等离子喷涂制备HA/ZrO2复合涂层

采用等离子喷涂技术,在Ｔｉ－６Ａｌ－４Ｖ基体上成功地制备了羟基磷灰石／氧化锆（ＨＡ／ＺｒＯ_２）复合涂层,对涂层的微观结构、相组成和结合强度进行了研究,并以模拟体液试验评估涂层的生物活性．结果表明,复合涂层具有较为均匀的微观结构．ＨＡ／ＺｒＯ_２复合涂层的结合强度明显高于 ＨＡ涂层, ＨＡ／６０ ｗｔ％ ＺｒＯ_２涂层的结合强度高达 ２８．５ＭＰａ,为 ＨＡ涂层的 ２．２倍．复合涂层在模拟体液中浸泡一段时间后,表面覆盖一层碳酸磷灰石（ｃａｒｂｏｎａｔｅ－ａｐａｔｉｔｅ）,表明涂层具有良好的生物活性．     

等离子喷涂HA/Ti复合涂层研究 I.结构、组成和力学性能

采用等离子喷涂方法,在Ｔｉ－６Ａｌ－４Ｖ基体上成功地制备了ＨＡ／Ｔｉ复合涂层,并对复合涂层的微观结构、相组成和力学性能进行了研究．结果表明,ＨＡ和Ｔｉ两相均匀地分布于复合涂层中．ＨＡ／Ｔｉ复合涂层的结合强度明显高于纯 ＨＡ涂层,这主要是由于 ＨＡ／Ｔｉ的复合缓和了涂层与基体之间的热膨胀系数失配．ＨＡ／Ｔｉ复合涂层在模拟体液中浸泡一段时间后,结合强度没有明显降低．ＨＡ／Ｔｉ复合涂层的断裂韧性和硬度均高于 ＨＡ涂层．     

等离子喷涂HA/Ti复合涂层研究 I.结构、组成和力学性能

采用等离子喷涂方法,在Ｔｉ－６Ａｌ－４Ｖ基体上成功地制备了ＨＡ／Ｔｉ复合涂层,并对复合涂层的微观结构,相组成和力学性能进行了研究。结果表明,ＨＡ和Ｔｉ两相均匀地分布于复合涂层中。ＨＡ／Ｔｉ复合涂层的结合强度明显高于纯ＨＡ涂层,这主要是由于ＨＡ／Ｔｉ的复合和了涂层与基体之间的热膨胀系数失配,ＨＡ／Ｔｉ复合涂层在模拟体液中浸泡一段时间后,结合强度没有明显降低,ＨＡ／Ｔｉ复合涂层的断裂韧性和硬度均高于Ｈ     

等离子喷涂HA/TiO2复合涂层

采用大气等离子喷涂方法,成功地制备了ＨＡ／ＴｉＯ２复合涂层,对复合涂层的结合强度、微观结构、水浸渍下的表面形貌进行了较为深入的研究,结果表明,由于ＴｉＯ２的加入,ＨＡ／ＴｉＯ２涂层的结合强度明显高于纯ＨＡ涂层,而且导致涂层破坏机理由粘合破坏向内聚破坏转化,这是由于ＨＡ／ＴｉＯ２的复合缓和了涂层与基体间的膨胀系数失配现象,改善了涂层与基体之间的结合,ＳＥＭ观察显示,ＨＡ／ＴｉＯ２涂层表面有一些细小的     

梯度热障涂层热冲击性能研究

采用等离子喷涂的方法,分别获得了２ｍｍ ＺｒＯ２－ＮｉＣｒＡｌ和ＺｒＯ２－Ｎｉ／Ａｌ系梯度热障涂层。热冲击实验结果表明,两种涂层具有不同的失效机理。ＺｒＯ２－ＮｉＣｒＡｌ系的失效是由于基于基体氧化引起的涂层整体脱落;而ＺｒＯ２－Ｎｉ／Ａｌ系的失效是支径向裂纹扩展到Ｎｉ／Ａｌ底层氧化共同作用的结果。     

