可降解镁金属材料表面钙磷复合物涂层处理的研究进展

镁金属材料是一种新型的可降解医用材料,因其可降解、生物相容性好、力学性能佳、可诱导骨生长等优点,具有良好的应用前景。但是由于耐腐性差其临床应用目前仍受到限制。在镁金属材料表面进行表面处理是目前研究中常用的提高耐腐性的方法,钙磷复合物涂层是其中最常见的表面处理方式之一。本文从涂层制备方法、成骨活性、机械性能、生物学性能等几方面对近年来镁金属材料表面钙磷复合物涂层处理的研究进行了总结,发现钙磷复合物涂层是一种很有潜力的能够将镁金属材料推向临床应用的表面处理方法,但在应用于临床前仍需进行深入、系统的研究。

紫杉醇水蛭素支架涂层复合物对HCASMC炎性活化过程中TLR4-MyD88信号通路的影响

目的探讨支架涂层复合物紫杉醇水蛭素对脂多糖(LPS)诱导人冠状动脉平滑肌细胞(HCASMC)炎性活化过程中TLR4-MyD88信号通路的影响。方法选用4-6代的HCASMC,用四唑盐(MTT)比色法筛选出紫杉醇水蛭素支架涂层复合物干预HCASMC的无毒性大、小两个浓度,使细胞活力保持在90%以上。进而将细胞分为空白对照组、脂多糖(LPS)造模组、LPS造模+紫杉醇水蛭素大浓度组、LPS造模+紫杉醇水蛭素小浓度组,其中大、小浓度紫杉醇水蛭素复合物处理组在LPS造模前预处理细胞4 h,继而用Q-PCR法对TLR4和MyD88 mRNA进行检测,并用Western blotting法检测对应蛋白表达的变化。结果 1μmol/L的紫杉醇配比0.8 mg/ml水蛭素对HCASMC生长有明显的抑制作用,细胞活力与空白对照组相比差异明显(P<0.05)。1μmol/L的紫杉醇配比0.4 mg/ml水蛭素干预后细胞活力降低为78.7%,对细胞生长产生了一定影响,其余各浓度组细胞活力均能保持在90%以上。紫杉醇水蛭素复合物预处理细胞4 h后,Q-PCR结果显示,与空白对照组相比,LPS造模后可同时激活TLR4、MyD88的mRNA表达(P<0.05),HCASMC炎症模型构建成功。各干预组经紫杉醇水蛭素处理后,与单纯LPS模型组相比,TLR4的mRNA基因表达量显著降低(P<0.05),但不影响MyD88基因表达(P>0.05)。Western blotting结果显示:与空白对照组相比,LPS模型组TLR4、MyD88蛋白表达明显升高(P<0.05),成功构建了稳定的HCASMC炎症模型。经紫杉醇水蛭素处理后,各干预组TLR4、MyD88蛋白表达较LPS模型组显著降低(P<0.05),其中紫杉醇水蛭素大浓度组的抗炎作用相对更强。结论紫杉醇水蛭素支架涂层复合物对LPS诱导的HCASMC细胞炎性活化过程中TLR4-MyD88通路的激活具有明显的抑制作用,此抑制作用不通过影响MyD88基因表达来产生,而可能与其对MyD88蛋白水平的调控有关。

