第43卷第8期
               ·1184 ·                           南 京    医 科 大 学 学         报                        2023年8月


                   electrowriting on human bone marrow stem cell osteogene⁃  Janus nanofiber［J］. J Mater Chem B，2022，10（5）：765-778
                   sis［J］. Biomed Mater，2019，14（6）：065016       ［27］ KIRAN A S K，KUMAR T S S，SANGHAVI R，et al. Anti⁃
             ［16］BUJ⁃CORRAL I，TEJO⁃OTERO A. 3D printing of bioinert  bacterial and bioactive surface modifications of titanium
                   oxide ceramics for medical applications［J］. J Funct Bio⁃  implants by PCL/TiO 2 nanocomposite coatings［J］. Nano⁃
                   mater，2022，13（3）：155                              materials，2018，8（10）：860
             ［17］ DONG Z，WU Y，WANG Q，et al. Reinforcement of elec⁃  ［28］ YUAN Q，ZHANG Q，XU X，et al. Development and char⁃
                   trospun membranes using nanoscale Al 2O3 whiskers for  acterization of novel orthodontic adhesive containing PCL⁃
                   improved tissue scaffolds［J］. J Biomed Mater Res A，  gelatin⁃AgNPs fibers［J］. J Funct Biomater，2022，13（4）：
                   2012，100（4）：903-910                               303
             ［18］ LEE J Y，PARK J Y，HONG I P，et al. 3D⁃printed barrier  ［29］ SOLTANI DEHNAVI S，MEHDIKHANI M，RAFIENIA
                   membrane using mixture of polycaprolactone and beta⁃tri⁃  M，et al. Preparation and in vitro evaluation of polycapro⁃
                   calcium phosphate for regeneration of rabbit calvarial de⁃  lactone/PEG/bioactive glass nanopowders nanocomposite
                   fects［J］. Materials（Basel），2021，14（12）：3280       membranes for GTR/GBR applications［J］. Mater Sci Eng
             ［19］ BHATTACHARYA R，MUKHERJEE P. Biological prop⁃       C Mater Biol Appl，2018，90：236-247
                   erties of“naked”metal nanoparticles［J］. Adv Drug Deliv  ［30］ PEDROSA M C G，DOS ANJOS S A，MAVROPOULOS E，
                   Rev，2008，60（11）：1289-1306                         et al. Structure and biological compatibility of polycapro⁃
             ［20］ QIAN Y，ZHOU X，ZHANG F，et al. Triple PLGA/PCL       lactone/zinc⁃hydroxyapatite electrospun nanofibers for tis⁃
                   scaffold modification including silver impregnation，colla⁃  sue regeneration［J］. J Bioact Compat Polym，2021，36
                   gen coating，and electrospinning significantly improve bio⁃  （4）：314-333
                   compatibility，antimicrobial，and osteogenic properties for  ［31］ PENG W，REN S，ZHANG Y，et al. MgO nanoparticles⁃in⁃
                   orofacial tissue regeneration［J］. ACS Appl Mater Interfac⁃  corporated PCL/gelatin ⁃ derived coaxial electrospinning
                   es，2019，11（41）：37381-37396                        nanocellulose membranes for periodontal tissue regenera⁃
             ［21］ ABDELAZIZ D，HEFNAWY A，AL ⁃ WAKEEL E，et al.         tion［J］. Front Bioeng Biotechnol，2021，9：668428
                   New biodegradable nanoparticles ⁃ in ⁃ nanofibers based  ［32］ WU X，MIAO L，YAO Y，et al. Electrospun fibrous scaf⁃
                   membranes for guided periodontal tissue and bone regen⁃  folds combined with nanoscale hydroxyapatite induce os⁃
                   eration with enhanced antibacterial activity［J］. J Adv  teogenic differentiation of human periodontal ligament
                   Res，2021，28：51-62                                 cells［J］. Int J Nanomedicine，2014，9：4135-4143
             ［22］ REN S，ZHOU Y，ZHENG K，et al. Cerium oxide nanopar⁃  ［33］ NIVEDHITHA SUNDARAM M，SOWMYA S，DEEPTHI
                   ticles loaded nanofibrous membranes promote bone regen⁃  S，et al. Bilayered construct for simultaneous regeneration
                   eration for periodontal tissue engineering［J］. Bioact Ma⁃  of alveolar bone and periodontal ligament［J］. J Biomed
                   ter，2021，7：242-253                                Mater Res B Appl Biomater，2016，104（4）：761-770
             ［23］ RASTIN H，MANSOURI N，TUNG T T，et al. Converging  ［34］ QIAN Y，ZHOU X，ZHANG F，et al. Triple PLGA/PCL
                   2D nanomaterials and 3D bioprinting technology：state⁃of⁃  scaffold modification including silver⁃impregnation，colla⁃
                   the ⁃ art，challenges，and potential outlook in biomedical  gen⁃coating，and electrospinning significantly improve bio⁃
                   applications［J］. Adv Healthc Mater，2021，10（22）：   compatibility，antimicrobial，and osteogenic properties for
                   2101439                                           oro⁃facial tissue regeneration［J］. ACS Appl Mater Inter⁃
             ［24］ PARK J，PARK S，KIM J E，et al. Enhanced osteogenic   faces，2019，11（41）：37381-37396
                   differentiation of periodontal ligament stem cells using a  ［35］ SHU Z，ZHANG C，YAN L，et al. Antibacterial and osteo⁃
                   graphene oxide⁃coated poly（ε⁃caprolactone）scaffold［J］.  conductive polycaprolactone/polylactic acid/nano ⁃ hy⁃
                   Polymers，2021，13（5）：797                           droxyapatite/Cu@ZIF⁃8 GBR membrane with asymmetric
             ［25］ DIAS A M，DA SILVA F G，MONTEIRO A P DE F，et al.     porous structure［J］. Int J Biol Macromol，2023，224：
                   Polycaprolactone nanofibers loaded oxytetracycline hydro⁃  1040-1051
                   chloride and zinc oxide for treatment of periodontal disease  ［36］ 周和阳，吕佳欣，刘栋宇，等. 美学区种植同期引导骨再
                  ［J］. Mater Sci Eng C Mater Biol Appl，2019，103：109798  生术骨替代材料留存率的相关因素分析［J］. 南京医科
             ［26］ SUN M，LIU Y，JIAO K，et al. A periodontal tissue regen⁃  大学学报（自然科学版），2023，43（3）：380-385
                   eration strategy via biphasic release of zeolitic imidazo⁃             ［收稿日期］ 2023-03-17
                   late framework⁃8 and FK506 using a uniaxial electrospun                     （本文编辑：唐      震）