基于聚多巴胺辅助自组装单分子层技术的PTFE表面修饰及其内皮细胞选择性黏附研究

利用聚多巴胺技术对PTFE进行表面改性,X射线光电子能谱(XPS)、椭偏、接触角以及石英晶体微天平(QCM-D)证实DOPA分子可以在PTFE表面自聚形成反应性的超薄膜功能涂层,并通过聚多巴胺辅助自组装单分子层(SAM)技术构建了活性多肽链段CGREDVDY的界面.细胞黏附实验反映活性链段CGREDVDY的修饰表面具备良好的内皮细胞选择性黏附能力.这种具有内皮细胞选择性黏附能力的界面有望实现材料在复杂生理环境中对内皮细胞的原位诱导,为制备具有血管内皮原位快速愈合功能的新型血液相容性人造血管提供新途径.     

硅表面CS/BSA复合微图形的制备及表征

采用微加工方法在硅表面成功地制备出壳聚糖/牛血清白蛋白(CS/BSA)复合微图形. 借助光镜和荧光显微镜对复合微图形进行形貌分析. 利用大肠杆菌和白色葡萄球菌定量考察了CS/BSA复合微图形的抗菌性能, 结果表明, 硅表面沟槽交叉状CS/BSA复合微图形对两种细菌都具有较好的抗菌效果. 通过MC3T3-E成骨细胞培养考察了复合微图形的细胞相容性, 结果表明, CS/BSA复合微图形对于细胞的生长方向具有较强的诱导性, 可促进细胞在材料表面的黏附、铺展及增殖分化. 结果表明, 采用微转移模塑法制备的CS/BSA复合微图形具有较好的抗菌性和细胞相容性.     

采用层层自组装与光化学修饰法在聚氨酯表面固定生物多糖衍生物

采用层层自组装技术与光化学修饰方法相结合在聚氨酯材料表面固定生物多糖衍生物,首先合成具有光反应活性的叠氮壳聚糖,再在聚氨酯基材表面进行叠氮壳聚糖与香菇多糖硫酸酯的层层自组装,然后通过光化学反应对自组装多层膜修饰层进行交联,制备得到生物多糖衍生物层层自组装与光化学表面修饰的聚氨酯材料.通过红外光谱、X射线光电子能谱、水接触角测量仪、抗菌活性测试、溶血试验和血小板黏附测试等方法对被修饰聚氨酯材料的表面性能和生物性能进行了分析,测试结果表明修饰后的聚氨酯材料表面的亲水性和血液相容性得到改善,并且被修饰材料对大肠杆菌具有良好的抑制效果.     

明胶在聚氨酯表面的固定化及其对内皮细胞生长的促进作用

理想的组织工程支架材料应具备有效促进细胞生长的能力和良好的组织相容性 .然而现有的聚合物生物材料大多呈现疏水性 ,不能有效支持细胞的生长 [1,2 ] .细胞外基质和血清中含有对细胞粘附、生长和繁殖有显著促进作用的多种活性因子 ,如纤维粘连蛋白 ( Fn)、层粘连蛋白 ( L aminin)、胶原( Collagen)、多聚赖氨酸和冷析蛋白 ( CIG)等 [3～ 5] ,把这些因子固定到材料表面 ,可为细胞的粘附生长提供理想的条件 .本文通过碳二酰亚胺脱水缩合技术 ,将明胶 ( Gelatin)共价键合到聚甲基丙烯酸接枝改性的聚氨酯 ( PU- g- PMAA)薄膜表面 ,并初…     

人工细胞外基质对血管内皮细胞生存的影响

通过物理吸附方法, 利用胶原、 聚赖氨酸和融合蛋白VEGF-Fc对聚苯乙烯培养板表面进行改性, 以研究细胞外基质材料对血管内皮细胞的影响. 结果表明, 3种蛋白显著提高了聚苯乙烯表面的亲水性. 内皮细胞的黏附、 增殖、 细胞骨架蛋白染色和血管性血友病因子(vWF)免疫染色实验结果表明, 胶原、 聚赖氨酸和VEGF-Fc基质均能有效提高血管内皮细胞的黏附, 其中胶原可与VEGF协同作用促进内皮细胞分化表型的表达; VEGF-Fc基质兼具了VEGF的生物学活性, 可促进内皮细胞的黏附和增殖以及vWF功能性蛋白的表达. 本研究为诱导材料表面内皮化和血管新生的生物活性材料的设计开发提供了新思路.     

