微弧氧化和水热合成在钛基上制备羟基磷灰石

在含有0.04mol/L的磷酸二氢钠和0.01mol/L的醋酸钙电解液中对T i进行微弧氧化,生成含Ca和P很高的氧化膜。氧化膜粗糙多孔。然后,将样品放在220℃的高压釜中进行4h的水热处理,羟基磷灰石晶体在氧化膜表面沉积。用XRD检测氧化膜的晶体结构,用XPS研究氧化膜表面的化学成份,用SEM-EDS观察样品表面形貌。     

Triton X-100/正己醇/环己烷反相微乳液体系合成纳米羟基磷灰石

用Triton X-100/正己醇/环己烷/水四元反相微乳液体系制备了纳米羟基磷灰石(HA)粉体,确定了影响制备过程的最佳pH值和煅烧温度等工艺条件.x-射线衍射仪、TEM、SEM对羟基磷灰石的颗粒进行表征和分析表明:颗粒分散均匀,呈杆状,a轴尺寸为20～40nm左右,c轴尺寸为60～80nm,此方法可以有效地控制和改变HAP的分散性和粒度大小.     

二氧化锆梯度复合羟基磷灰石生物材料的制备及其生物相容性

采用干铺2烧结法制备了一种以二氧化锆(ZrO₂ ) 为基体梯度复合羟基磷灰石( HAP) 的新型生物复合材料, 并对其力学性能、微观结构和生物相容性进行了研究。用扫描电镜(SEM) 、X 射线衍射仪(XRD) 、透射电镜( TEM) 和EDAX 能谱仪对粉体和复合材料进行分析。用复合材料的浸提液进行小鼠急性毒性试验、细胞毒性试验、体外溶血试验以及兔肌肉和骨内材料植入试验, 评价复合材料的生物相容性。研究结果表明, 复合材料的表面涂层厚度约80μm , 芯部基体组织与表面均匀过渡结合, 结合良好, 没有明显界面, 涂层结合强度为15. 1 MPa ,最大弯曲强度为1112. 24 MPa , KIC为7. 3～11. 4 MPa·m1/2 。其组织相容性好, 具有良好的骨传导作用, 促进骨组织生长, 是一种较理想的新型骨科植入材料。      

玻璃基多孔骨水泥的制备和性能研究

将SiO2-CaO-P2O5系统生物活性玻璃粉末、甘露醇和磷酸铵调和液均匀混合制得多孔玻璃基骨水泥.利用XRD、FTIR和SEM对骨水泥的晶相和显微结构进行了观察和分析,并对其显气孔率和力学强度进行了测试.实验结果表明,随着浸泡时间的增加,骨水泥固化体中生成了HAP晶体,HAP晶体呈短柱状,交织分布于玻璃颗粒间隙,尺寸大约为200nm;甘露醇晶体能在生理模拟液的浸泡下降解,降解后留下的孔隙显著增加了骨水泥的显气孔率,并且随着甘露醇含量的增加而增加,而体积密度和力学强度则呈下降的趋势.     

羟基磷灰石作为催化材料的研究进展

羟基磷灰石(HAP)由于具有无毒性、生物相容性、热稳定性、吸附性、离子交换性、结构稳定性等,因而被广泛应用到催化剂的制备中.作为一种新型催化材料,HAP的特殊晶体结构对一些反应表现出催化活性,并且经过改性、负载等方法处理过后的HAP催化剂显示出独特的催化优势.基于近年来HAP在催化邻域的发展,综述了HAP作为催化材料在...     

Medicated Scaffolds Prepared with Hydroxyapatite/Streptomycin Nanoparticles Encapsulated into Polylactide Microfibers

The preparation, characterization, and controlled release of hydroxyapatite (HAp) nanoparticles loaded with streptomycin (STR) was studied. These nanoparticles are highly appropriate for the treatment of bacterial infections and are also promising for the treatment of cancer cells. The analyses involved scanning electron microscopy, dynamic light scattering (DLS) and Z-potential measurements, as well as infrared spectroscopy and X-ray diffraction. Both amorphous (ACP) and crystalline (cHAp) hydroxyapatite nanoparticles were considered since they differ in their release behavior (faster and slower for amorphous and crystalline particles, respectively). The encapsulated nanoparticles were finally incorporated into biodegradable and biocompatible polylactide (PLA) scaffolds. The STR load was carried out following different pathways during the synthesis/precipitation of the nanoparticles (i.e., nucleation steps) and also by simple adsorption once the nanoparticles were formed. The loaded nanoparticles were biocompatible according to the study of the cytotoxicity of extracts using different cell lines. FTIR microspectroscopy was also employed to evaluate the cytotoxic effect on cancer cell lines of nanoparticles internalized by endocytosis. The results were promising when amorphous nanoparticles were employed. The nanoparticles loaded with STR increased their size and changed their superficial negative charge to positive. The nanoparticles’ crystallinity decreased, with the consequence that their crystal sizes reduced, when STR was incorporated into their structure. STR maintained its antibacterial activity, although it was reduced during the adsorption into the nanoparticles formed. The STR release was faster from the amorphous ACP nanoparticles and slower from the crystalline cHAp nanoparticles. However, in both cases, the STR release was slower when incorporated in calcium and phosphate during the synthesis. The biocompatibility of these nanoparticles was assayed by two approximations. When extracts from the nanoparticles were evaluated in cultures of cell lines, no cytotoxic damage was observed at concentrations of less than 10 mg/mL. This demonstrated their biocompatibility. Another experiment using FTIR microspectroscopy evaluated the cytotoxic effect of nanoparticles internalized by endocytosis in cancer cells. The results demonstrated slight damage to the biomacromolecules when the cells were treated with ACP nanoparticles. Both ACP and cHAp nanoparticles were efficiently encapsulated in PLA electrospun matrices, providing functionality and bioactive properties.     