紫杉醇-比伐卢定球囊涂层复合物调控NF-κB与Nrf2/ARE通路抗HCASMC增殖迁移的机制研究

目的 基于人冠状动脉平滑肌细胞(HCASMC)核因子κB(NF-κB)与重组合成蛋白2/抗氧化反应元件(Nrf2/ARE)双通路活化模型探索紫杉醇-比伐卢定球囊涂层复合物(LFN)抑制HCASMC增殖迁移抗介入术后再狭窄的微观机理。方法 选用4~6代的HCASMC,利用脂多糖(LPS)作为诱导剂,最大化激活NF-κB与Nrf2/ARE双通路,构建LPS诱导HCASMC炎性和氧化应激双通路活化细胞模型。在此基础上,将体外培养的HCASMC分为空白对照组、LPS造模组及LPS造模+LFN复合物干预组,用CCK-8法检测LFN对HCASMC增殖率的影响,同时用免疫荧光法检测增殖细胞核抗原(PCNA)表达量确证细胞增殖状态。进而用Transwell法检测LFN对HCASMC迁移、侵袭能力的影响,并用免疫荧光单染法检测α平滑肌肌动蛋白(α-SMA)、骨桥蛋白(OPN)、NF-κB p65和Nrf2的表达变化,探索LFN对HCASMC表型转化的影响,并探究其对HCASMC中活化的NF-κB与Nrf2/ARE通路关键蛋白的调控作用,继而结合Q-PCR和Western blotting明确LFN干预后双通路关键位点基因和蛋白表达的变化,深入挖掘LFN调控炎性和氧化应激活化的HCASMC增殖迁移的潜在机制。结果 1μmol/L的紫杉醇配比0.2 mg/ml比伐卢定对造模活化后的HCASMC增殖状态具有明显抑制作用,减弱了HCASMC迁移和侵袭能力,并将活化后分泌型的HCASMC转换为收缩型。此外,与LPS造模组相比,LFN通过激活人核因子κB抑制蛋白α(IκBα)表达、阻碍NF-κB活化入核,截断了炎症过程,同时抑制胞质接头蛋白1(Keap-1)表达、促进Nrf2核转位、激活下游醌氧化还原酶1(NQO-1)和人血红素加氧酶1(HO-1)基因和蛋白表达(P<0.05),大幅减缓了胞内氧化应激状态。结论 LFN对NF-κB与Nrf2/ARE双通路活化的HCASMC胞内炎症和氧化应激状态具有显著抑制作用,此抑制作用通过调控NF-κB与Nrf2/ARE通路中核转录因子及其配体表达、影响通路下游效应分子活化而实现,为LFN涂层球囊抗经皮冠状动脉介入治疗(PCI)术后再狭窄的分子机理提供了细胞学依据。

Microstructure and wear resistance of laser clad TiB-TiC/TiNi-Ti_2Ni intermetallic coating on titanium alloy

A wear resistant TiB-TiC reinforced TiNi-Ti2Ni intermetallic matrix composite coating（TiB-TiC/TiNi-Ti2Ni） was prepared on Ti-6.5Al-2Zr-1Mo-1V titanium alloy by the laser cladding process using Ti＋Ni＋B4C powder blends as the precursor materials.Microstructure and worn surface morphologies of the coating were characterized by optical microscopy（OM）,scan electron microscopy（SEM）,X-ray diffraction（XRD）,energy dispersive X-ray analysis（EDS） and atomic force microscopy（AFM）.Wear resistance of the coating was evaluated under dry sliding wear test condition at room temperature.The results indicate that the laser clad coating has a unique microstructure composed of flower-like TiB-TiC eutectic ceramics uniformly distributed in the TiNi-Ti2Ni dual-phase intermetallic matrix.The coating exhibits an excellent wear resistance because of combined action of hard TiB-TiC eutectic ceramic reinforcements and ductile TiNi-Ti2Ni dual-phase intermetallic matrix.

Microstructure and formation mechanism of in-situ TiC-TiB_2/Fe composite coating

Steel matrix composite coatings locally reinforced with in situ TiC-TiB2 particulates were prepared by argon arc cladding(AAC) with different mass fractions of Fe and Ti+B4C powders as the binding materials. The microstructure, micro-hardness and wear resistance were investigated using SEM, XRD, Micro-hardness Tester, and Friction and Wear Tester, respectively. The results show that the main phases of coating are TiC, TiB2 and α-Fe. The excellent metallurgical bonding is formed between the composite coating and substrate. The coating is uniform, continuous and almost defect-free and the particles are dispersively distributed in the cladded coating. Moreover, the formation mechanism was investigated. With the increase of the content of TiC+TiB2, the micro-hardness and wear resistance are also improved at the room temperature under normal atmosphere conditions.

