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pH敏感性可注射型醛基瓜尔豆胶-托普霉素自愈抗菌水凝胶及其性质()

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《南京师范大学学报》（自然科学版）[ISSN:1001-4616/CN:32-1239/N]

卷:: 第43卷
期数:: 2020年02期

页码:: 34-42

栏目:: ·化学·

出版日期:: 2020-05-30

文章信息/Info

Title:: Injectable pH-sensitive Antibacterial Hydrogel Based onAldehyde-Guar and Tobramycin and Its Properties

文章编号:: 1001-4616(2020)02-0034-09

作者:: 程淼¹; 王怀生¹; 程霜²; (1.聊城大学化学化工学院,山东聊城 252000)(2.聊城大学农学院,山东聊城 252000)

Author(s):: Cheng Miao¹; Wang Huaisheng¹; Cheng Shuang²; (1.College of Chemistry and Chemical Engineering,Liaocheng University,Liaocheng 252000,China)(2.College of Agriculture,Liaocheng University,Liaocheng 252000,China)

关键词:: 醛基瓜尔豆胶; 托普霉素; 水凝胶; 流变学; 可注射; 自愈; pH敏感性; 抗菌活力

Keywords:: aldehyde-guar; tobramycin; composite hydrogel; rheological characteristics; injectable; self-healing; pH-sensitive; antibacterial activity

分类号:: TS201.7

DOI:: 10.3969/j.issn.1001-4616.2020.02.007

文献标志码:: A

摘要:: 微生物感染是当今严重危害人类健康、威胁人类安全的公共卫生问题之一,有效抑制微生物感染特别是抑制其耐药性是当今研究热点,抗生素水凝胶作为一种新型生物响应医学材料,能实现缓释靶位给药,达到清除微生物的目的. 本研究以氧化瓜尔豆胶作为生物兼容性好的可降解天然多糖为骨架,通过席夫碱反应(可逆亚胺键)接枝托普霉素制备了一种可自愈、原位注射成型的酸敏性抗菌水凝胶,并研究了它们的流变学、自愈能力、可注射性、pH响应性、生物相容性和体外抗菌性能. 结果表明,凝胶能负载相当量的托普霉素,凝胶具有优异的自愈性能、良好的切稀和可注射性,呈现酸敏给药模式. 扫描电镜显示所得水凝胶成多孔网络结构,适合药物、细胞或生物大分子的运载,适于微创抗感染治疗手术的实施,具有潜在的应用价值.

Abstract:: Microbial infection is one of the underlying causes of death in the world,which imposes the threat to the public health. To fight against infection and overcome the resistance of microbial has drawn great research interest in materials science and engineering. Polymer hydrogels based on antibiotics have been highly pursued due to the excellent antimicrobial ability,biocompatibility,biodegradability and negligible toxicity. The stimuli-responsive characteristic,bio-inspired functions and rheological properties of the hydrogel which was facilely prepared simply by fabricating aldehyde-guar gum and tobramycin in situ deposition,with its antibacterial ability against E.coli and cytocompatiblility were extensively uated in this paper. The results reveal that the smart injectable self-healing hydrogel prepared through the dynamic Schiff base possesses satisfactory rheological properties and sufficient drug loading capability,which presents a self-healing acid sensitive tobramycin sustained release profile after inject in situ and can be used as a practical platform for drug-delivery with distinct applications of antimicrobial. The composite hydrogel is exceptionally propitious to accelerate treatment potential of infection for its porous microstructure,it also is the appropriate biocarrier for cell,drug and macromolecules delivery in the biomedical field.

参考文献/References:

[1] SUNDIN G W,CASTIBLANCO L F,YUAN X C,et al. Bacterial disease management:challenges,experience,innovation and future prospects[J]. Molecular plant pathology,2016,17(9):1506-1518.
[2]O’HARA L M,THOM K A,PREAS M A. Update to the centers for disease control and prevention and the healthcare infection control practices advisory committee guideline for the prevention of surgical site infection(2017):a summary,review,and strategies for implementation[J]. American journal of infection control,2018,46(6):602-609.
[3]BRUSSOW H. Infection therapy:the problem of drug resistance and possible solutions[J]. Microbial biotechnology,2017,10(5):1041-1046.
[4]WENCEWICZ T A. New antibiotics from Nature’s chemical inventory[J]. Bioorganic medicinal chemistry,2016,24(24):6227-6252.
[5]HOQUE J,BHATTACHARJEE B,PRAKASH R G,et al. Dual function injectable hydrogel for controlled release of antibiotic and local antibacterial therapy[J]. Biomacromolecules,2018,19(2):267-278.
[6]PAL A,VERNON B L,NIKKHAH M. Therapeutic neovascularization promoted by injectable hydrogels[J]. Bioactive materials,2018,3(4):389-400.
[7]NASITHA I A,KRISHNAKUMAR K,DINESHKUMAR B. Hydrogel in pharmaceuticals:a review[J]. Indo American journal of pharmaceutical sciences,2016,3(3):265-270.
[8]PARHI R. Cross-linked hydrogel for pharmaceutical applications:a review[J]. Advanced pharmaceutical bulletin,2017,7(4):515-530.
[9]AHMAD M,RAI S M,MAHMOOD A. Hydrogel microparticles as an emerging tool in pharmaceutical field:a review[J]. Advances in polymer technology,2016,35(2):121-128.
[10]DOUGLAS T E L,DZIADEK M,SCHIETSE J,et al. Pectin-bioactive glass self-gelling,injectable composites with high antibacterial activity[J]. Carbohydrate polymer,2019,205:427-436.
[11]ZHANG H H,NIE W,WANG H K,et al. Preparation and experimental dust suppression performance characterization of a novel guar gum-modification-based environmentally-friendly degradable dust suppressant[J]. Powder technology,2018,339:314-325.
[12]LIU Y,HSU S H. Synthesis and biomedical applications of self-healing hydrogels[J]. Frontiers in chemistry,2018,6:00449.
[13]VIDAL C A G,PAWLIK M. Molecular weight effects in interactions of guar gum with talc[J]. International journal of mineral processing,2015,138:38-43.
[14]PRABAHARAN M. Prospective of guar gum and its derivatives as controlled drug delivery systems[J]. International journal of biological macromolecules,2011,49(2):117-124.
[15]梁耀东,陈创前,李步南. 妥布霉素对刚果红的褪色反应及其分析应用[J]. 西安科技大学学报,2013,33(1):96-100.
[16]陈咏梅,董坤,刘振齐,等. 高强度双网络高分子水凝胶:性能、进展及展望[J]. 中国科学:技术科学,2012,42(8):859-873.
[17]LIU H C,SUI X F,XU H,et al. Self-healing polysaccharide hydrogel based on dynamic covalent enamine bonds[J]. Macromolecular materials & engineering,2016,301(6):725-732.
[18]ZHANG Y L,YANG B,XU L X,et al. Self-healing hydrogels based on dynamic chemistry and their biomedical applications[J]. Acta chimica sinica,2013,71(4):485-492.
[19]LAKES A L,PEYYALA R,EBERSOLE J L,et al. Synthesis and characterization of an antibacterial hydrogel containing covalently bound vancomycin[J]. Biomacromolecules,2014,15(8):3009-3018.

备注/Memo

备注/Memo:: 收稿日期:2019-09-06.
基金项目:国家自然科学基金项目(21375055).
通讯联系人:王怀生,教授,研究方向:生物电分析化学. E-mail:hswang@lcu.edu.cn; 程霜,教授,研究方向:食品与药物安全. E-mail:chengshuang@lcu.edu.cn

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更新日期/Last Update: 2020-05-15