聚乙烯表面接枝聚合改性及抗凝血性的研究

聚乙烯(PE)膜经Ar等离子体预处理,无光引发剂紫外光照接枝甲基丙烯酸缩水甘油酯(GMA),然后进行肝素化处理,以改善PE的抗凝血性能。用正交实验确定接枝反应的最优条件。通过X-射线光电子能谱(XPS)、衰减全反射红外光谱(ATR-FTIR)、扫描电子显微镜(SEM)和接触角测定PE膜接枝GMA前后表面性能和表面形貌。用复钙时间、凝血酶原时间、部分凝血活酶时间、凝血酶时间和血小板粘附实验对其抗凝血性能进行评价,结果表明,被修饰PE膜的抗凝血性能显著提高。     

反应性梳状聚乙二醇改性聚酯薄膜表面及其内皮细胞相容性的研究

以高密度梳状PEG(CPEG)作为表面改性材料, 将PEG末端羟基转化为醛基, 将梳状PEG和线形PEG固定在氨基化的PET膜表面, 并利用表面的反应性醛基进一步固定了氨基酸和整合素配体多肽片段RGD多肽. 红外光谱、 接触角和X射线光电子能谱(XPS)测定结果表明, 该法可有效地固定氨基酸和多肽, 获得模拟细胞膜中多糖-蛋白质复合物结构的特异性功能表面. 对两种不同结构的PEG细胞培养实验结果表明, CPEG比线形PEG(LPEG)具有更好的抗非特异粘附性. 此外, CPEG比LPEG具有更多的活性反应基团, 用PEG末端活性的醛基固定整合素配体多肽片段RGD, 可有效地诱导材料表面的内皮细胞化, 改善材料的细胞相容性.     

具有抗凝性能的肝素化ε-己内酯/L-丙交酯共聚酯的合成及电纺丝加工

以辛酸亚锡为催化剂,1,4-丁二醇为引发剂,制备出ε-己内酯/L-丙交酯共聚酯(PLCL).以1-(3-二甲氨基丙基)-3-乙基碳二亚胺/N-羟基琥珀酰亚胺为缩合剂将肝素连接在PLCL两侧端基上.采用1HNMR技术测定了共聚酯端基的肝素化率;用XPS分析了肝素化后聚酯中N和S含量,利用甲苯胺蓝紫外分光光度计法测定了表面肝素含量,并根据静态接触角测定结果讨论了材料表面的亲水性变化.凝血酶原时间、凝血酶时间和部分凝血活酶时间测试数据表明,肝素化后PLCL的抗凝血性能得到明显改善.探索了该共聚酯进行电纺丝加工的可行性.     

具有抗凝性能的肝素化ε-己内酯/L-丙交酯共聚酯的合成及电纺丝加工

以辛酸亚锡为催化剂, 1,4-丁二醇为引发剂, 制备出ε-己内酯/L-丙交酯共聚酯(PLCL). 以1-(3-二甲氨基丙基)-3-乙基碳二亚胺/N-羟基琥珀酰亚胺为缩合剂将肝素连接在PLCL两侧端基上. 采用 1H NMR技术测定了共聚酯端基的肝素化率; 用XPS分析了肝素化后聚酯中N和S含量, 利用甲苯胺蓝紫外分光光度计法测定了表面肝素含量, 并根据静态接触角测定结果讨论了材料表面的亲水性变化. 凝血酶原时间、凝血酶时间和部分凝血活酶时间测试数据表明, 肝素化后PLCL的抗凝血性能得到明显改善. 探索了该共聚酯进行电纺丝加工的可行性.     

肝素杂化材料的制备及抗凝血性质的初步研究

以甲苯二异氰酸酯(TDI)中的-NCO基与纳米金属氧化物表面的羟基发生反应,得到改性纳米金属氧化物,并使其与肝素钠(Heparin)进行接枝反应生成肝素杂化材料,结合红外、热重、扫描电镜(SEM)等表征方法,确定纳米金属氧化物确实接枝到了肝素钠的表面。通过对体外凝血时间和复钙时间的测定,来初步研究肝素杂化材料的抗凝血性质。结果表明：肝素杂化材料的抗凝血时间和复钙时间均比肝素钠的要短,表明它的抗凝血性比肝素钠的抗凝血性要弱一些;但比纳米金属氧化物和空白组的抗凝血时间和复钙时间要长,说明肝素杂化材料的抗凝血性与其相比则有明显的提高。     