Antisepsis and Fresh-keeping Effects of Natamycin Coating Compounds Treatment on Red Global Grape

The aim was to research fresh-keeping effects of natamycin on cold-pre- served grape. Red globe grapes were processed with compound coating liquid of chitosan with mass fraction at 1% and natamycin with mass fractions at 0.20% （T1）, 0.40% （T2） and 0.60% （T3）, respectively. Grapes processed with water （CK3） and 1% chitosan （CK2） were taken as control groups. Rotten rate, seed shattering rate, mass loss rate, respiratory intensity and related physiological quality in test and control groups were compared. The results indicated that respiratory intensity, mass loss rate, rotten rate and seed shattering rate in CK1 were all higher than those in CK2. In addition, T1, T2 and T3 were lower in the indices than CK1 and CK2, but still kept at a high level in fruit hardness. Furthermore, mass fractions of Vc and titratable acid declined more slowly in T1, T2 and T3, compared with CK1 and CK2. Natamycin better preserved grapes and prolonged storage period. In general, natamycin with mass fraction at 0.4% proved best in fresh-keeping.

Oxidation and hot corrosion of electrodeposited Ni-7Cr-4Al nanocomposite

A Ni-7Cr-4Al（mass fraction, %） nanocomposite was fabricated by co-electrodeposition of Ni with Cr（40 nm） and Al（100 nm） nanoparticles from a nickel sulfate bath, and its oxidation at 800 °C in air and hot corrosion under molten 75% Na2SO4 ＋ 25% Na Cl salts（mass fraction） at 750 °C were investigated. For comparison, Ni-11 Cr nanocomposite and Ni-film were also investigated in order to elucidate the effect of Cr nanoparticles. The results indicate that Cr and Al nanoparticles are dispersed in the electrodeposited nanocrystalline Ni grains（in size range of 20-60 nm）. Ni-7Cr-4Al nanocomposite exhibits a dramatically increased oxidation resistance compared with Ni-11 Cr nanocomposite and Ni-film due to the fast formation of alumina scale, which also improves its hot corrosion resistance under molten 75% Na2SO4 ＋ 25% Na Cl salts.

In-situ synthesis of Al_3Ti particles reinforced Al-based composite coating

Using titanium wires （99.5%, 200 μm in diameter） as a reactive source, an Al-based composite coating reinforced by titanium tri-aluminide （A13Ti） particles was fabricated by infiltration plus in-situ methods. According to the differential thermal analysis （DTA） curve, the reactive temperature between Ti wires and A1 matrix can be determined at 890 ℃. The obtained composite coatings were characterized by X-ray diffraction （XRD）, scanning electron microscopy （SEM）, and microhardness and wear test. The experimental results show that when holding period is 20 min at 890℃, the titanium wires react completely to in-situ synthesize Al3Ti particles, which presents blocky and strip-like states. The microhardness of in-situ synthesized Al3Ti particles is about 4.5 times that of the Al-matrix. Under the condition of dry sliding at 10 N load, compared with the unreinforced Al matrix, the composite coating fabricated with 20 min offers unique wear resistance behavior, and its wear mechanism is that the adhesive wear and abrasive wear coexist.

Effect of MoSi_2 content on dielectric and mechanical properties of MoSi_2/Al_2O_3 composite coatings

Molybdenum disilicide （MoSi2） sheath and aluminum oxide （Al2O3） core blended powders were fabricated by spray drying. A derived coating material was produced for the application as microwave absorbers using the as prepared powders by atmospheric plasma spray （APS） technology. The effects of MoSi2/Al2O3 mass ratio on the dielectric and physical mechanical properties of the composite coatings were investigated. When the MoSi2 content of the composites increases from 0 to 45%, the flexure strength and fracture toughness improve from 198 to 324 MPa and 3.05 to 4.82 MPa-m1/2 then decline to 310 MPa and 4.67 MPa-m1/2, respectively. The dielectric loss tangent increases with increasing MoSi2 content, and the real part of permittivity decreases conversely over the frequency range of 8.2-12.4 GHz. These effects are due to the agglomeration of early molten MoSi2 particles and the increase of the electrical conductivity with increasing MoSi2 content.