高分子化8-羟基喹啉锂的合成与静电自组装研究

设计合成了甲基丙烯酸二甲氨基乙酯(DM)含量为9.69%的丙烯酸甲酯共聚物(CPA),将制得的5-氯甲基-8-羟基喹啉(CHQ)挂接到CPA上,得到季铵型高分子化8-羟基喹啉(CPA-HQ)后,与金属离子Li+配位得到CPA-HQ-Li.化合物结构通过红外、紫外和荧光光谱等表征.多层超薄膜用CPA-HQ-Li和聚阴离子电解质(全氟磺酸)通过静电自组装制得.自组装膜的紫外和荧光相对于溶液(溶剂为四氢呋喃)发生了红移,膜的紫外吸收强度随组装膜层数增加线性增大,荧光强度随膜层数增加线性递减.高分子化8-羟基喹啉锂溶液和自组装膜的紫外和荧光光谱与文献报道一致.实验结果表明这种材料可用于有机电致发光器件(OLEDs)的制备.     

层层自组装技术在生物医用材料领域中的应用研究进展

基于聚电解质阴阳离子交替组装的层层自组装技术由于可在温和的条件下实现多种生物大分子在材料表面的固定,并通过对组装条件的控制实现多种生物功能,已成为生物医用材料表面设计的重要手段。本文对层层自组装技术在构建血液相容性界面、组织工程表面、药物控释涂层等生物医用材料领域的应用研究进行了比较系统的阐述。     

与胶原特异性结合的BMP2模拟肽/PLGA 3D打印复合支架的制备及成骨诱导活性

将胶原绑定结构域(CBD)多肽序列与骨形态发生蛋白2模拟肽(BMP2-MP)序列连接制备具有胶原绑定能力的CBD-BMP2-MP, 再将CBD-BMP2-MP与聚丙交酯-乙交酯/胶原(PLGA/COL)3D打印支架相结合, 以支架表面的胶原成分为媒介, 将CBD-BMP2-MP更有效地固定于骨修复材料上, 达到对其进行改性的目的. 利用扫描电子显微镜(SEM)、 电子万能试验机和接触角测量仪对复合支架表面形貌、 力学强度和亲水性等材料学性能进行评价. 用荧光成像法评测 CBD-BMP2-MP及BMP2-MP与支架材料的结合能力. 在各组支架材料表面接种MC3T3-E1细胞进行体外培养, 采用CCK-8、 鬼笔环肽荧光染色、 茜素红染色及qPCR综合评价细胞在材料表面的黏附、 增殖和成骨分化等细胞行为, 研究CBD-BMP2-MP修饰的3D多孔PLGA/COL复合支架的生物学性能. 研究结果表明, 利用3D打印技术制备的多孔支架具有形貌可控的孔隙结构, 为细胞生长创造更有利的细胞微环境, 支架表面胶原成分的加入提高了支架材料的亲水性, 同时对支架材料本身的力学性能无任何影响, 提高了复合支架本身的生物相容性. 与普通BMP2-MP相比, CBD-BMP2-MP具有更好的胶原绑定能力, 与复合支架的结合更稳定, 提高了PLGA/COL复合支架对BMP2-MP的负载能力. 支架表面负载CBD-BMP2-MP后具有极强的促细胞成骨分化能力. MC3T3-E1细胞表现出更高的钙沉积能力, 并且成骨分化相关基因Runx2, ALP, COL-I及OPN等水平也有了明显提升. 表明CBD-BMP2-MP多孔复合支架具有良好的生物相容性和成骨诱导活性, 在骨组织修复领域具有良好的应用前景.     

p(HEMA-MMA)表面固定I-型胶原和碱性成纤维生长因子(bFGF)改善细胞相容性的研究

材料表面固定生物分子一直都被认为是其提高其细胞相容性有效的途径。本文采用羧基二咪唑(CDI)作为缩合剂,使p(HEMA-MMA)表面羟基与胶原中氨基发生缩合反应,从而将I-型胶原接枝在材料表面。然后利用"接枝-吸附"的方法,将I-型胶原和bFGF混合层吸附固定于材料表面,形成稳定的胶原与bFGF涂层。红外光谱(FTIR)和原子力显微镜(AFM)证实了该种固定方法的成功。静态接触角显示材料表面亲水性较改性前略微降低。涂层稳定性实验结果表明在类似人体环境(pH=7.4)下涂层具有良好的稳定性。细胞粘附性实验以及MTT实验一致显示改性后材料的细胞相容性得到明显提高。因此,Col/bFGF-p(HEMA-MMA)有望成为能够被宿主机体所接受的生物材料。     

