Effects of MgO nanoparticle addition on the mechanical properties,degradation properties,antibacterial properties and in vitro and in vivo biological properties of 3D-printed Zn scaffolds  

在线阅读下载全文

作  者:Leiting Yu Fengdong Sun Yuanyuan Wang Wei Li Yufeng Zheng Guangxin Shen Yao Wang Minfang Chen 

机构地区:[1]School of Materials Science and Engineering,Tianjin University of Technology,Tianjin,300384,China [2]School of Stomatology,Tianjin Medical University,Tianjin,300070,China [3]School of Materials Science and Engineering,Peking University,Beijing,100871,China [4]Changzhi Medical College,Changzhi,046000,Shanxi,China [5]National Demonstration Center for Experimental Function Materials Education,Tianjin University of Technology,Tianjin,300384,China

出  处:《Bioactive Materials》2024年第7期72-85,共14页生物活性材料(英文)

基  金:support for this work from the National Natural Science Foundation of China (Nos.52171241 and 52373251).

摘  要:Bone tissue engineering is the main method for repairing large segment bone defects.In this study,a layer of bioactive MgO nanoparticles was wrapped on the surface of spherical Zn powders,which allowed the MgO nanoparticles to be incorporated into 3D-printed Zn matrix and improved the biodegradation and biocompatibility of the Zn matrix.The results showed that porous pure Zn scaffolds and Zn/MgO scaffolds with skeletal-gyroid(G)model structure were successfully prepared by selective laser melting(SLM).The average porosity of two porous scaffolds was 59.3 and 60.0%,respectively.The pores were uniformly distributed with an average pore size of 558.6-569.3μm.MgO nanoparticles regulated the corrosion rate of scaffolds,resulting in a more uniform corrosion degradation behavior of the Zn/MgO scaffolds in simulated body fluid solution.The degradation ratio of Zn/MgO composite scaffolds in vivo was increased compared to pure Zn scaffolds,reaching 15.6%at 12 weeks.The yield strength(10.8±2.4 MPa)of the Zn/MgO composite scaffold was comparable to that of cancellous bone,and the antimicrobial rate were higher than 99%.The Zn/MgO composite scaffolds could better guide bone tissue regeneration in rat cranial bone repair experiments(completely filling the scaffolds at 12 weeks).Therefore,porous Zn/MgO scaffolds with G-model structure prepared with SLM are a promising biodegradable bone tissue engineering scaffold.

关 键 词:3D printing Porous Skeletal-gyroid Zn/MgO scaffold BIOCOMPATIBILITY 

分 类 号:R318[医药卫生—生物医学工程]

 

参考文献:

正在载入数据...

 

二级参考文献:

正在载入数据...

 

耦合文献:

正在载入数据...

 

引证文献:

正在载入数据...

 

二级引证文献:

正在载入数据...

 

同被引文献:

正在载入数据...

 

相关期刊文献:

正在载入数据...

相关的主题
相关的作者对象
相关的机构对象