Surface Photografting of Novel Sulfobetaine Copolymers on Silica

A couple of novel sulfobetaine copolymer is developed via Michael-type addition reaction. The comonomers, diamines and maleimide react via Michael reaction through UV irradiation using AIBN as photoinitiator producing polyamine chain. Further, sulfobetaine copolymers were obtained on treatment of the polyamine with sulfopropylating agent, 1,3-propane sultone. These novel sulfobetaine polymers were grafted on silica surface to produce responsive biocompatible surface. This easy straightforward, catalyst free facile protocol for synthesis of polymer grafted surface is useful for developing biomedical devices. Additionally, both the copolymers show fluorescence characteristics.

GRAFTING OF SULFOBETAINE ONTO A POLYURETHANE SURFACE TO IMPROVE BLOOD COMPATIBILITY

On the molecular level, it is believed that polymers containing zwitterionic structures should be compatible withblood. In this work polyurethane films were grafted with sulfobetaine by a three-step procedure. In the first step, the films'surfaces were treated with hexamethylene diisocyanate (HDI) in toluene at 50℃ in the presence of di-n-butyl tin dilaurate(DBTDL) as a catalyst. The extent of the reaction was monitored by ATR-IR spectra; a maximum number of free NCOgroups was obtained after a reaction time of 90 min. In the second step, the hydroxyl groups of N,N-dimethylethylethanolamine (DMEA) were allowed to react in toluene with NCO groups bound on the surface. In the thirdstep, sulfobetaines were formed on the surface through the ring-opening reaction between tertiary amine of DMEA and 1,3-propanesultone (PS). The surfaces of the films were characterized by ATR-IR and XPS showing that the grafted surfaceswere composed of sulfobetaine. The results of the contact angle measurement show that the surface was strongly hydrophilic.The platelet adhesion test demonstrated that the films grafted with sulfobetaine have excellent blood compatibility.

Rapid fabrication of zwitterionic sulfobetaine vinylimidazole-based monoliths via photoinitiated copolymerization for hydrophilic interaction chromatography

Zwitterionic sulfobetaine-based monolithic stationary phases have attracted increasing attention for their use in hydrophilic interaction chromatography.In this study,a novel hydrophilic polymeric monolith was fabricated through photo-initiated copolymerization of 3-(3-vinyl-1-imidazolio)-1-propanesulfonate(SBVI)with pentaerythritol triacrylate using methanol and tetrahydrofuran as the porogenic system.Notably,the duration for the preparation of this novel monolith was as little as 5 min,which was significantly shorter than that required for previously reported sulfobetaine-based monoliths prepared via conventional thermally initiated copolymerization.Moreover,these monoliths showed good morphology,permeability,porosity(62.4%),mechanical strength(over 15 MPa),column efficiency(51,230 plates/m),and reproducibility(relative standard deviations for all analytes were lower than 4.6%).Mechanistic studies indicated that strong hydrophilic and negative electrostatic interactions might be responsible for the retention of polar analytes on the zwitterionic SBVI-based monolith.In particular,the resulting monolith exhibited good anti-protein adhesion ability and low nonspecific protein adsorption.These excellent features seem to favor its application in bioanalysis.Therefore,the novel zwitterionic sulfobetaine-based monolith was successfully employed for the highly selective separation of small bioactive compounds and the efficient enrichment of N-glycopeptides from complex samples.In this study,we prepared a novel zwitterionic sulfobetaine-based monolith with good performance and developed a simpler and faster method for preparation of zwitterionic monoliths.

两性离子中间层调控的纳滤膜制备及其脱盐性能

为了打破纳滤膜的渗透性-选择性上限,制备兼具高渗透通量和高截留性能的薄层复合纳滤膜,首先在水解聚丙烯腈(HPAN)基膜表面沉积聚多巴胺/聚甲基丙烯酰乙基磺基甜菜碱(PDA/PSBMA)中间层,然后利用哌嗪(PIP)和均苯三甲酰氯(TMC)进行界面聚合,制备聚酰胺(PA)层;对膜的化学结构、形貌和表面特性进行表征,研究纳滤膜的性能。结果表明:中间层亲水且带负电,对膜孔未造成严重堵塞,优化了界面聚合反应界面;聚酰胺层的厚度仅为65 nm左右,聚酰胺层内部及其与支撑层之间存在大量通道,使纳滤膜纯水渗透性高达21.82 L/(m^(2)·h·bar)(1 bar=100 kPa);纳滤膜对盐的截留顺序为Na_(2)SO_(4)(98.87%)>MgSO_(4)(96.92%)>MgCl_(2)(50.14%)>NaCl(30.60%),Na_(2)SO_(4)截留率基本不受操作压力和盐浓度的影响,NaCl和Na_(2)SO_(4)的分离因子为61.42;此外,纳滤膜具有良好的抗污染性和长期稳定性,在海水淡化、饮用水净化等领域具有应用潜力。