耐热防腐蚀复相陶瓷涂层的研究

在经表面预处理的普通碳素钢上，采用热化学反应法制备均匀的陶瓷涂层。微观结构分析和性能检测表明，涂层为含有ＭｇＡｌ２Ｏ４、Ａｌ６ＳｉｏＯ１３、ＺｒＯ２等的复相陶瓷结构。涂层与基体的结合强度较高，耐热防腐蚀性能优异，抗热震性较好。     

超细ZrO2粉末等离子喷涂层质量的探讨

采用两种ＺｒＯ２粉末分别在碳钢基体表面制备了ＺｒＯ２等离子涂层，并考察了两种ＺｒＯ２粉末的等离子涂层的质量，结果表明，由烧结－粉碎法制备了ＺｒＯ２烧结粉形成的涂层比较致密，强度较高，在轴向拉应力的作用下，开裂发生在涂层与基体的结合界面处；而由冷压－球磨法制备的ＺｒＯ２团聚簇涂层中孔隙较多，强度亦较低，在轴向拉压力的作用下开裂发生的涂层内部。     

生物活性钛涂层

真空等离子喷涂的钛涂层经 ５．０ｍｏｌ／Ｌ ＮａＯＨ溶液处理后,将其浸泡在含 Ｃａ^２＋、ＨＰＯ_４^２－的模拟生理体液（ＦＣＳ和ＳＢＦ）中,考察涂层诱导羟基磷灰石生长过程,并评价其生物活性．用ＳＥＭ观察碱处理前后和在模拟生理体液中浸泡后钛涂层的形貌,用ＡＥＳ分析了碱处理前后钛涂层的表面成分;用ＸＲＤ、ＦＴ－ＩＲ和ＥＤＳ表征浸泡后涂层表面生长物的结构和成分;并测量了处理后钛涂层在浸泡过程中溶液中离子浓度和ｐＨ值的变化．结果表明,经处理的钛涂层在模拟生理体液中能诱导羟基磷灰石在其表面生长;在ＳＢＦ和ＦＣＳ分别形成碳酸羟基磷灰石层和含氧磷灰石的羟基磷灰石层．钛涂层的活性是由于碱处理后表面形成了网状和纤维状结构的Ｎａ－Ｔｉ－Ｏ化合物．这种化合物在模拟生理溶液中释放Ｎａ^＋,吸收Ｈ^＋;形成水化钛酸盐,诱导羟基磷灰石成核生长．     

等离子喷涂HA/Ti复合涂层研究 Ⅱ.生物学性能

对等离子喷涂ＨＡ／Ｔｉ复合涂层进行模拟体液和体外细胞试验,以考察涂层的生物学性能。结果指出,涂层经模拟体液浸泡后,表面覆盖一层碳酸磷灰石（ｃａｒｂｏｎａｔｅ－ａｐａｔｉｔｅ）,这表明涂层具有良好的生物活性,粗糙的涂层表面易于形成碳酸磷灰石,,模拟体液的浓度太小或ｐＨ值太大,均会导致碳酸磷灰石层不能在涂层表面形成,体外细胞试验显示,成骨细胞能在涂层表面紧密贴壁并正常生长,显示涂层具有优良的生物相容性     

添加Al_2O_3对SiC板粒／Y－TZP复合材料力学性能的影响

本文以ＳｉＣ板粒、ＺｒＯＣｌ２－８Ｈ２Ｏ、ＡｌＣｌ３和Ｙ（ＭＯ）３为原料，利用共沉淀和热压烧结工艺，制备ＳｉＣ板粒／Ｙ－ＴＺＰ和（含Ａｌ２Ｏ３）ＳｉＣ板粒／Ｙ－ＴＺＰ复合材料．测试了材料的室温和高温力学性能．研究了添加Ａｌ２Ｏ３对ＳｉＣ板粒／Ｙ－ＴＺＯ复合材料的影响．结果表明，ＳｉＣ板粒／Ｙ－ＴＺＰ复合材料与Ｙ－ＴＺＰ陶瓷相比，其室温强度和韧性出现明显下降，高温强度也没有改善；而在ＳｉＣ板粒与Ｙ－ＴＺＰ复合的基础上，添加Ａｌ２Ｏ３可明显提高材料的强度和断裂韧性，同时，材料的高温强度也获得显著改善．     

