体外磷灰石沉积在热处理、H(2)O(2)-和naoh处理钛表面的比较研究。

X X Wang, S Hayakawa, K Tsuru, A Osaka
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引用次数: 170

摘要

对商业纯钛标本进行三种不同的处理,并通过将标本浸泡在模拟体液(SBF, Kokubo的配方)中长达7天的不同时期来评估其生物活性,特别注意向SBF开放的表面和与容器底部接触的表面之间磷灰石沉积的差异。用H(2)O(2)/HCl溶液在80℃下处理30分钟,然后在400℃下加热1小时,在样品表面产生锐钛矿型二氧化钛凝胶层。该凝胶层在接触表面和开放表面沉积磷灰石,并且在蒸馏水中预桩不会改变磷灰石的沉积能力。用60℃的NaOH溶液处理3天,形成钛酸钠凝胶层。该凝胶层只能在接触面沉积磷灰石,在蒸馏水中预桩1天后,磷灰石沉积能力完全丧失。因此,二氧化钛凝胶的生物活性源于凝胶本身的良好结构,而钛酸钠凝胶的生物活性很大程度上取决于凝胶中的离子释放。第三种处理,在400℃下进行1小时的简单热处理,在试样表面产生致密的(不多孔的)氧化层。试件在SBF中桩敷3天后就能在接触表面沉积磷灰石,但在开放表面长达2个月的桩敷中不能沉积磷灰石。讨论了这种磷灰石沉积行为与骨内钛植入物环境的关系以及SBF桩接实验的方法。
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A comparative study of in vitro apatite deposition on heat-, H(2)O(2)-, and NaOH-treated titanium surfaces.

Commercially pure titanium specimens are subjected to three different treatments, and their bioactivity are evaluated by immersing the specimens in a simulated body fluid (SBF, Kokubo's recipe) for various periods up to 7 days, with particular attention being paid to the differences in apatite deposition between surfaces open to SBF and surfaces in contact with the container's bottom. The treatment with a H(2)O(2)/HCl solution at 80 degrees C for 30 min followed by heating at 400 degrees C for 1 h produces an anatase titania gel layer on the specimen surface. This gel layer deposits apatite both on the contact and on open surfaces, and apatite deposition ability does not change with pre-staking in distilled water. The treatment with a NaOH solution at 60 degrees C for 3 days produces a sodium titanate gel layer. This gel layer can deposit apatite only on the contact surface, and the apatite deposition ability is completely lost after 1 day of pre-staking in distilled water. It is concluded, therefore, that the bioactivity of the titania gel originates from the favorable structure of the gel itself while the bioactivity of the sodium titanate gel depends heavily on ion release from the gel. The third treatment, a simple heat treatment at 400 degrees C for 1 h, produces a dense (not porous) oxide layer on the specimen surface. The specimens can deposit apatite on the contact surface after only 3 days of staking in SBF, but they cannot deposit apatite on the open surface for up to 2 months of staking. The implications of such apatite deposition behavior have been discussed in relation to the environments of titanium implants in bone as well as to the methodology of the SBF staking experiment.

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