聚砜阴离子交换膜的制备及结构与性能研究

以1,4-二氯甲氧基丁烷(BCMB)为氯甲基化试剂,使聚砜(PSF)发生氯甲基化反应,制得了氯甲基化聚砜(CMPSF),考察了主要因素对聚砜氯甲基化反应的影响,并使用FTIR及1H-NMR等法对CMPSF的化学结构进行了表征.采用三乙胺(TEA)、三丙胺(TPA)及三丁胺(TBA)等3种叔胺对CMPSF进行了季铵化反应,并以4,4′-联吡啶为交联剂实施了交联反应,制备了聚砜阴离子交换膜(PSFAEM).测定了交换膜PSFAEM的主要性能,包括离子交换容量(IEC)、含水量(WC)及膜电阻(Rm).实验结果表明,使用BCMB,聚砜的氯甲基化反应可顺利进行,以氯仿为溶剂,以SnCl4为Lewis酸催化剂,可制得氯甲基化程度为1.75mmol/g的CMPSF.交换膜PSFAEM的IEC、WC及Rm与季铵化反应时间及叔胺的种类密切相关.季铵化反应时间相同时,采用烷基中碳原子数少的叔胺TEA所制备的交换膜具有高的IEC与WC,低的Rm;使用同一种叔胺时,随季铵化反应时间的增长,交换膜的IEC与WC增大,Rm减小.     

两亲性超支化聚砜胺对染料的可逆高装载

采用戊酰氯、壬酰氯和棕榈酰氯对超支化聚砜胺(HPSA)进行封端,合成了3种不同烷基末端的两亲性核壳型超支化聚砜胺,并将其用于小分子装载.发现它们对刚果红(CR)、甲基橙(MO)、虎红(RB)等水溶性染料具有很强的装载能力,且对同种染料的封装载荷随着末端亲油性烷基链的增长而增大.对于末端为棕榈酰基的HPSA-PC,平均每个大分子可以捕捉CR和MO分子的数目分别高达41.8和19.4个,远高于已报道的树枝状聚合物和超支化聚合物对这些染料的封装载荷.这主要是聚砜胺内核的高度亲水性及其与亲油性烷基外壳的极性差所致.与已报道的聚合物不同,两亲性超支化聚砜胺装载的染料用纯水洗涤可以释放出来.这种高装载性能和可逆性赋予超支化聚砜胺在药物释放、分子识别和分离以及纳米催化剂和纳米涂料等领域具有广阔的应用前景.     

季铵化聚砜/层状双金属氢氧化物阴离子交换膜的制备与表征

共沉淀法制备的层状双金属氢氧化物(LDH)分散于氯甲基化聚砜的溶液,经流延法制备了有机-无机杂化膜.通过季铵化、碱性化处理,杂化膜被转变为阴离子交换膜(AEM).使用X-射线衍射对LDH和AEM样品的结构进行了表征,同时用扫描电镜对AEM样品形貌进行了直接观察,测试了AEM的吸水率、溶胀率、机械性能和离子传导率等.结果表明,LDH含量为5%的AEM具有最佳的综合性能,95℃的离子传导率为3.81×10-2S/cm.     

木质素磺酸钠改性聚砜膜的制备及其在正渗透膜中的应用

采用木质素磺酸钠作为亲水添加剂,通过浸没沉淀相转化法制备了木质素磺酸钠共混改性聚砜膜,以改善聚砜膜的亲水性,并用作正渗透膜的支撑层,以降低内浓差极化效应.利用扫描电子显微镜、衰减全反射傅里叶变换红外光谱仪、水接触角仪等研究了不同木质素磺酸钠添加量对聚砜膜的结构和表面性质的影响.结果表明,添加木质素磺酸钠后,聚砜膜的指状孔变得规整且狭长.水接触角实验证实添加木质素磺酸钠能改善聚砜膜的亲水性,当木质素磺酸钠含量为0.4 wt%时,聚砜膜的表面水接触角可降低至65°.正/反渗透测试装置分别用于表征正渗透膜的传质性质和结构参数.结果表明,以0.4 wt%木质素磺酸钠改性聚砜膜为支撑层的正渗透膜的水渗透性能(A=3.12×10~(-5) LMH×Pa~(-1))优于纯聚砜基底正渗透膜(0.76×10~(-5)LMH×Pa~(-1)),而且前者的结构参数(S=2010mm)远小于后者(3450mm),说明木质素磺酸钠改性聚砜膜有效弱化了正渗透膜的内浓差极化效应.     