具有可生物降解、细胞相容、抗菌及生物膜控制的壳聚糖磺基甜菜碱衍生物薄膜生物材料的研究

The purpose of this research was to develop a chitosan sulfobetaine(CS-SNCC)film via the solutioncasting method as a biodegradable antibacterial material for biomedical applications.Chitosan and monochloro-triazine sulfobetaine were used as the raw materials for CS-SNCC preparation,and Fourier-transform infrared(FTIR),ultraviolet–visible(UV-Vis),energy-dispersive X-ray(EDX),and Xray photoelectron spectroscopy(XPS)spectra were used to characterize and analyze the structure of the synthesized CS-SNCC.Furthermore,the swelling property,thermal stability,biodegradability,cytocompatibility,and antibacterial properties of the CS-SNCC film were comprehensively investigated and compared with those of the chitosan film.The results for the film’s enzymatic biodegradation behavior show that the CS-SNCC film undergoes a weight loss of 45.54%after 21 days of incubation.In addition,the CS-SNCC film effectively resists bacterial adhesion,prevents the formation of bacteria biofilms,and exhibits high antibacterial activity,with inactivation rates of 93.43%for Escherichia coli and 91.00%for Staphylococcus aureus.Moreover,the CS-SNCC film shows good cellular activity and cytocompatibility according to the cytotoxicity results.Therefore,the prepared biodegradable,cytocompatible,antibacterial,and biofilm-controlling CS-SNCC film has potential for biomedical applications.

高温高盐水中月桂酰胺丙基羟磺基甜菜碱在砂岩表面吸附规律研究

月桂酰胺丙基羟磺基甜菜碱表面活性剂在高盐含量水中具有较好的起泡性能,但在砂岩表面的吸附量尚不明确。本文利用Shim-pack VP-ODS 4.6 mm×250 mm色谱柱、紫外检测器,优化了流动相组成、流速、柱温等色谱条件,建立了高盐水中月桂酰胺丙基羟磺基甜菜碱的高效液相色谱检测方法。吸附性评价表明:温度为110℃、NaCl质量浓度为25×10^(4) mg/L的水中,质量分数小于1%的月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量小于2 mg/g;在温度为110℃、水中NaCl质量浓度为(20~25)×10^(4) mg/L条件下,质量分数为0.4%月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量随溶液中NaCl含量的增加而增加;在110℃、水中NaCl质量浓度为22.5×10^(4) mg/L、CaCl_(2)质量浓度为(0~3)×10^(4) mg/L条件下,质量分数为0.4%的月桂酰胺丙基羟磺基甜菜碱在80~100目石英砂表面吸附量随溶液中CaCl 2含量的增加而降低。研究结果对高温高盐水中甜菜碱表面活性剂的选择与应用有指导作用。

高强度耐低温离子水凝胶的制备及在摩擦纳米发电机中的应用

摩擦纳米发电机(TENG)作为一种新型可持续的能量收集设备,具有自供电、高输出、低成本、灵活性和轻量化等优点。然而,传统TENG的电极材料为金属薄膜、碳片和液态金属等,存在可拉伸性差、导电性差且在低温无法工作等缺点。文中将氯化锌(ZnCl_(2))、磺基甜菜碱(SBMA)、纳米纤维素(CNC)和柠檬酸(CA)引入聚丙烯酸(AA)基体中,制备了具有优异力学性能(拉伸强度2.16 MPa、断裂伸长率382%)、抗疲劳性、导电性能(9.3 mS/cm)、抗冻性能(-75℃)和保水性能的离子水凝胶材料。基于该离子水凝胶所制备的TENG具有良好的可拉伸性、抗冻性(-50℃)和稳定的输出电压(60 V),能够将人体运动产生的机械能转化为电能,并成功点亮了39个LED灯。因此该水凝胶基TENG在能量收集领域展示出巨大的发展潜力,具有广阔的应用前景。

