新型双功能交联型阴离子交换膜的制备与性能

以2-甲基咪唑为原料合成2种离子液体前驱体1-烯丙基-2-甲基咪唑和1-丁基-2-甲基咪唑,以苯乙烯(St)和对氯甲基苯乙烯(VBC)为原料制备聚离子液体主链p(St-co-VBC),2种离子液体前驱体与聚离子液体主链发生季铵化反应铸膜,制备了交联结构和梳型侧链结构型阴离子交换膜(AEMs).通过傅里叶红外光谱、扫描电子显微镜和热重分析等考察了阴离子交换膜的结构、微观形貌、氢氧根离子传导率、热稳定性及碱性稳定性等性能.结果表明,AEMs含水率为36.7%~93.4%,离子交换容量为1.61~2.16 mmol/g,80℃时,p(St-co-VBC)-3型AEMs氢氧根离子传导率高达68.4 mS/cm,在1 mol/L NaOH溶液中碱性浸泡240 h后,氢氧根离子传导率仍高达52.2 mS/cm,具备良好的碱性稳定性.     

一种具有识别运输钠离子的离子通道膜的制备

以三氯甲烷为溶剂,用3-异氰酸基丙基三乙氧基硅烷和对氨基苯酚合成得到一种自组装杂化材料——3-(脲基酚基)丙基三乙氧基硅烷.采用FTIR、XPRD分析方法对该化合物的结构以及晶体形态进行了表征.利用旋涂法和共混法分别制备离子通道膜,采用ATR-FTIR和SEM分析手段表征膜的化学结构和形态结构,并通过自制的膜运输实验装置测定膜的传输性能并提出了相应的传输机理.实验结果表明,两种方式所得的离子通道膜表面是致密无孔的,致密层厚度为8～10μm左右;采用共混法制得的离子通道膜的传输速度较旋涂法快.离子通道是杂化材料通过分子自组装形成的,该通道可以识别并运输Na+.     

正负离子表面活性剂混合体系中正离子与芳环π电子的相互作用

通过UV-vis, ~1H NMR和TEM等方法研究了[溴化十烷基三甲铵（DTAB）与N-（ 4-癸氧基-2-羟基苄基）甘氨酸（C_(10)HG）]正负离子表面活性剂混合体系中的正 离子-π相互作用。实验结果表明在聚集体中DTAB分子处于C_(10)HG的芳环平面上 方,二者之间存在着阳离子-π相互作用,该相互作用有利于囊泡的形成。     

表面离子法制备多组分LB膜和CeO_2-Gd_2O_3陶瓷膜

以铈、钆的β二酮螯合物Ce(tmhd)_4和Gd(tmhd)_3(tmhd = tetramethylheptanedionate)为表面离子,与花生酸（AA）在水面上共铺展,可 形成具有良好相容性、稳定性和可压缩性的混合Langmuir膜,这是由于稀土螯合物 与AA间发生了新的配合,而且Gd(tmhd)_3与AA间的相互作用更强。用垂直法将它们 的三组分混合Langmuir膜沉积,制得了具有良好周期性结构的Y型三组分混合LB膜 。以它作前驱物,经过紫外臭氧（UVO）和热处理,制得了CeO_2-Gd_2O_3(CGO)超 薄陶瓷膜。X射线光电子能谱（XPS）表明,由于两种稀土螯合物和AA间的结合强度 不同,在沉积LB膜时表面离子发生了选择性转移,而且温度对表面离子的转移选择 性有影响。这对制备组分和厚度可控的应用薄膜很有意义。     

表面活性剂混合物水溶液中的囊泡形成

1:1烷基羧酸钠-溴化烷基三甲铵混合水溶液的浓度在cmc以上时, 能自发或超声分散形成一类新型混合表面活性剂囊泡(单层膜), 正负离子表面活性剂的突出囊泡形成能力以及不同表面活性剂结构组合变化所显现的多样特性, 皆预示出混合功能有序组合体研究的广阔前景。     