聚羟基脂肪酸酯的亲水性改性及其与人脐静脉内皮细胞相容性的研究

用丝素蛋白(SF)对微生物合成的高分子聚合物聚(3-羟基丁酸酯-co-3-羟基己酸酯)(PHBHHx)进行亲水改性,以提高材料的生物相容性.水接触角测定和表面自由能分析表明,丝素蛋白在支架表面吸附,使PHBHHx材料表面的水接触角从90°降至51°,表面自由能从37.9 mJ/m2增至57.4 mJ/m2,因而增加了材料的亲水性.进一步对亲水性改性前后PHBHHx多孔支架与人脐静脉内皮细胞(HUVECs)的相容性进行了比较.MTT法细胞活力分析表明,细胞在支架上培养3,5,7天后,其在SF改性PHBHHx多孔支架上的活力显著高于在未改性的PHBHHx支架上的活力;扫描电镜观察细胞生长形貌表明,细胞在改性后多孔支架上黏附及生长5天后,形成了连续细胞单层,其生长状态优于在未改性的PHBHHx支架上的生长状态;胶原含量测定表明细胞在改性后支架上比在未改性支架上有更好的胶原分泌能力,即改性后支架更利于诱导HUVECs分泌细胞外基质(ECM)从而构建类似体内的生长环境.     

型胶原在聚-L-乳酸(PLLA)表面的化学接枝和涂层及其对软骨细胞生长的促进作用

采用接枝-涂层技术在聚-L-乳酸(PLLA)膜表面接枝聚甲基丙烯酸(PMAA)得到稳定的PLLA-g-PMAA胶原涂层.利用水溶性碳化二亚胺作为缩合剂,使PLLA-g-PMAA表面的羧基和胶原分子中的氨基发生缩合反应,从而将型胶原接枝在PLLA表面;同时保留材料表面物理涂层的胶原溶液,获得了稳定的胶原涂层.XPS谱图证实了接枝反应的发生.分别用比色法和茚三酮法测定了PLLA-g-PMAA表面的羧基密度和PLLA膜表面胶原的接枝量和涂层量.细胞培养结果表明,改性后的PLLA膜表面软骨细胞的铺展性能和增长速度明显改善.     

Fabrication of Layer-by-layer Films of Polyhedral Oligomeric Silsesquioxanes

Layer-by-layer(LBL)self-assembly method was used to fabricate siliceous ultrathin films by using polyhedral oligomeric silsesquioxanes as building blocks.Ammonium salt of kctasilsesquioxane acid (OSi8) and bply(diallyldimethylammonium chloride)(PDDA) were altermately assembled onto CaF2 slide to form nanocomposite multilqyers,Linear build-up of the LBL films was confirmed by UV-Vis spectroscopy.IR spectrum suggests existence of OSi8 and PDDA in the LBL films.Atomic force microscopic surface topography of the LBL films indicates the OSi8 covers the entire surface of the topmost layer and shows a granular morphology.     

Microscale control over collagen gradient on poly(L-lactide) membrane surface for manipulating chondrocyte distribution

A collagen gradient was constructed to interrogate cell adhesion on a poly(L-lactide) (PLLA) membrane surface. Utilizing a microinfusion pump, gradients of amino groups were generated on the PLLA surface by an aminolysis method. Immobilization of collagen onto the gradient surfaces was performed by glutaraldehyde (GA) coupling to form the collagen gradients. The -NH(2) and immobilized collagen density profiles on the PLLA membranes were quantitatively determined by ninhydrin and hydroproline (Hyp) analysis, respectively. By using fluorescein isothiocyanate (FITC) labeled collagen (FITC-Col), the profile of the as-prepared collagen gradient was directly monitored by a fluorescence microscope. The scanning force microscopy and water contact angle studies revealed that the morphology and wettability of the modified membranes changed progressively as a function of position along the gradient surface. Rabbit auricular chondrocytes were cultured on the collagen gradient membranes to test their cellular response. The attachment and spreading behaviors of the chondrocytes were dependent on the surface collagen density. These results indicate a surface on which the variation of collagen gradient strongly modifies the biological response of chondrocytes.     