燃料电池用磺化聚砜类质子交换膜研究

聚砜类聚合物是一类具有良好应用前景的质子交换膜材料。本文对近年来磺化聚砜的制备、磺化聚砜质子交换膜的性能和磺化聚砜交联膜的研究情况做了比较全面的归纳与分析，特别是从聚砜膜的水化性能和导电性能两个大的方面对该类膜的物理性能和电化学性能进行了阐述，并对存在的问题以及研究前景进行了探讨。     

溶剂挥发法制备萃取剂微胶囊

萃取剂微胶囊的制备是利用微囊化方法将萃取剂包覆起来 ,解决传统液液萃取中的两相相分散、相混合、相分离以及溶剂的损失和设备结构复杂等问题 .用简单易控制的溶剂挥发法成功制备了聚砜及聚苯乙烯材料包覆的多种萃取剂 (如磷酸三丁酯 ,2 乙基己基磷酸 ,三辛胺和Aliquat 336 )微胶囊 ,并考察了壁材和分散剂的选择对不同萃取剂进行包覆的影响 ,同时研究了搅拌速度和膜溶液组成对微胶囊的形态、萃取剂包覆量的影响 .结果表明 ,(1)用聚砜作壁材可以包覆磷酸三丁酯、2 乙基己基磷酸 ,而用聚苯乙烯可以包覆三辛胺、Aliquat336 ;(2 )对于不同的O W乳液体系 ,只有选择合适的分散剂 ,才能得到理想球形状、分散性好的微胶囊 ;(3)增大搅拌速度可以降低液滴尺度 ,从而减小微胶囊粒径 ;(4)膜溶液组成的影响则表现在两个方面 ,一是膜溶液的粘度和两相界面张力是除搅拌速度外微胶囊粒径的决定因素 ,二是膜溶液中壁材与萃取剂的比例优化时 ,才能得到萃取剂包覆量高的微胶囊 .     

聚砜与丙烯酸的紫外光辐射接枝共聚及其表征

在均相溶液体系下,运用紫外光辐射引发合成了聚砜与丙烯酸的接枝共聚物。用化学滴定、漫反射傅立叶变换红外光谱和热分析等技术对接枝聚合物进行了表征。结果表明:丙烯酸被接枝在聚砜链上;光照时间、单体浓度和光引发剂浓度对接枝率均有较大影响。膜表面接触角的研究表明,接枝共聚物膜的亲水性比改性前有所提高。     

接枝型镉离子印迹膜的制备及其识别选择性能

以乙二胺(EDA)为试剂,对氯甲基化聚砜微滤膜(CMPSF)进行化学改性,制得胺基化聚砜微滤膜(AMPSF);然后在AMPSF膜与水溶液界面处,构建—NH2/S2O2-8表面引发体系;最后以对苯乙烯磺酸钠(SSS)为单体、Cd~(2+)为模板、N,N-亚甲基双丙烯酰胺(MBA)为交联剂,采用接枝/交联与离子印迹同步进行的方法,制得接枝型Cd~(2+)印迹膜(GIIM)。采用傅里叶红外光谱(FTIR)、扫描电子显微镜(SEM)及光学显微镜(OM)对印迹膜进行表征,并深入研究了印迹膜对Cd~(2+)的识别选择性能和渗透分离性能。结果表明,印迹膜对Cd~(2+)具有优良的结合亲和性、识别选择性及渗透分离性,结合量与渗透量分别高达1.41 mmol/cm2和0.95mg/mL,而相对于参比离子Pb~(2+)和Zn~(2+),印迹膜对Cd~(2+)的选择系数分别为9.97和11.9。     

LTV—PSF富氧膜的复合机理研究

用不同种类和浓度的极性有机物水溶液(醇-水溶液、羧酸-水溶液、多官能团有机物-水溶液)以及四种类型(阳离子、阴离子、两性、非离子)表面活性剂水溶液处理聚砜支撑膜改变其表面化学特性,改善硅橡胶汽油溶液在其表面的铺展性能;用两次浸泡减少涂层过程中硅橡胶汽油溶液向支撑膜内的渗透程度,使LTV-PSF复合膜的透量获得较大幅度的提高。同时考察了聚砜支撑膜结构因素的影响。     

聚酰胺-胺树状大分子修饰硅胶固定化胰蛋白酶的研究

以聚酰胺-胺(PAMAM)树状大分子修饰的硅胶为载体,胰蛋白酶为模型,考察了PAMAM的代数和固定化条件对酶的固载量及活力的影响.实验结果表明:选用3.0代PAMAM树状大分子修饰硅胶为载体固定化胰蛋白酶,酶促反应最适pH值为9.0,最适温度为60℃,对酪蛋白表现米氏常数K<,m>为7.76mg/mL,固定化胰蛋白酶表...     

Membrane affinity chromatography used for the separation of trypsin inhibitor.

