To clarify the antibacterial behavior at early adhesion,two titania nanotube(TNT)arrays were fabricated on polished commercially pure titanium(Ti),and the interaction mechanisms between TNT arrays and the model bacter...To clarify the antibacterial behavior at early adhesion,two titania nanotube(TNT)arrays were fabricated on polished commercially pure titanium(Ti),and the interaction mechanisms between TNT arrays and the model bacteria(Escherichia coli,E.coli)were investigated.The results show that TNT arrays exhibit a significant early antibacterial effect,which is highly related to the surface free energy and nano-topography.The underlying antibacterial mechanisms include:(1)the anti-initial-attachment effect at the lag phase(0−4 h);(2)the anti-proliferation and physical bactericidal effects at the logarithmic phase(4−12 h);(3)the reduced antimicrobial properties probably due to the overgrowth of bacteria on TNT arrays at the stationary phase(12 h and then).展开更多
1 Results Quasi one-dimensional nanostructured materials have received considerable attention due to their unique optical and electrical properties and potential applications in nanodevices.Much effort has been direct...1 Results Quasi one-dimensional nanostructured materials have received considerable attention due to their unique optical and electrical properties and potential applications in nanodevices.Much effort has been directed toward exploring novel synthetic methods and understanding the chemical and physical properties of these nanostructures.The chemical vapor deposition and thermal evaporation,are proved to be efficient for the preparation of wirelike nanomaterials,however these methods are quite energy co...展开更多
Mesoporous silica thin film has been widely used in various fields,particularly the medical implant coating for drug delivery.However,some drawbacks remain with the films produced by traditional method(evaporation-ind...Mesoporous silica thin film has been widely used in various fields,particularly the medical implant coating for drug delivery.However,some drawbacks remain with the films produced by traditional method(evaporation-induced self-assembly,EISA),such as the poor permeability caused by their horizontal aligned mesochannels.In this study,the vertical aligned mesoporous silica thin film(VMSTF)is uniformly grown alongside the walls of titania nanotubes array via a biphase stratification growth method,resulting in a hierarchical two-layered nanotubular structure.Due to the exposure of opened mesopores,VMSTF exhibits more appealing performances,including rapid degradation,efficient small-molecular drug(dexamethasone)loading and release,enhanced early adhesion and osteogenic differentiation of MC3T3-E1 cells.This is the first time successfully depositing VMSTF on nanoporous substrate and our findings suggest that the VMSTF may be a promising candidate for bone implant surface coating to obtain bioactive performances.展开更多
基金The authors are grateful for the financial supports from the National Natural Science Foundation of China(Nos.51604104,52171114,81702709)the Innovation-oriented Advanced Technology and Industrial Technology Program Project of Hunan Province,China(No.2020SK2017)+2 种基金the Central South University Postgraduate Education and Teaching Reform Project,China(No.2020JGB116)the Natural Science Foundation of Hunan Province,China(No.2020JJ4459)the Fundamental Research Funds for the Central Universities of Central South University,China(No.CX20200267).
文摘To clarify the antibacterial behavior at early adhesion,two titania nanotube(TNT)arrays were fabricated on polished commercially pure titanium(Ti),and the interaction mechanisms between TNT arrays and the model bacteria(Escherichia coli,E.coli)were investigated.The results show that TNT arrays exhibit a significant early antibacterial effect,which is highly related to the surface free energy and nano-topography.The underlying antibacterial mechanisms include:(1)the anti-initial-attachment effect at the lag phase(0−4 h);(2)the anti-proliferation and physical bactericidal effects at the logarithmic phase(4−12 h);(3)the reduced antimicrobial properties probably due to the overgrowth of bacteria on TNT arrays at the stationary phase(12 h and then).
文摘1 Results Quasi one-dimensional nanostructured materials have received considerable attention due to their unique optical and electrical properties and potential applications in nanodevices.Much effort has been directed toward exploring novel synthetic methods and understanding the chemical and physical properties of these nanostructures.The chemical vapor deposition and thermal evaporation,are proved to be efficient for the preparation of wirelike nanomaterials,however these methods are quite energy co...
基金the National Natural Science Foundation of China[grant numbers 81530051,31800790 and 31670966]Shaanxi Provincial Key Research and Development Plan Project(2019SF-031)+2 种基金Young Talent fund of University Association for Science and Technology in Shaanxi,China(20190304)supported by Danmarks Frie Forskningsfond(9040-00219B)Carlsbergfondet。
文摘Mesoporous silica thin film has been widely used in various fields,particularly the medical implant coating for drug delivery.However,some drawbacks remain with the films produced by traditional method(evaporation-induced self-assembly,EISA),such as the poor permeability caused by their horizontal aligned mesochannels.In this study,the vertical aligned mesoporous silica thin film(VMSTF)is uniformly grown alongside the walls of titania nanotubes array via a biphase stratification growth method,resulting in a hierarchical two-layered nanotubular structure.Due to the exposure of opened mesopores,VMSTF exhibits more appealing performances,including rapid degradation,efficient small-molecular drug(dexamethasone)loading and release,enhanced early adhesion and osteogenic differentiation of MC3T3-E1 cells.This is the first time successfully depositing VMSTF on nanoporous substrate and our findings suggest that the VMSTF may be a promising candidate for bone implant surface coating to obtain bioactive performances.