基于多巴胺自聚合及肝素固定改善钛的血液相容性

利用多巴胺自聚合及肝素固定的方法对纯钛进行表面修饰, 以改善其血液相容性. 采用水接触角测量、 X射线光电子能谱(XPS)和甲苯胺蓝法(TBO)等方法对所修饰的材料进行了表征. 采用溶血实验检测了材料的溶血性能, 并结合活化部分凝血活酶时间(APTT)测试和血小板黏附实验对所修饰材料的血液相容性进行了评价. 结果表明, 多巴胺能够在钛表面实现自聚合, 肝素可以共价接枝在聚多巴胺层上, 经肝素修饰后的材料的表面亲水性显著提高, 而且具有较低的溶血率, APTT时间显著延长, 血小板的黏附数量和被激活程度也显著降低. 因此, 纯钛经多巴胺自聚合以及肝素接枝修饰后的血液相容性得到了显著改善, 有望成为具有抗凝血功能的新型心血管植入材料.     

环状构象PEG改性表面及其优越的抗凝血性能

聚乙二醇(PEG)因其优异的抗蛋白质吸附能力成为抗凝血材料的首选.目前,多数研究都集中在PEG链长和接枝密度对蛋白质吸附的影响,鲜有关注PEG链构象影响的研究.本文利用硫金键在石英晶体微天平金片表面构建了两种不同分子量(MW=1000和MW=5000)的环状(SH-PEG-SH)和线型(m PEG-SH)构象的PEG改性表面,并研究了其抗纤维蛋白原吸附机理和抗凝血性能.X射线光电子能谱仪和原子力显微镜确定了不同表面的组成及其相结构.结果发现,环状构象的PEG表面相对于线型PEG构象能更加有效地抑制纤维蛋白原的吸附,同时具有更加优异的抗血小板和红细胞黏附性能.分析其蛋白质吸附机理发现,当PEG分子量较低时(MW=1000),其环状构象PEG表面抗纤维蛋白原吸附机理源于较高的表面覆盖率;当PEG分子量较高时(MW=5000),其抗纤维蛋白原吸附机理源于高黏弹性和高表面覆盖率共同作用的结果.本工作为构建抗凝血涂层提供了新的思路,并为制备高性能生物医用材料提供了理论基础.     

共价键合多层肝素薄膜修饰涂有硅橡胶的人工血管

报道一种采用医用硅橡胶涂层作软支撑共价键合多层肝素薄膜修饰人工血管等生物医学装置使其表面具有抗凝血性能的方法. 该项技术首先在人工血管的表面上涂上医用硅橡胶作为软支撑, 再在硅橡胶涂层的表面上涂上全氟磺酸(Nafion), 为接下来的层层静电组装提供活性基团. 然后将带正电荷的二苯胺重氮树脂(PA)和带负电荷的肝素分子(Hep)通过静电吸引作用交替沉积到全氟磺酸涂层的表面上. 紫外可见吸收光谱和傅立叶红外光谱数据表明, 在紫外光照射下, 重氮树脂的重氮基团与肝素的硫酸基团之间发生光化学反应, 生成硫酸酯, 使膜内层间离子键转变成共价键, 从而使肝素多层膜的稳定性大大提高. 研究表明经层层自组装和光化学反应后肝素分子呈现良好的抗凝血性能. 人工血管肝素化表面中的肝素分子以壁面结合的方式存在, 在人工血管表面固化肝素和抗凝血酶-III (AT-III)形成的络合物显示出较好的抗凝血性. 硅橡胶涂层使肝素分子与人工血管表面有一定距离, 有利于提高抗凝血性能. 在四个双层之内, 肝素对凝血酶失活的影响随着PA/Hep双层数目增加而增加, 说明了只有最外层的肝素才对凝血酶失活有直接影响. 该方法操作工艺简单, 重复性好, 可较广泛地适用于在多种生物医用装置和多孔组织工程支架材料的表面制备稳定的抗凝血涂层, 具有良好的应用前景.     