Surface modification of poly(tetramethylene adipate-co-terephthalate) membrane via layer-by-layer assembly of chitosan and dextran sulfate polyelectrolyte multiplayer

The improvement of hydrophilicity and hemocompatibility of poly(tetramethylene adipate-co-terephthalate) (PTAT) membrane was developed via polyelectrolyte multilayers (PEMs) immobilization. The polysaccharide PEMs included chitosan (CS, as a positive-charged and antibacterial agent) and dextran sulfate (DS, as a negative-charged and anti-adhesive agent) were successfully prepared using the aminolyzed PTAT membrane in a layer-by-layer (LBL) self-assembly manner. The obtained results showed that the contact angle of as-modified PTAT membranes reached to the steady value after four bilayers of coating, hence suggesting that the full coverage was achieved. It could be found that the PTAT–PEMs membranes with DS as the outmost layer could resist the platelet adhesion and human plasma fibrinogen (HPF) adsorption, thereby prolonging effectively the blood coagulation times. According to L929 fibroblast cell growth inhibition index, the as-prepared PTAT membranes exhibited non-cytotoxic. Overall results demonstrated that such an easy, valid and shape-independent processing should be potential for surface modification of PTAT membrane in the application of hemodialysis devices.     

以重氮树脂与4-甲酰基苯甲酸为底层构筑三联吡啶-钌离子层-层自组装超薄功能膜

在呈负电性的基底表面依次使用重氮树脂(DR)、4-甲酰基苯甲酸(FBA)和4-′(4-氨基苯基)-2,2′:6′,2″-三联吡啶(Atpy)进行修饰,在先后经过离子键转变为共价键和希夫碱反应后,实现了2,2′:6′,2″-三联吡啶基团在基片表面的锚定;然后基于配位作用,由1,4-二(2,2′:6′,2″-三联吡啶-4′-基)苯(Bi-tpy)与RuCl3在其表面构筑具有纳米尺寸的金属-有机超分子超薄膜.紫外-可见光谱、AFM均证明了这种层层自组装超薄膜的成功形成.光电转换显示其具有良好的光电转换性能和光化学稳定性,其转换效率与膜的厚度呈现较好的线性关系.     

一种基于立构复合及自组装方法构筑的耐受性疏水表面

利用丙交酯开环聚合法制备了聚(D-乳酸)-聚二甲基硅氧烷-聚(D-乳酸)(PDLA-b-PDMS-b-PDLA)三嵌段聚合物,将其溶液涂覆至充斥着非溶剂蒸汽的聚(L-乳酸)(PLLA)表面,PDLA-b-PDMS-b-PDLA在缓慢沉积的过程中与PLLA发生立构复合及自组装,得到由立构复合的亚微米颗粒组装体形成的聚乳酸表面疏水层。 研究了聚合物溶液的质量浓度、组装温度以及溶剂对聚乳酸表面的微观形貌和疏水性能产生的影响。 结果表明,随着PDLA-b-PDMS-b-PDLA聚合物溶液质量浓度的增加,可以实现聚乳酸表面Wenzel-Cassie-Wenzel的疏水行为转变;在0 ℃下,可得到最大疏水角151°的疏水层;选择对聚合物溶解性、挥发速度不同的溶剂,得到的表面微观形貌和疏水性也不同。 由于聚乳酸制品表面的PLLA链段与亚微米颗粒中的PDLA链段也能够立构复合,因此该表面疏水层对刀刮、胶带剥离和手指擦拭测试均表现出良好的耐受性。     

Surface modification of poly(ethylene terephthalate) via hydrolysis and layer-by-layer assembly of chitosan and chondroitin sulfate to construct cytocompatible layer for human endothelial cells

Surface modification of poly(ethylene terephthalate) (PET) film was performed by surface hydrolysis and layer-by-layer (LBL) assembly followed a mechanism of electrostatic adsorption of oppositely charged polymers, exemplified with chitosan and chondroitin sulfate (CS). Hydrolysis of PET in concentrated alkaline solution produced a carboxyl-enriched surface. The changes of weight loss and surface chemistry, morphology and wettability were monitored and verified by UV-vis spectroscopy, atomic force microscopy (AFM) and water contact angle. Assembly of positively charged chitosan and negatively charged CS was then conducted in a LBL manner to create multilayers on the hydrolyzed PET film. The process of layer growth and oscillation of surface wettability were monitored by UV-vis spectroscopy and water contact angle measurement, respectively. In vitro cell culture revealed that the adherence of endothelial cells was significantly enhanced on the biomacromolecules-modified PET film with preserved endothelial cell function, in particular on those assembled with larger number of chitosan/CS layers. However, with regard to cell proliferation and viability properties after cultured for 4 days, minor difference was determined between the modified and the unmodified PET films.     