Polysulphone (PS) was chemically modified by acrylation-amination and by chloromethylation-amination, respectively. An ultrafiltration membrane of chemically modified polysulphone (CMPS) was prepared by the phase inversion method. Trypsin was then covalently bonded onto the CMPS membrane by diazotization. The activity of immobilized trypsin reaches up to 10200 U/g; 15 mg trypsin was immobilized on 1 g CMPS membrane. Separation of soybean trypsin inhibitor was carried out on the affinity membrane, yielding 6.5 mg pure trypsin inhibitor in one run. The enzyme membrane has good activity and stability.     

复合纤维素膜固定化胰蛋白酶反应器及其应用于蛋白质酶解

合成了甲基丙烯酸缩水甘油酯-纤维素复合膜,并以此膜为基质共价键合固定化胰蛋白酶,以N-苯甲酰-L-精氨酰乙酯(BAEE)为底物,应用高效液相色谱系统测定了酶固定化膜柱的催化反应特性。研究结果表明:温度、pH值、离子强度、有机溶剂及蛋白变性剂等都对固定化酶的活力有一定的影响。在最适条件下,固定化胰蛋白酶的活力为17800U/g干膜,蛋白载量为3.6mg/g(≈0.15μmol/g)干膜,活性回收率达到52%.固定化酶表现出较高的使用和储藏稳定性,在40℃下,水解BAEE底物24h活力无显着变化。固定化酶膜柱在4℃冷藏保存100d仍保存90%以上的水解活力。固定化酶反应器被应用于蛋白质酶解的肽谱实验。     

Adsorptive Removal of Hg(II) from Synthetic and Real Aqueous Solutions Using Modified Papaya Seed

The performance of chemically modified papaya seed (CMPS) adsorbent with carboxyl and amino groups has been studied. Adsorption experiments were performed with respect to the changes in initial pH of the solution, contact time, initial Hg(II) concentration, and CMPS dosage. Kinetic data were fitted to the pseudo-second-order model. The maximum adsorption capacity calculated by Langmuir model was 18.34 mg/g. CMPS was characterized by elemental analysis, Fourier transform infrared (FTIR) spectroscopy, and scanning electron microscopy. The results indicate that adsorption mechanism of CMPS involves ion exchange (2Na⁺/Hg²⁺) and carboxylic-group-dominated surface complexation. Regeneration study revealed that CMPS can be used successfully for four cycles with a small adsorption capacity loss (6.8%).     

Characterization of p-aminobenzamidine-based sorbent and its use for high-performance affinity chromatography of trypsin-like proteases

An affinity sorbent, hydrophilic polymer-based carrier of different pore size (Toyopearl) with immobilized p-aminobenzamidine (ABA), has been prepared. Its basic properties and some applications for protein purification were studied. ABA, which is a synthetic inhibitor for trypsin-like proteases, was covalently immobilized to Toyopearl by reductive amination. The ligand density and binding capacity for porcine trypsin varied depending on the pore size of Toyopearl. The maximum binding capacity of the immobilized p-aminobenzamidine Toyopearl (ABA-Toyopearl) for trypsin was more than 40 mg/ml gel. ABA-Toyopearl thus obtained was very stable below pH 8 and was successfully used for high-performance affinity chromatography of trypsin-like proteases such as trypsin, thrombin, tissue-type plasminogen activator or urokinase in a single step at 25 degrees C.     

On-line characterization of the activity and reaction kinetics of immobilized enzyme by high-performance frontal analysis

A microreactor by immobilized trypsin on the activated glycidyl methacrylate-modified cellulose membrane packed column was constructed. Immobilized trypsin mirrored the properties of the free enzyme and showed high stability. A novel method to characterize the activity and reaction kinetics of the immobilized enzyme has been developed based on the frontal analysis of enzymatic reaction products, which was performed by the on-line monitoring of the absorption at 410 nm of p-nitroaniline from the hydrolysis of N-alpha-benzoyl-DL-arginine-p-nitroanilide (BAPNA). The hydrolytic activity of the immobilized enzyme was 55.6% of free trypsin. The apparent Michaelis-Menten kinetics constant (Km) and Vmax values measured by the frontal analysis method were, respectively, 0.12 mM and 0.079 mM min(-1) mg enzyme(-1). The former is very close to that observed by the static and off-line detection methods, but the latter is about 15% higher than that of the static method. Inhibition of the immobilized trypsin by addition of benzamidine into substrate solution has been studied by the frontal analysis method. The apparent Michaelis-Menten constant of BAPNA (Km), the inhibition constant of benzamidine (Ki) and Vmax were determined. It was indicated that the interaction of BAPNA and benzamidine with trypsin is competitive, the Km value was affected but the Vmax was unaffected by the benzamidine concentration.     