抗凝血高分子生物材料的表面设计

生物材料,尤其是血液接触材料,满足抗凝血性能是临床应用的首要前提。采用表面改性策略来提高材料表面的抗凝血性能,简单易行。表面改性主要包括表面设计和方法设计两个方面。本文对抗凝血性高分子生物材料的表面设计各类方法进行了综述,其中包括材料表面的微相分离结构、材料的负电荷表面设计、材料的亲(疏)水性表面设计、材料的生物活性化表面设计和材料的内皮细胞化表面设计等等,并重点阐述了两性离子的抗凝血表面设计。     

抗凝血生物材料研究 Ⅵ. 聚乙烯的表面肝素化

通过聚乙烯膜表面的臭氧活化及其随后与甲基丙烯酸环氧丙酯（ＧＭＡ）的接枝共聚、α，ω 二氨基聚氧乙烯（ＪｅｆａｍｉｎｅＥＤ ６００、ＥＤ ９００、ＥＤ ２００１）的亲核开环反应以及在碳二亚胺（ＥＤＣ）缩合剂存在下与肝素的缩合反应，可对聚乙烯膜表面进行高效的肝素共价固定化，其中ＪｅｆａｍｉｎｅＥＤ ６００所固定的肝素浓度可高达１３６μｇ／ｃｍ２，材料抗凝血性也最好     

溶剂对聚氯乙烯-聚乙二醇-KOH体系脱氯行为的影响

废旧塑料的回收利用是当今研究的热点之一.据报道,2007年中国聚氯乙烯(PVC)产量高达960万吨[1],如何合理利用相应产生的废旧PVC是一个十分重要的课题.     

Comparative Studies on Hydrophilic and Hydrophobic Segments Grafted Poly(vinyl chloride)

Poly(vinyl chloride) (PVC) is one of the mostly produced plastics in the world and is widely used in single-use medical devices.However,the additives that are often necessary for PVC arouse concerns of its safety,thus quests the modifications of PVC itself.In this study,poly(ethylene glycol) (PEG) and polydimethylsiloxane (PDMS) segments were grafted onto PVC backbone in similar ways,and the chemical structures of the modified PVCs were characterized by Fourier transform infrared spectra,X-ray photoelectron spectra,thermogravimetric analysis and differential scanning calorimetry.Moreover,the water contact angle,protein adsorption,platelet adhesion,cell attachment and proliferation on different material surfaces were studied and compared.It was found that both PEG and PDMS grafting yielded improvement on biocompatibility compared with bare PVC,while hydrophobic PDMS grafted PVC showed more effective on cell attachment and proliferation than that of hydrophilic PEG grafted PVC.     

PVC固载亲水性离子液体选择性分离血红蛋白研究

将N-甲基咪唑嫁接到聚氯乙烯(PVC)链上制备了亲水性离子液体1-乙烯基-3-甲基咪唑氯代盐-PVC复合物, 并用红外光谱、核磁共振氢谱和表面电荷分析对其进行了表征, 咪唑基团对氯乙烯基中氯的取代率为2.8%. 蛋白质吸附研究表明, 在特定条件下该固载型离子液体对血红蛋白具有吸附选择性, 据此建立了固相萃取分离血红蛋白的方法. 考察了吸附时间、离子强度、洗脱剂及其浓度等对分离纯化效率的影响. 在最优实验条件下, 该固载型离子液体-PVC复合物对30μg•mL^-1血红蛋白的吸附效率为91%, 洗脱效率为75%, 吸附容量为22.7μg•mg^-1. 用1.0% (m/V) SDS洗脱后血红蛋白活性约为原始溶液中的71%. SDS-PAGE凝胶电泳证明其有效地从人全血样品中分离出纯度较高的血红蛋白.     

选择性接聚乙烯醇枝聚醚氨酯的合成及其血液相容性

合成了α－甲基，ω－（２，３－环氧丙基）－聚乙二醇醚（Ⅱ）．经水解得到悬挂聚乙二醇（ＰＥＧ）枝的丙二醇－２，３（Ⅲ）．用二元醇（Ⅲ）为扩链剂制得了在硬链段上接有ＰＥＧ枝的聚醚氨酯（Ｈ－ＰＥＵ）．以四氢呋喃与少量大分子单体（Ⅱ）进行正离子开环共聚合制得每个链接有约１．３个ＰＥＧ枝的聚丁二醇（Ⅳ），用以合成了在软链段上接有ＰＥＧ枝的聚醚氨酯（Ｓ－ＰＥＵ）．ＥＳＣＡ及抗凝血性研究结果表明，不同位置接枝的ＰＥＵ，其表面都有明显的聚醚链段富集．Ｓ－ＰＥＵ抗凝血复钙时间只比未接枝者增长约２０％，而Ｈ－ＰＥＵ则增约一倍，比Ｓ－ＰＥＵ增约６０％．随ＰＥＧ最增大，复钙时间增长．     

聚硅氧烷侧链高分子液晶的合成

合成了烯丙氧基苯甲酸对苯二酚酯的衍生物，用ＮＭＲ及ＭＳ对其结构进行了鉴定。     

Improving the hydrophilic and antifouling properties of poly(vinyl chloride) membranes by atom transfer radical polymerization grafting of poly(ionic liquid) brushes