离子液体掺杂聚苯胺固相微萃取涂层的电沉积制备及其在芳香胺检测中的应用

新型萃取材料及相关涂层制备技术是固相微萃取技术发展的重点.本研究在1-羟丙基-3-甲基咪唑-四氟硼酸盐([C3(OH)mim][BF4])和HNO3混合溶液中,通过电化学方法在铂(Pt)丝表面固定新型聚苯胺-离子液体(PANI-IL)涂层.电镜分析表明,离子液体存在时,PANI膜孔结构变均匀、比表面积增大.以芳香胺为模...     

基于过渡态速率理论的叶片类囊体膜离子通道模型

开发了一种基于过渡态速率理论(TSRT)的离子通道模型,并首次应用在植物叶片类囊体膜阳离子通道建模中.在该模型体系中,离子跨膜输运被认为是穿越数个能垒和结合位点的耗能过程.模型采用3个能垒和2个结合位点的模式(3B2S),并允许不同种类离子占据其中位点,但"挤出(knock out)效应"不考虑在内.通过计算叶片类囊体膜上的电压门控离子通道的阳离子流密度和研究跨膜电势差的消长情况,发现该模型能够很好地模拟离子通道所具备的3种特性,即饱和性、选择性以及竞争性抑制.而且该模型对参数需求少,运算时间短,可快速高效地获取一种离子通道的协助转运特性,为进一步的布朗动力学仿真提供基础.该模型也可嵌入到叶片整体光合系统模型中,为深入理解叶绿体光诱导的跨膜电势差的消散机理提供一种新的思路.     

离子缔合型离子选择电极的研究 Ⅰ.PVC膜铬(Ⅵ)离子选择电极的研制和应用

铬(Ⅵ)离子选择电极已有报道。固膜电极用铬酸钡或铬酸铅为活性材料,流动载体电极多采用离子缔合型交换剂,如季铵盐、季鏻盐、结晶紫、四苯鉮和邻二氮菲等。ypycoB等用四辛铵等制成的PVC膜电极,线性响应下限为1×10~(-5)M。本文报道以三庚基十二烷基碘化铵为活性材料的铬(Ⅵ)离子选择电极,在氢氟酸体系中其线性响应下限为2×10~(-6)M,斜率为58mV(25℃),选择性优于ypycoB报道的电极。一、仪器     

双分子层膜人工离子通道的合成

离子通道(ion channels)是由细胞膜上的一类特殊亲水性蛋白质构成的微孔道,它的主要功能就是传输离子跨膜,相当于细胞的通气孔。其结构与功能的异常往往引起上千种疾病,统称为离子通道病,这种疾病目前不能靠常规的仪器来检查,在确诊上有一定的难度。因此通过化学手段合成人工离子通道来模拟生物体内细胞膜上的离子通道的结构与功能,对于深入研究这些疾病并发现特异性治疗药物均具有十分重要的理论和实际意义。本论文就近三十年来人们设计合成的不同种类人工离子通道进行了综述,介绍了其研究进展并总结了各种人工离子通道的分子结构设计以及在膜上传输离子行为,展望了其在模拟天然离子通道功能的同时在生物医药以及生命科学等领域的应用前景。     

具有多级孔结构的NH4-β沸石的直接合成及其性能

以非离子表面活性剂壬基酚聚氧乙烯醚(Tx-15)为模板,设计氟化铵作为矿化剂.在近中性条件下直接合成了具有微孔-介孔复合孔道的铵型β沸石.合成样品采用粉末X射线衍射(PXRD),高分辨扫描电子显微镜(SEM),微分热重(DTG)以及氨程序升温脱附(NH3-TPD)等手段进行了表征.结果表明,氟离子及非离子表面活性剂的加入对沸石的孔结构、酸性质均起到了一定的调变作用.该沸石具有发达的呈梯级分布的多级孔结构,孔容高达0.67 cm3·g-1,且具有较强的Bronsted酸和适度分布的Lewis酸,大大改善了反应物和产物分子的扩散和反应性能.在混合C4烃的催化裂解反应中,该沸石与传统方法合成的β沸石相比,其转化率提高了约15%,烯烃(乙烯和丙烯)产率提高了近10%,芳烃(苯和甲苯)产率提高了3%.     

