteogenesis scaffold delivers ascorbic acid,β-glycerophosphate,and dexamethasone in vivo to promote bone regeneration[J].Oncotarget,2017,8(19):31612-31625.
[16] KIM B S,AHN M,CHO W W,et al.Engineering of diseased human skin equivalent using 3D cell printing for representing pathophysiological hallmarks of type 2 diabetes in vitro[J].Biomaterials,2021,272:120776.
[17] DAIKUARA L Y,YUE Z L,SKROPETA D,et al.In vitro characterisation of 3D printed platelet lysate-based bioink for potential application in skin tissue engineering[J].Acta Biomater,2021,123:286-297.
[18] SHERA S S,BANIK R M.Development of tunable silk fibroin/xanthan biopolymeric scaffold for skin tissue engineering using L929 fibroblast cells[J].Journal of Bionic Engineering,2021:103-117.DOI:10.1007/S42235-021-0004-4.
[19] 陈珍玉,张小宁,罗钰昕,等.丝素蛋白/姜黄素复合膜敷料促进皮肤创面愈合的评价[J].中国组织工程研究,2021,25(16):2554-2561.

备注/Memo

备注/Memo:
基金项目:国家自然科学基金青年基金(81904053)
浙江省医药卫生科技计划项目(2020KY796,2020KY797)
杭州市萧山区社会发展重大科技计划项目(11216,2019318)
更新日期/Last Update: 2022-01-18