高透光性甜菜碱型明胶水凝胶的制备与表征

甲基丙烯酰化明胶(gelatin methacryloyl,GelMA)水凝胶透光性、抗蛋白吸附能力较弱,限制了其在人工角膜的应用。基于GelMA水凝胶,引入具抗生物吸附能力及生物相容性的磺基甜菜碱甲基丙烯酸酯(Methacryloxyethyl sulfobetaine,SBMA),构建系列比例的复合两性离子水凝胶GelMA-SBMA体系,讨论单体配比对水凝胶理化性能、生物学性能的影响,并进行体外细胞实验,讨论复合水凝胶对细胞生长、增殖的影响。结果表明,GelMA∶SBMA为5∶1的复合水凝胶在700 nm波长下透光率可达94%,与纤维蛋白的接触角保持在90°以上,体现出抗蛋白吸附能力。细胞实验表明,SBMA的引入有助于细胞生长、增殖,体现出良好的生物相容性。

Molecular Size and Morphology of Single Chains of Poly（sulfobetaine methacrylate）

The effects of the concentration of sodium chloride in an aqueous solution（cNacl and the temperature on the molecular size of poly（sulfobetaine methacrylate）（PSBMA） were studied via viscometry and dynamic light scattering（DLS）. The morphology of single-chain PSBMA was determined by atomic force microscopy（AFM）. The results demonstrate that the hydrodynamic diameter of PSBMA can be expressed as a continuous function of CNaCl, with the molecular size of PSBMA increasing and eventually approaching an asymptotic value with increasing CNaCl. The molecular size of PSBMA at a lower CNaCI（0.04 mol/L） increases with increasing temperature, which is the opposite of the temperature effect at a higher CNaCl（2.0 mol/L）. Therefore, the internal structure of PSBMA chains in solutions with a low salt concentration differs from that in solutions with a high salt concentration. In addition, the morphology of single chains of PSBMA appears to be spherical, containing 89% void space, and the apparent size of the dried chains is almost identical to that in solution.

月桂酰胺丙基-2-羟基-3-磺基甜菜碱的合成及性能研究

以月桂酸为原料,与N,N-二甲基-1,3-丙二胺在氢氧化钾为催化剂的碱性条件下缩合反应生成月桂酸酰胺丙基二甲基胺(PKO12),再与3-氯-2-羟基丙磺酸钠进行季铵化反应合成月桂酰胺丙基-2-羟基-3-磺基甜菜碱(LHSB)。通过讨论反应方式及反应条件(时间、温度、用量)等对转化率的影响,得出了缩合反应和季铵化反应的优化合成工艺条件。最终产物LHSB的临界胶束浓度(CMC)为1 mmol/L、CMC下的表面张力为18.16 mN/m、起泡高度为10.5 cm、稳泡性能达到0.90,具有广泛的应用前景。

磺基甜菜碱型两性离子表面活性剂的合成及其聚合的研究

表面活性剂的化学结构与其物化性能密切相关,两性离子表面活性剂由于其头基阴、阳离子共价键合的特殊结构备受关注。本文以11-溴-1-十一醇和二甲胺为原料,通过甲基丙烯酰氯(MA)和丙烯酰氯(A)的醇解反应引入可聚合基团,最后与1,4-丁磺酸内酯开环反应合成了两种新型的两性离子表面活性剂SB114MA和SB114A,利用核磁共振氢谱表征其纯度较高,计算其产率均可达70%。通过与水和交联剂共混利用紫外光引发自由基聚合实现了可聚合型表面活性剂的固化成膜。红外光谱图中波数为1633 cm-1的碳碳双键在聚合后消失证实了聚合反应的发生。利用扫描电子显微镜和万能试验机表征膜的截面形貌和机械性能,结果表明制备的聚合物薄膜均相且机械性能良好,其断裂强度为2.6 MPa,断裂伸长率为9.2%。