等离子体喷涂氧化钛涂层的生物活性研究

以纳米TiO₂粉末为喷涂原料, 采用大气等离子体喷涂技术在医用钛合金上制备氧化钛涂层. 利用酸和碱溶液对氧化钛涂层表面进行生物活化处理, 体外模拟体液浸泡实验考察涂层的生物活性. 采用XRD、SEM、FTIR、EDS等测试技术对改性前后氧化钛涂层的生物活性进行表征. 结果表明: 氧化钛涂层和钛合金基体的结合强度较高, 其值高达40MPa, 涂层的耐模拟体液腐蚀性优于钛合金. 酸和碱溶液表面改性后的氧化钛涂层经模拟体液浸泡可在其表面生成含有碳酸根的羟基磷灰石(类骨磷灰石), 显示良好的生物活性.     

两步电沉积法制备HA-Ti/HA复合涂层的研究

为了提高金属基羟基磷灰石（HA）涂层的结合强度,采用复合电沉积一电沉积两步法在含Ti粉的钙磷电解液中制备HA—Ti／HA复合涂层,对涂层的组分结构、表面形貌、热稳定性、结合强度和生物活性进行了研究．实验结果表明：两步法制备的底层为HA—Ti复合涂层,外层为纯HA涂层的HA—Ti／HA复合涂层既提高了涂层的结合强度,又保证了涂层的生物活性．当涂层中Ti粉的质量分数为51．2wt％时,涂层与基体的结合强度达到21．2MPa,约为纯HA涂层的3倍．模拟体液浸泡7天后,涂层表面即被一层球状碳磷灰石覆盖,具有良好的生物活性,与纯HA涂层相比,复合涂层具有更好的耐蚀性能．     

Plasma spraying of zirconia-reinforced hydroxyapatite composite coatings on titanium: Part II Dissolution behaviour in simulated body fluid and bonding degradation

The change of phase, morphology and bond strength of plasma sprayed hydroxyapatite (HA) coating and ZrO2/HA composite coatings immersed in simulated body fluid (SBF) for various periods of time was studied. X-ray diffractometry (XRD) and scanning electron microscopy (SEM) were used to identify the phase and observe the morphology of the coating surface before and after immersion. In addition, inductively coupled plasma emission spectroscopy (ICP) was used to measure the ion release rate of coatings in SBF for various periods of time. Observation of the morphology by SEM shows that the composite coating with the addition of ZrO2 in HA significantly reduced the dissolution rate of impurity phases in simulated body fluid. The argument was supported by measurement of Ca2+ ion concentration in SBF. During plasma spraying, less OH- ions were lost in a ZrO2-containing composite coating. This factor, together with the reduced effective surface of the ZrO2-containing HA coating, were attributed to the reduced dissolution rate of the composite coatings. All the plasma sprayed coatings degraded after immersion in SBF owing to dissolution of constituents in the coating, however, the addition of ZrO2 in HA improved the bonding strength of HA coating after immersion in SBF.     

Biological responses of neonatal rat calvarial osteoblasts on plasma-sprayed HA/ZrO2 composite coating

Plasma-sprayed hydroxyapatite (HA) coating, applied to metal substrates, can induce a direct chemical bond with bone and hence achieve a biological fixation of the implant. However, the poor bonding strength between the HA coating and the substrate has been a concern for the orthopedists. In a previous study, the zirconia-reinforced hydroxyapatite composite coatings (HA/ZrO₂) could significantly improve the mechanical strength before and after soaking in simulated body fluid. This study aims to investigate the biological responses of osteoblasts on plasma-sprayed HA/ZrO₂ coating. The osteoblasts derived from neonatal rat calvarial were cultured in Dulbeccos modified Eagle medium (DMEM) with fetal bovine serum (FBS) on the surface of plasma-sprayed HA coating, HA/ZrO₂ coating, and ZrO₂ coating, respectively. The biological responses were investigated by the cell growth (1, 3, 5, and 10 days) and the cell morphology under scanning electron microscopy (SEM) (3, 6, 12, 24 and 48 h). Examination by SEM revealed that osteoblasts on HA coatings exhibit less spreading during the medium phase (6 and 12 h), while, better morphologies were observed at the latter phases (24 and 48 h). This should be derived by the dissolution of HA coating in the culture medium. On HA/ZrO₂ coating, the cells showed the poor morphologies at the latter phases (24 and 48 h). This could be explained by the no apatite formed at the surface HA/ZrO₂ coating after soaking in simulated body fluid. The lower contents of ZrO₂ coating in HA coating and the addition of other solid solution (ZrO₂–MgO, CaO–ZrO₂, ZrO₂–CeO₂) in HA coating are the two possible methods to improve the cytocompatibility of HA/ZrO₂ coating.     