Layer-by-layer self-assembly of TiO<Subscript>2</Subscript> sol on wool to improve its anti-ultraviolet and anti-ageing properties

A new method for improving the anti-ultraviolet and anti-ageing abilities of wool fabric was reported in this paper. TiO₂ sols and poly (sodium 4-styrene-sulfonate) (PSS) were coated on the wool fibers via layer-by-layer (LBL) electrostatic self-assembly deposition. The morphologies and compositions of TiO₂ sol-coated wool fabrics were characterized using SEM, surface Zeta potential, apparent color depth (K/S), ultraviolet (UV) transmission and alkali solubility. The SEM pictures showed that there were quite a few deposits absorbed on the wool surface. The dyeing depth and Zeta potential presented obvious “layer–layer alternate vibration” along with the change of deposited materials, revealing the surface structure of the assembled wool fiber. The results of ultraviolet (UV) transmission and alkali solubility indicated that the modified wool fabrics obtained good anti-ultraviolet and anti-ageing properties. In addition, the sol-assembled wool fabrics had good washing fastness. The studies proved that the LBL electrostatic self-assembly deposition is a promising way to endow the textiles with surface functionality.     

Enhanced interlayer interaction in cellulose single nanofibre and poly(l-lactic acid) layered films by plasma-initiated surface grafting of poly(acrylic acid) onto poly(l-lactic acid) films

The surface of a poly(l-lactic acid) (PLLA) film was modified with poly(acrylic acid) (PAA) by plasma-initiated polymerization to increase the interaction between PLLA and cellulose single nanofibres (CSNF). The surface wettability of the PAA grafted PLLA film (PLLA-PAA film) was investigated by contact angle measurements. Modification of the PLLA film with PAA decreased the contact angle from 61° to 50°. The surface morphologies of the PLLA film, PLLA-PAA film and CSNF-coated PLLA-PAA film were studied by atomic force microscopy. The interaction between the CSNF and PLLA layers was strengthened by incorporation of a PAA layer onto the PLLA films and it is higher than 2N as proved by a peeling test. This is probably because the carboxyl groups of PAA form hydrogen bonds with the hydroxyl groups of CSNF.     

Surface modification of cellulose fibers with layer-by-layer self-assembly of lignosulfonate and polyelectrolyte: effects on fibers wetting properties and paper strength

To convert the hydrophilic cellulose fiber into hydrophobic, multilayers composed of cationic polyacrylamide (CPAM) and lignosulfonate (LS) were constructed on cellulose fiber surface using layer-by-layer (LBL) self-assembly technique. The presence of CPAM/LS multilayers were validated by zeta potential, X-ray photoelectron spectroscopy and atomic force microscopy (AFM). It was found that potential of fiber surface inversed after deposition of each layer, the contents of characteristic elements (i.e. S and N) of CPAM/LS multilayers increased with increasing bilayer number, furthermore, the calculated surface LS content increased linearly as a function of bilayers. AFM phase images indicated that the cellulose microfibrils on fiber surface were gradually covered by LS granules, resulting in an increase in fiber surface roughness as self-assembly proceeded. The wetting properties of modified cellulose fibers were detected by dynamic contact angle measurement. The results showed that the initial water contact angle gradually increased and the attenuation rate of the contact angle gradually decreased with the number of bilayers, suggesting that the controllable hydrophobicity of cellulose fiber can be achieved depending on the number of bilayers. It also showed that the polyelectrolyte presented in the outermost layer significantly influenced the wetting properties of cellulose fibers, and a higher hydrophobicity was observed when LS was in the outermost layer. Moreover, tensile strength test was performed on the handsheet prepared from LBL modified fibers to evaluate the effect of CPAM/LS multilayers on strength property of cellulose fiber networks. The tensile index of handsheet prepared from fibers modified with a (CPAM/LS)₅ multilayer increased by 12.4% compared with that of handsheet prepared from original fibers. The print density of handsheet increased with the number of bilayers, suggesting that printability of the handsheet was improved by constructing CPAM/LS multilayers on cellulose fiber surface. This strategy will have a positive impact and potential application value in printing process control of cellulose fiber-based products.