磺基甜菜碱BS11/聚合物复合体系驱油实验研究

考察了以磺基甜菜碱为表面活性剂的SP二元和ASP三元复合体系在大庆油田条件下的岩心驱油效果。所用岩心为环氧树脂胶结石英砂均质和非均质(变异系数0.65)人造岩心。岩心水驱后分别注入0.35 PV BS11/聚合物(2.0/2.5 g/L)二元体系、Na3PO4(牺牲剂)/BS11/聚合物(4.0/2.0/2.5)三元体系、NaOH/重烷基苯磺酸钠Sy/聚合物(1.0/3.0/2.5)三元体系,再注入0.20 PV 1.0 g/L聚合物溶液,测得均质岩心复合驱采收率增值分别为25.8%,27.3%,25.7%(2个岩心的平均值),非均质岩心上分别为26.2%,27.7%,26.1%(单个岩心的测值),无碱的BS11二元体系的驱油效果与大庆油田使用的常规强碱ASP三元体系相当,加入少量Na3PO4可改善该二元体系的驱油效果。从均质岩心流出的BS11二元和三元体系,与模拟原油(黏度10 mPa.s)之间的界面张力(最低值)达到10-3mN/m。图2表2参6。

十二烷基磺基甜菜碱与其它类型表面活性剂的相互作用

通过测定两性表面活性剂十二烷基磺基甜菜碱(SB12)与非离子表面活性剂TritonX100(TX)、阳离子表面活性剂十六烷基三甲基溴化铵(CTAB)、阴离子表面活性剂十二烷基硫酸钠(SDS)混合溶液的表面张力及理论计算,探讨了它们之间的相互作用,从而为两性表面活性剂的复配应用提供了有价值的基础数据.

两性离子聚合物表面改性的聚偏氟乙烯抗污染膜的制备及性能

提高聚偏氟乙烯(PVDF)抗污染性能是改善PVDF应用效果的重要途径。文中通过自由基聚合的方法将抗污染材料——两性离子类化合物磺酸甜菜碱(DMAPS)接枝到碱处理过的PVDF膜表面。研究了接枝DMAPS后,PVDF膜表面的结构与性能变化,并初步探讨了改性后的PVDF膜对牛血清蛋白的吸附性能。结果表明,在PVDF膜表面接枝DMAPS后,膜表面孔洞减小,亲水性提高。虽然改性后的PVDF膜通量有所下降,但通过牛血清蛋白(BSA)的振荡吸附实验发现,两性离子改性膜表现出良好的抗蛋白质吸附性能。与PVDF原膜相比,改性膜在BSA溶液中通量下降率小,用水清洗后膜通量恢复率高。

系列羟基磺基甜菜碱表面活性剂的合成及胶束化行为研究

采用长碳链烷基叔胺和2-羟基-3-氯丙磺酸钠为原料,合成了3种不同碳链长度的羟基磺基甜菜碱表面活性剂。采用元素分析,MS,1HNMR和FTIR对其结构进行了分析表征。测定了不同温度下各表面活性剂水溶液的临界胶束浓度(cmc),并研究了它们的胶束化行为。结果表明,在25℃下,随着疏水链长由C8增加到C14,cmc由1.32×10-2mol·L-1降低到1.67×10-4mol·L-1,最低表面张力(γcmc)由35.9 mN.m-1降低到34.6 mN.m-1;随着温度的升高,同一表面活性剂的cmc略有上升,γcmc略有下降。胶束化热力学计算结果表明其胶束的形成过程为熵驱动过程。

芳基油酸酰胺羟丙基磺基甜菜碱的合成及性能

合成了3种具有不同疏水基团的新型磺基甜菜碱两性表面活性剂,通过红外光谱对它们的结构进行了表征。用滴体积法测定表面活性剂水溶液在25℃下的表面张力,从而确定其临界胶束浓度(cmc)及临界胶束浓度下的表面张力(γcmc);采用罗氏泡沫仪考察了浓度、温度对其泡沫性能的影响;采用分水时间法考察了其乳化性能。结果表明,随着芳环在烷基链中的体积增大,cmc以及γcmc增大,饱和吸附面积Amin增大,而饱和吸附量Γmax减小。3种表面活性剂的起泡性随浓度增大而增加,到一定值后趋于稳定;泡沫稳定性随浓度增大逐渐增强;起泡性随着温度的升高而显著增加,泡沫稳定性随温度升高而显著降低。3种表面活性剂的乳化能力随浓度增大而逐渐增强然后趋于稳定。

