Magnesium is an excellent material in terms of biocompatibility and its corrosion products can serve as an active source for new bone formation.However,localized corrosion and H_(2)generation limit the potential of Mg...Magnesium is an excellent material in terms of biocompatibility and its corrosion products can serve as an active source for new bone formation.However,localized corrosion and H_(2)generation limit the potential of Mg-based implants.Utilizing low-alloyed Mg-Zn wires can strongly reduce problems with large H_(2)bubbles and improve the mechanical properties considerably while maintaining excellent long-term biocompatibility.Acidic pickling and a polymer coating can be effectively used to lower the rate of in vivo degradation.In this work,microstructural,mechanical,and in vitro characterization of 250μm and 300μm extruded wires made from ultra-pure Mg,commercially pure Mg,Mg-0.15Zn,Mg-0.4Zn and Mg-1Zn was performed.Additionally,Mg-0.4Zn wires together with a variant coated with a copolymer of L-lactide andε-caprolactone were tested in vivo on artificially damaged Wistar rat femurs.Based on the observed Mg-induced osteogenesis,polymer-coated Mg wires with a small addition of Zn are a perspective material for bone-support applications,such as cerclage and fixation wires.展开更多
In situ monitoring of bone regeneration enables timely diagnosis and intervention by acquiring vital biological parameters.However,an existing gap exists in the availability of effective methodologies for continuous a...In situ monitoring of bone regeneration enables timely diagnosis and intervention by acquiring vital biological parameters.However,an existing gap exists in the availability of effective methodologies for continuous and dynamic monitoring of the bone tissue regeneration process,encompassing the concurrent visualization of bone formation and implant degradation.Here,we present an integrated scaffold designed to facilitate real-time monitoring of both bone formation and implant degradation during the repair of bone defects.Laponite(Lap),CyP-loaded mesoporous silica(CyP@MSNs)and ultrasmall superparamagnetic iron oxide nanoparticles(USPIO@SiO2)were incorporated into a bioink containing bone marrow mesenchymal stem cells(BMSCs)to fabricate functional scaffolds denoted as C@M/GLU using 3D bioprinting technology.In both in vivo and in vitro experiments,the composite scaffold has demonstrated a significant enhancement of bone regeneration through the controlled release of silicon(Si)and magnesium(Mg)ions.Employing near-infrared fluorescence(NIR-FL)imaging,the composite scaffold facilitates the monitoring of alkaline phosphate(ALP)expression,providing an accurate reflection of the scaffold’s initial osteogenic activity.Meanwhile,the degradation of scaffolds was monitored by tracking the changes in the magnetic resonance(MR)signals at various time points.These findings indicate that the designed scaffold holds potential as an in situ bone implant for combined visualization of osteogenesis and implant degradation throughout the bone repair process.展开更多
基金the project Ferr Mion of the Ministry of Education,Youth and Sports,Czech Republic,co-funded by the European Union(CZ.02.01.01/00/22_008/0004591)the support of The Charles University Grant Agency in the frame of the project No.121724 and the project Cooperatio No.207030 Dental Medicine/LF1 of the Charles University+4 种基金financial support from the Ministry of Education,Youth and Sport of the Czech Republic under the grant No.RVO 14000supported by the Ministry of Health of the Czech Republic-RVO project VFN64165the support of the project GAMA 2 of the Technology Agency of the Czech Republic No.TP01010055the project of the Czech Academy of Sciences,Czech Republic(Praemium Academiae grant No.AP2202)the support of the Ministry of Health of the Czech Republic,grant project No.NU20-08-00150。
文摘Magnesium is an excellent material in terms of biocompatibility and its corrosion products can serve as an active source for new bone formation.However,localized corrosion and H_(2)generation limit the potential of Mg-based implants.Utilizing low-alloyed Mg-Zn wires can strongly reduce problems with large H_(2)bubbles and improve the mechanical properties considerably while maintaining excellent long-term biocompatibility.Acidic pickling and a polymer coating can be effectively used to lower the rate of in vivo degradation.In this work,microstructural,mechanical,and in vitro characterization of 250μm and 300μm extruded wires made from ultra-pure Mg,commercially pure Mg,Mg-0.15Zn,Mg-0.4Zn and Mg-1Zn was performed.Additionally,Mg-0.4Zn wires together with a variant coated with a copolymer of L-lactide andε-caprolactone were tested in vivo on artificially damaged Wistar rat femurs.Based on the observed Mg-induced osteogenesis,polymer-coated Mg wires with a small addition of Zn are a perspective material for bone-support applications,such as cerclage and fixation wires.
基金support from various resources,including the National Natural Science Foundation of China (grant numbers 32071350,32271412,32171404)the Shanghai Rising-Star Program (grant numbers 22QA1400100)+1 种基金the Fundamental Research Funds for the Central Universities (grant numbers 2232019A3-06,2232021D-10)the Science and Technology Commission of Shanghai Municipality (grant numbers 21ZR1403100,19440741600,20DZ2254900).
文摘In situ monitoring of bone regeneration enables timely diagnosis and intervention by acquiring vital biological parameters.However,an existing gap exists in the availability of effective methodologies for continuous and dynamic monitoring of the bone tissue regeneration process,encompassing the concurrent visualization of bone formation and implant degradation.Here,we present an integrated scaffold designed to facilitate real-time monitoring of both bone formation and implant degradation during the repair of bone defects.Laponite(Lap),CyP-loaded mesoporous silica(CyP@MSNs)and ultrasmall superparamagnetic iron oxide nanoparticles(USPIO@SiO2)were incorporated into a bioink containing bone marrow mesenchymal stem cells(BMSCs)to fabricate functional scaffolds denoted as C@M/GLU using 3D bioprinting technology.In both in vivo and in vitro experiments,the composite scaffold has demonstrated a significant enhancement of bone regeneration through the controlled release of silicon(Si)and magnesium(Mg)ions.Employing near-infrared fluorescence(NIR-FL)imaging,the composite scaffold facilitates the monitoring of alkaline phosphate(ALP)expression,providing an accurate reflection of the scaffold’s initial osteogenic activity.Meanwhile,the degradation of scaffolds was monitored by tracking the changes in the magnetic resonance(MR)signals at various time points.These findings indicate that the designed scaffold holds potential as an in situ bone implant for combined visualization of osteogenesis and implant degradation throughout the bone repair process.