In this study, poly(1‐butyl‐3‐vinylimidazolium bromide) (PBVIm‐Br) was grafted onto the poly(vinyl chloride) (PVC) membrane surface via a 2‐step atom transfer radical polymerization (ATRP) reaction. Poly(2‐hydroxyethylmethacrylate) (PHEMA) was grafted onto the membrane surface by aqueous ATRP reaction; then, BVIm‐Br was introduced onto the surface of the PHEMA‐modified PVC membrane through traditional ATRP reaction. The analysis of surface chemistry confirmed the successful grafting of PHEMA and PBVIm‐Br on PVC membrane surface, and the grafting density (GD) of PBVIm‐Br gradually increased as the grafting time was prolonged. The modified membrane exhibited a positive charge and significantly enhanced surface hydrophilicity. The static water contact angle of the membrane surface decreased from 92.3° to 51.6° as the GD of the PBVIm‐Br brushes increased. Filtration experiments indicated that the water flux of the modified membrane increased with increasing GD, and their recovered fluxes were more than twice than the original. In addition, the total fouling ratio of the membranes decreased from 89% in M0 to 67% in M5, and most of the fouling was reversible as the GD of PBVIm‐Br brushes increased. These results indicated that the positive charged poly(ionic liquid) brushes featuring hydrophilic properties would have potential applications in membrane separation.     

Encapsulation of silica nanoparticles by redox-initiated graft polymerization from the surface of silica nanoparticles

This study describes a facile and versatile method for preparing polymer-encapsulated silica particles by ‘grafting from’ polymerization initiated by a redox system comprising ceric ion (Ce⁴⁺) as an oxidant and an organic reductant immobilized on the surface of silica nanoparticles. The silica nanoparticles were firstly modified by 3-aminopropyltriethoxysilane, then reacted with poly(ethylene glycol) acrylate through the Michael addition reaction, so that hydroxyl-terminated poly(ethylene glycol) (PEG) were covalently attached onto the nanoparticle surface and worked as the reductant. Poly(methyl methacrylate) (PMMA), a common hydrophobic polymer, and poly(N-isopropylacrylamide) (PNIPAAm), a thermosensitive polymer, were successfully grafted onto the surface of silica nanoparticles by ‘grafting from’ polymerization initiated by the redox reaction of Ce⁴⁺ with PEG on the silica surface in acid aqueous solutions. The polymer-encapsulated silica nanoparticles (referred to as silica@PMMA and silica@PNIPAAm, respectively) were characterized by infrared spectroscopy, thermogravimetric analysis, and transmission electron microscopy. On the contrary, graft polymerization did not occur on bare silica nanoparticles. In addition, during polymerization, sediments were observed for PMMA and for PNIPAAm at a polymerization temperature above its low critical solution temperature (LCST). But the silica@PNIPAAm particles obtained at a polymerization temperature below the LCST can suspend stably in water throughout the polymerization process.     

In vitro haemocompatibility and stability of two types of heparin-immobilized silicon surfaces

Heparin was covalently immobilized onto a silicon surface by two different methods, carbodiimide-based immobilization and photo-immobilization. In the former method, a (3-aminopropyl) trimethoxysilane (APTMS) self-assembled monolayer (SAM) or multilayer was first coated onto the silicon surface as the bridging layer, and heparin was then attached to the surface in the presence of water-soluble carbodiimide. In the latter method, an octadecyltrichlorosilane (OTS) SAM was coated on the silicon surface as the bridging layer, and heparin was modified by attaching photosensitive aryl azide groups. Upon UV illumination, the modified heparin was then covalently immobilized onto the surface. The hydrophilicity of the silicon surface changed after each coating step, and heparin aggregates on APTMS SAM and OTS SAM were observed by atomic force microscopy (AFM). In vitro haemocompatibility assays demonstrated that the deposition of APTMS SAM, APTMS multilayer and OTS SAM enhanced the silicon's haemocompatibility, which was further enhanced by the heparin immobilization. There is no evident distinction regarding the haemocompatibility between the heparin-immobilized surfaces by both methods. However, heparin on silicon with APTMS SAM and multilayer as the bridging layers is very unstable when tested in vitro with a saline solution at 37 °C, due to the instability of APTMS SAM and multilayer on silicon. Meanwhile, photo-immobilized heparin on silicon with OTS SAM as the bridging layer showed superb stability.