中国组织工程研究与临床康复
中國組織工程研究與臨床康複
중국조직공정연구여림상강복
JOURNAL OF CLINICAL REHABILITATIVE TISSUE ENGINEERING RESEARCH
2009年
38期
7474-7476
,共3页
徐立新%史雪婷%王彦平%石宗利
徐立新%史雪婷%王彥平%石宗利
서립신%사설정%왕언평%석종리
磷酸钙骨水泥%聚磷酸钙纤维%复合材料%力学性能
燐痠鈣骨水泥%聚燐痠鈣纖維%複閤材料%力學性能
린산개골수니%취린산개섬유%복합재료%역학성능
目的:制备α-磷酸三钙/聚磷酸钙纤维复合材料,探讨聚磷酸钙纤维增强磷酸钙骨水泥的可行性.方法:首先利用沉淀法合成出α-磷酸三钙粉末,然后将其与不同质量比、不同长度聚磷酸钙纤维混合,最后用固化液调和制得骨水泥.对样品进行凝固时间、力学性能测试,利用扫描电镜观察固化体微观结构.结果:当聚磷酸钙纤维的含量为10%、长度为2 mm时,复合材料抗压强度达到62.5 MPa,抗折强度达到12.4 MPa.扫描电镜显示适量的聚磷酸钙纤维在骨水泥基体中分布均匀,与基体结合性好.在Ringer溶液中浸泡2个月后,纤维未发生明显的降解作用,仍具有一定的增强增韧效果.结论:聚磷酸钙纤维在一定程度上可对骨水泥起到增强作用.α-磷酸三钙/聚磷酸钙纤维复合材料具有良好的力学特性.
目的:製備α-燐痠三鈣/聚燐痠鈣纖維複閤材料,探討聚燐痠鈣纖維增彊燐痠鈣骨水泥的可行性.方法:首先利用沉澱法閤成齣α-燐痠三鈣粉末,然後將其與不同質量比、不同長度聚燐痠鈣纖維混閤,最後用固化液調和製得骨水泥.對樣品進行凝固時間、力學性能測試,利用掃描電鏡觀察固化體微觀結構.結果:噹聚燐痠鈣纖維的含量為10%、長度為2 mm時,複閤材料抗壓彊度達到62.5 MPa,抗摺彊度達到12.4 MPa.掃描電鏡顯示適量的聚燐痠鈣纖維在骨水泥基體中分佈均勻,與基體結閤性好.在Ringer溶液中浸泡2箇月後,纖維未髮生明顯的降解作用,仍具有一定的增彊增韌效果.結論:聚燐痠鈣纖維在一定程度上可對骨水泥起到增彊作用.α-燐痠三鈣/聚燐痠鈣纖維複閤材料具有良好的力學特性.
목적:제비α-린산삼개/취린산개섬유복합재료,탐토취린산개섬유증강린산개골수니적가행성.방법:수선이용침정법합성출α-린산삼개분말,연후장기여불동질량비、불동장도취린산개섬유혼합,최후용고화액조화제득골수니.대양품진행응고시간、역학성능측시,이용소묘전경관찰고화체미관결구.결과:당취린산개섬유적함량위10%、장도위2 mm시,복합재료항압강도체도62.5 MPa,항절강도체도12.4 MPa.소묘전경현시괄량적취린산개섬유재골수니기체중분포균균,여기체결합성호.재Ringer용액중침포2개월후,섬유미발생명현적강해작용,잉구유일정적증강증인효과.결론:취린산개섬유재일정정도상가대골수니기도증강작용.α-린산삼개/취린산개섬유복합재료구유량호적역학특성.
AIM: To prepare α-tricalcium phosphate (α-TCP)/calcium polyphosphate (CPP) fiber and to study the feasibility of CPP fiber to reinforce calcium phosphate bone cement composites. METHODS: Firstly,α-TCP powder was synthesized using chemical sediment method. Secondly, the α-TCP was mixed with CPP fiber according to different contents and lengths. Finally, bone cement was tempered with firming agent. Solidification time and mechanical property of the samples were measured. Microstructure of hardened sample was observed with scanning electron microscope. RESULTS: When the amount of CPP fibers was 10% and the length was 2 mm, the compressive strength reached 62.5 MPa and the rupture strength reached 12.4 MPa. Scanning electron microscope suggested that CPP fibers with great associativity were well distributed in bone cement. After immersing in Ringer fluid for two months, the CPP fibers did not biodegrade obviously and still had certain function to increase strength and toughness. CONCLUSION: To a certain extent, the CPP fiber can increase strength and toughness of bone cement. Furthermore, α-TCP/CPP composites have good mechanical properties and biocompatibility.