磺基甜菜碱Gemini表面活性剂的合成与应用性能

为了改善储层的非均质性差异,有效提高碳酸盐储层的酸化解堵效果,以长链烷基二甲基叔胺、3-氯-2-羟基丙烷磺酸钠和1,4-二溴丁烷为原料,通过两步反应合成了一系列磺基甜菜碱双子表面活性剂(2Cn-SGS,其中n为疏水链中碳原子数,n=12,14,16,18)自转向酸主剂。以2C16-SGS为例,采用FTIR对中间产物(C16-SGS)及2C16-SGS的结构进行表征。通过表面张力法测定2Cn-SGS的表面活性,结果表明,2Cn-SGS具有良好的表面活性,随着疏水链的增长,2Cn-SGS的CMC和表面张力均减小,且胶束化能力增强。可用于黏弹性表面活性剂自转向酸酸化技术,具有良好的转向分流能力,优选配方为4%2C16-SGS+20%盐酸+20%Ca^2+,而且高黏胶束遇煤油等烃类能够自动破胶降黏,易返排对地层无伤害。

三次采油用磺基甜菜碱的研究进展

概述了磺基甜菜碱型表面活性剂,磺基甜菜碱型表面活性剂具有优异的耐高浓度酸、碱、盐及耐高温性能,可与其他表面活性剂进行复配使用;分析了我国三次采油用表面活性剂的研究现状与趋势;综述了三次采油用磺基甜菜碱表面活性剂的合成、复配性能及其在无碱二元复合驱体系中的应用;讨论了磺基甜菜碱在实际推广中所存在的问题;并对磺基甜菜碱型表面活性剂今后在三次采油中的发展方向及应用前景进行了展望。

以聚乙二醇/甲醇为二元致孔剂的新型磺酸甜菜碱型两性离子亲水毛细管整体柱的合成与色谱评价

使用新型二元致孔剂聚乙二醇(PEG)/甲醇,以N,N-二甲基-N-甲基丙烯酰胺基丙基-N,N-二甲基-N-丙烷磺酸内盐(SPP)为单体,季戊四醇三丙烯酸酯(PETA)为交联剂,偶氮二异丁腈(AIBN)为引发剂,通过原位聚合法制备磺酸甜菜碱型两性离子亲水毛细管整体柱。对各反应物的配比进行了优化。结果表明,当单体与致孔剂的质量比为1∶2.5,并且致孔剂中PEG与甲醇的质量比为1∶2,单体内部SPP与PETA的质量比为1∶1,AIBN为总质量的0.1%时为最优配比;PEG/甲醇二元致孔剂的加入实现了对整体柱内部孔径大小的调节,得到了结构更为均一,渗透性、机械稳定性良好的毛细管整体柱,并且理论塔板数与传统制备方法相比有显著提高,在毛细管液相色谱模式下最高可达2.4×105塔板/m。将制备的整体柱应用于毛细管液相色谱和加压毛细管电色谱分离酚类、核苷类等极性小分子混合物,得到了很好的分离效果。

适合低渗透砂岩油层的新型磺基甜菜碱表面活性剂的研究

报道了以中部有芳环的长链烷基为亲油基的一种新的驱油用磺基甜菜碱SLB-13，给出了化学结构，讨论了亲油基最佳结构。45℃时该表面活性剂水溶液在0．05～3．0g／L宽浓度范围可产生超低（10^-3mN／m）油水界面张力。在尺寸4．5×4．5×3．0（cm）、纵向渗透率变异系数0．72、平均渗透率29×10^-3～45×10^-3μm^2的石英砂胶结岩心上，使用黏度10mPa·s的模拟油，在45℃考察了水驱之后注入0．3PV化学剂段塞提高采收率的幅度及段塞注入性和提高波及体积能力（通过Ps／Pw值即注剂注水最大压差比），结果如下。1．0和3．0（g／L）SLB-13段塞仅提高采收率4．62％和3．41％，Ps／Pw值为0．37和0．43，注入性好但不能提高波及体积；0．4HPAM（M=4．8×10^6）段塞提高采收率7．22％，Ps／Pw=1．05；3．0＋0．4、1．0＋0．4、1．0＋0．8SLB-13＋HPAM复合段塞分别提高采收率8．68％、11．74％、16．20％，Ps／Pw值分别为1．04、1．37、2．30，最佳段塞为1．0＋0．4S阻13＋HPAM。SLB-13可用于大庆低渗油藏提高采收率。表3参6。