Hydroxyapatite/bioactive glass functionally graded materials (FGM) for bone tissue engineering

In this work, HA/bioactive glass Functionally Graded Materials (FGMs) are obtained for the first time by means of Spark Plasma Sintering (SPS). Two series of highly dense 5 layered products, namely FGMS1 and FGMS2, are prepared under optimized SPS conditions, i.e. 1000 °C/2 min/16 MPa and 800 °C/2 min/50 MPa, respectively, using a die with varying cross section.Results arising from XRD, SEM, mechanical and biological characterization in SBF, evidence that lower temperature and higher-pressure levels used for FGMS2 samples provide better materials in terms of microstructure, compactness, hardness, elastic modulus and in vitro bioactivity. Indeed, a fully sintered and crack-free microstructure with no crystallisation at the top layer (100% bioactive glass) is correspondingly produced.The obtainment of such FGMs is quite promising, since it permits to vary the relative volume fractions of the two constituents and, consequently, tailor the biological response for specific clinical applications.     

A Biomimetic Hybrid Hydrogel Based on the Interactions between Amino Hydroxyapatite and Gelatin/Gellan Gum

In this work, a gelatin (Gel)‐oxidized gellan gum (OG)/amino hydroxyapatite (mHap) hybrid hydrogel with Schiff base linkages is reported. The mHap is obtained by modifying hydroxyapatite with tetraethyl orthosilicate and 3‐aminopropyl‐triethoxysilane. The effects of different mHap contents on the structure, morphology, and properties of hydrogels are particularly investigated. Scanning electron microscopy coupled with energy dispersion spectroscopy reveals that mHap of around 100 nm is uniformly distributed inside the hydrogel with interconnected porous structures. Notably, the hydrogel with 1 wt% mHap possesses the highest compressive stress (2.01 ± 0.10 MPa) at 90% strain, as well as the lowest equilibrium swelling ratio (97% ± 5%) and degradation rate than other hydrogels. Besides, an ultra‐high compressive stress equivalent to 91% of the initial stress can be obtained by this hydrogel after 50 loading‐unloading cycles (85% strain). Meanwhile, after being swollen, this improved hydrogel also exhibits better structural stability than Gel‐OG hydrogel. The in vitro 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium bromide (MTT) assay further shows that all hydrogels are nontoxic against mouse fibroblasts. This work provides a biomimetic strategy to construct the organic/inorganic hydrogels with excellent interactions, elasticity, reversibility, and biocompatibility, which is of great importance for the practical applications in cartilage tissue engineering.     

Size controlled synthesis of well-distributed nano-silver on hydroxyapatite using alkanolamine compounds

A well-distributed nano-silver hydroxyapatite composite has been successfully prepared by a one-pot synthesis method. Hydroxyapatite was separately synthesized by a sol-gel method, then impregnated with silver nanoparticles with the mediation of Uncaria gambir Roxb. leaf extract in the presence of three kinds of alkanolamine compound; monoethanolamine (MEA), diethanolamine (DEA), and triethanolamine (TEA) as capping agents. The effect of different capping agents on the properties of the silver nanoparticles and the nano-silver hydroxyapatite composite were studied. UV–visible spectrophotometer analysis exhibited absorbance peaks at 402–439 nm which specifically corresponds to spherical silver nanoparticles. Higher optical absorbance was observed in TEA-capped silver nanoparticles, than in DEA and MEA-capped ones. X-ray diffraction (XRD) analysis showed a highly crystalline hexagonal structure for hydroxyapatite and no detected metallic silver. However, the presence of 1.65% silver was confirmed by energy dispersive x-ray (EDX) spectroscopy analysis. Transmission electron microscopy (TEM) analysis revealed spherical silver nanoparticles with a size range of 2–62 nm (smallest mean diameter of 2 nm) adhered to the hydroxyapatite surface. The TEA capped impregnated silver nanoparticles were the smallest, corresponding to the best capping performance, followed by those capped by DEA and MEA. Small-sized nanoparticles on hydroxyapatite are beneficial for highly antibacterial bone implants.     

纳米掺锶羟基磷灰石的制备及其抗菌性能研究

以硝酸钙、氯化锶、磷酸氢二氨等为原料,采用溶胶-凝胶-超临界流体干燥法,制备了纳米掺锶羟基磷灰石(SrHAP).通过元素含量分析、TEM、XRD、FT-IR等手段对其结构进行了表征,分析了锶的掺入对羟基磷灰石(HAP)的结构、晶形及结晶度的影响;研究了HAP掺入锶后对大肠杆菌、金黄色葡萄球菌、乳酸杆菌的抗菌性能.结果表明:采用溶胶-凝胶-超临界CO2干燥法,可制备结晶性较好的纳米HAP和Sr/[Sr Ca]原子比为0.5的纳米SrHAP;在给定的条件下,锶可以按化学计量比掺入到HAP的结构中;HAP掺入锶后,其主要官能团红外光谱吸收峰的振动频率降低,晶形从HAP的短棒状改变为SrHAP的针状,结晶度降低,对大肠杆菌、金黄色葡萄球菌、乳酸杆菌的抗菌性能提高.