Combination of MALDI-TOF mass spectrometry with immobilized enzyme microreactor for peptide mapping

Matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) has been combined with immobilized enzyme microreactor for the rapid, sensitive, and accurate tryptic mapping of protein and polypeptides. The technique utilizes the trypsin microreactor by immobilized enzyme on the glycidyl methacrylate (GMA)-modified cellulose membrane. The membrane micro-reactor was used for the tryptic mapping of cytochrome C and the results were compared with those obtained by using free trypsin. A significant increase in the overall sensitivity of the process was observed using the membrane microreactor, as well as the elimination of background signals due to the autolysis of the trypsin. Further, membrane microreactor digestions were found to be rapid and convenient.     

Trypsin inhibitor screening in traditional Chinese medicine by using an immobilized enzyme microreactor in capillary and molecular docking study

A trypsin immobilized enzyme microreactor was successfully prepared in capillary for studying enzyme kinetics of trypsin and online screening of trypsin inhibitors from traditional Chinese medicine through capillary electrophoresis. Trypsin was immobilized on the inner wall at the inlet of the capillary treated with polydopamine. The rest of the capillary was used as a separation channel. The parameters including the separation efficiency and the activity of immobilized trypsin were comprehensively evaluated. Under the optimal conditions, online screening of trypsin inhibitors each time can be carried out within 6 min. The Michaelis–Menten constant of immobilized trypsin was calculated to be 0.50 mM, which indicated high affinity of the immobilized trypsin for the substrate. The half‐maximal inhibitory concentration of known inhibitor of benzamidine hydrochloride hydrate as a model inhibitor was 13.32 mM. The proposed method was successfully applied to screen trypsin inhibitors from 15 compounds of traditional Chinese medicine. It has been found that baicalin showed inhibitory potency. Molecular docking study well supported the experimental result by exhibiting molecular interaction between enzyme and inhibitors.     

The properties of covalently immobilized trypsin on soap-free P(MMA-EA-AA) latex particles

The covalent immobilization of trypsin onto poly[(methyl methacrylate)-co-(ethyl acrylate)-co-(acrylic acid)] latex particles, produced by a soap-free emulsion polymerization technique, was carried out using the carbodiimide method. The catalytic properties and kinetic parameters, as well as the stability of the immobilized enzyme were compared to those of the free enzyme. Results showed that the optimum temperature and pH for the immobilized trypsin in the hydrolysis of casein were 55 degrees C and 8.5, both of which were higher than that of the free form. It was found that K(m) (Michaelis constant) was 45.7 mg . ml(-1) and V(max) (maximal reaction rate) was 793.0 microg . min(-1) for immobilized trypsin, compared to a K(m) of 30.0 mg . ml(-1) and a V(max) of 5 467.5 microg . min(-1) for free trypsin. The immobilized trypsin exhibited much better thermal and chemical stabilities than its free counterpart and maintained over 63% of its initial activity after reusing ten times.     

STUDIES ON NATURAL AND MODIFIED PEPTIDE Trichosanthes TRYPSIN INHIBITORS

A peptide trypsin inhibitor was isolated and purified from the roots of Trichosanthes kirilowii (a Chinese medical herb) by using immobilized anhydro-trypsin affinity chromatography and HPLC C_(18) column reverse chromatography. It contains two major components, both consisting of 27 amino acid residues with three pairs of disulfide bonds. The sequence determination indicated that the difference between them is only in the ninth position, being Gln and Lys, respectively. The peptide bond of the inhibitor reactive site Arg-Ile (3--4) is easy to cleave at low pH by trypsin, resulting in a modified inhibitor. It might be the smallest naturally occurring protein inhibitor so far known. The modification reaction of the Trichosanthes inhibitor with trypsin is similar to the catalytic enzyme-substrate reaction. The dissociation constant of the modified inhibitor with trypsin is around fourfold that of the natural inhibitor.     

Studies on natural and modified peptide Trichosanthes trypsin inhibitors

A peptide trypsin inhibitor was isolated and purified from the roots of Trichosanthes kirilowii (a Chinese medical herb) by using immobilized anhydro-trypsin affinity chromatography and HPLC C18 column reverse chromatography. It contains two major components, both consisting of 27 amino acid residues with three pairs of disulfide bonds. The sequence determination indicated that the difference between them is only in the ninth position, being Gln and Lys, respectively. The peptide bond of the inhibitor reactive site Arg-Ile (3-4) is easy to cleave at low pH by trypsin, resulting in a modified inhibitor. It might be the smallest naturally occurring protein inhibitor so far known. The modification reaction of the Trichosanthes inhibitor with trypsin is similar to the catalytic enzyme-substrate reaction. The dissociation constant of the modified inhibitor with trypsin is around fourfold that of the natural inhibitor.