A facile method for fabrication of nano-structured Ni-Al_2O_3 graded coatings: Structural characterization

Powder charges of micron-size Ni and Al2O3were utilized to deposit nano-structured Ni-Al2O3composite coatings on analuminum plate fixed at the top end of a milling vial using a planetary ball mill.Composite coatings were fabricated using powdermixtures with a wide range of Ni/Al2O3mass ratio varying from1:1to plain Ni.XRD,SEM and TEM techniques were employed tostudy the structural characteristics of the coatings.It was found that the composition of the starting mixture strongly affects the Al2O3content and the microstructure of the final coating.Mixtures containing higher contents of Al2O3yield higher volume fractions of theAl2O3particles in the coating.Though Ni-Al2O3composite coatings with about50%of Al2O3particles were successfully deposited,well-compacted and free of cracks and/or voids coatings included less than20%(volume fraction)of Al2O3particles which weredeposited from powder mixtures with Ni/Al2O3mass ratios of4:1or higher.Moreover,mechanical and metallurgical bondings arethe main mechanisms of the adhesion of the coating to the Al substrate.Finally,functionally graded composite coatings withnoticeable compaction and integrity were produced by deposition of two separate layers under identical coating conditions.

Biodegradation behavior of polymethyl methacrylate−bioactive glass 45S5 composite coated magnesium in simulated body fluid

The biodegradation behavior of Mg,coated by polymethyl methacrylate as well as polymethyl methacrylate(PMMA)−bioactive glass(BG)composite was investigated.Electrophoretic deposition and dip coating techniques were adopted to prepare composite coating using a suspension of different percentages of the above two chemical materials.The deposited coatings were characterized using SEM,EDS,FTIR,and water contact angle measurements.Biodegradation behavior study of the coated Mg was performed using linear polarization,impedance spectroscopy,and immersion tests in simulated body fluid.The compact and homogeneous composite coating was developed as evidenced by electron microscopy results.The water contact angle measurement showed a 44°increase in the contact angle of the composite coated Mg compared to the uncoated one.The composite coating was covered by a bone-like hydroxyapatite layer after 336 h,indicating that the coating has an excellent in vitro bioactivity.The electrochemical testing results confirmed a significant reduction,96.9%,in the biodegradation rate of Mg coated with the composite prepared from 45 g/L PMMA+3.5 g/L 45S5 GB suspension compared to that of the uncoated one.Therefore,the composite coated Mg can be proposed as a promising material for biodegradable implant application.

Influence of Heat Treatment on Microstructure and Sliding Wear Behavior of Fe-Al/WC Composite Coatings

An experimental study has been carried out to investigate the influence of heat treatment at 300 ℃,450 ℃,550 ℃,650 ℃ and 800 ℃ on the microstructure and sliding wear behavior of Fe Al/WC intermetallic composite coatings produced by high velocity arc spraying (HVAS) and cored wires. The result shows, the main phases in both as sprayed and heat treated Fe Al/WC composite coatings are iron aluminide intermetallics (Fe 3Al+FeAl) and α as well as a little oxide (Al 2O 3) and carbides (WC, W 2C, Fe 2W 2C and Fe 6W 6C). After heat treated at 450-650 ℃, dispersion strengthening of Fe 2W 2C and Fe 6W 6C will lead to a rise in microhardness of the coatings. The microhardness is likely to be the most important factor which influences the sliding wear behavior of the coatings. Increasing the microhardness through heat treatment will improve the sliding wear resistance of the Fe Al/WC composite coatings.

Organic-magnesium complex conversion coating on AZ91D magnesium alloy

An organic-magnesium complex conversion(OMCC)coating on AZ91D magnesium alloy was obtained by treating in a solution containing organic compounds.SEM,FESEM and XPS were used to examine the surface morphology,thickness and structure of the conversion coatings.The results show that the continuous and uniform conversion coating is deposited on AZ91D alloy and the main component of the coatings is organic compound containing benzene ring,which forms a chemical bond with magnesium.The polarization measurement and salt spray test show that the corrosion resistance of the conversion coating is much higher than that of traditional chromate conversion coating.