Plasma-sprayed zirconia bond coat as an intermediate layer for hydroxyapatite coating on titanium alloy substrate

This study aims to strengthen the bonding at HA coating/Ti–6Al–4V interface by adding an intermediate ZrO₂ bond coat between them. The bonding strength of the HA/ZrO₂ coating was evaluated with the separately prepared HA coating as control. The phase, microstructure and chemistry, and surface roughness of the plasma-sprayed two-layer HA/ZrO₂ coating on Ti–6A1–4V substrate were investigated by X-ray diffractometry, scanning electron microscopy, and surfcorder, respectively. Experimental results indicate that the bonding strength increases from 28.6±3.22 MPa for HA coating to 36.2±3.02 MPa for HA/ZrO₂ composite coating. Elemental analysis employed on the surface of ZrO₂ bond coat, on which the HA top coat was first dissolved completely in HCl acid, reveals the sign of diffusion of calcium ions from HA to ZrO₂ bond coat. In addition, rougher surface morphology provided by ZrO₂ bond coat is also considered to aid in the bonding at HA/ZrO₂ interface. Similar coating system done by other researchers is compared and discussed.     

钛涂覆多孔羟基磷灰石涂层的制备及其生物活性

在纯钛基体表面通过电泳沉积的方法制得壳聚糖/羟基磷灰石(CS/HA)复合涂层, 然后将复合涂层烧结形成多孔HA涂层。采用SEM对多孔HA涂层的形貌进行观察, XRD分析涂层的物相组成, 粘结拉伸实验测定涂层与基体的结合强度, 1.5倍人体模拟体液(1.5SBF)浸泡测定涂层的生物活性。结果表明: 当悬浮液中CS与HA质量比为1∶1时, 制得的CS/HA复合涂层经过700℃烧结处理, 涂层中CS热分解致孔形成多孔HA涂层, 孔径在10~25 μm, 涂层与基体的结合强度可达19.5 MPa; 在1.5SBF中浸泡5天后, 多孔HA涂层表面完全碳磷灰石化, 呈现较好的生物活性。      

等离子喷涂HA/TiO2复合涂层

采用大气等离子喷涂方法,成功地制备了HA／TiO₂复合涂层,对复合涂层的结合强度、微观结构、水浸渍下的表面形貌进行了较为深入的研究．结果表明,由于TiO₂的加入,HA／TiO₂涂层的结合强度明显高于纯HA徐层,而且导致涂层破坏机理由粘合破坏向内聚破坏转化．这是由于HA／TiO₂的复合缓和了涂层与基体间的膨胀系数失配现象,改善了涂层与基体之间的结合．SEM观察显示,HA／TiO₂涂层表面有一些细小的裂纹,但在去离子水中浸泡后就会消失,而且不容易产生新的裂纹,这说明TiO₂的加入不但改善了涂层与基体之间的结合,同时增强了涂层内部颗粒的结合．     

等离子喷涂HA／Ti复合涂层研究

对等离子喷涂HA／Ti复合涂层进行模拟体液和体外细胞试验,以考察涂层的生物学性能．结果指出,涂层经模拟体液浸泡后,表面覆盖一层碳酸磷灰石(carbonate-apatite),这表明涂层具有良好的生物活性．粗糙的涂层表面易于形成碳酸磷灰石．模拟体液的浓度太小或pH值太大,均会导致碳酸磷灰石层不能在涂层表面形成．体外细胞试验显示,成骨细胞能在涂层表面紧密贴壁并正常生长,显示涂层具有优良的生物相容性．