自组装杂化离子通道膜的构筑及阳离子传输机制

以3-异氰酸丙基三乙氧基硅烷和对甲氧基苯胺为原料合成了一种可以自组装形成有机-无机杂化材料的化合物--3-(脲基-4-甲氧基苯基)丙基三乙氧基硅烷. 采用FT-IR, ¹H NMR, DSC 和XRD 分析方法对该化合物的结构以及结晶性进行了表征. 将该化合物与聚乙烯醇(PVA)共混, 利用化合物的自组装性质构筑结构均一且致密无孔的离子通道杂化膜, 通过自制的膜运输实验装置测定膜对阳离子的传输性能并提出了相应的传输机制. SEM 照片显示, 自组装杂化膜致密无缺陷, 膜厚度为8 μm. 选择5 种阳离子进行运输实验测试, 结果表明, 自组装杂化离子通道膜对一价的碱金属离子Li⁺, Na⁺和K⁺有很好的传输功能, 这要归功于杂化材料中甲氧基苯基与碱金属阳离子形成的阳离子-π相互作用力. 碱金属阳离子在膜中的扩散过程可由溶解-扩散机制来解释, 结果显示, Li⁺, Na⁺和K⁺在杂化膜中传输的渗透率大小为: P_Na⁺ > P_K⁺ > P_Li⁺ , 说明本研究中的的自组装杂化离子通道膜对Na⁺有优先选择性. 杂化离子通道膜对二价的Ca²⁺和Mg²⁺没有传输作用, 此结果给一二价阳离子的分离带来很好的研究思路.     

钙离子对支撑磷脂膜离子通道行为的诱导作用

将一种支撑磷脂膜--杂化双层膜(Hybridbilayermembrane,HBM)用于钙离子与磷脂作用的研究,以Fe(CN)₆^3-为探针,发现钙离子可诱导HBM产生离子通道,且通道的打开与关闭可反复运转,并用STM观察了这一现象.     

膜片电极支撑自组装双层脂膜中短杆菌肽离子通道的形成

通过一个两步程序在膜片电极尖端形成自组装双层脂膜：（1）膜片电极尖端沾取成膜液；（2）将吸附成膜液的尖端浸入电解液中，排除尖端多余的成膜液，通过电学方法监测双层脂膜的形成。将短杆菌肽通道蛋白分散在成膜液和电解质溶液中，在制备膜片电极支撑双层脂膜过程中，短杆菌肽重组到双层脂膜中形成离子通道，对通道的一般特性进行了研究，并观察到通道开放和关闭的现象。     

Ion Channel Behavior of a Supported Bilayer Lipid Membrane Composed of 5,5-Ditetradecyl-2-(2-trimethyl-ammonioethyl)-1,3-dioxane Bromide Modified Glassy Carbon Electrode

A synthetic cationic surfactant, 5, 5-ditetradecyl-2-(2-trimethyl-ammonioethyl)-1, 3-dioxane bromide (DTDB), was used toconstruct a supported bilayer lipid membrane (s-BLM) coatedon an underlying glassy carbon electrode (GCE). Electrochem-ical impedance spectroscopy (EIS), small-angle X-ray diffrac-tion (SAXD) and cyclic voltammetry were used to characterizethe s-BLM. Both EIS and SAXD data indicated that the syn-thetic lipid exists as a well-oriented bilayer in the membrane.     

Light-Driven Active Ion Transport

Solar energy can be harvested by biological systems to regulate the directional transport of protons and ions across cells and organelles. Structural and functional bio-mimic photo-active ion nanofluidic conductors, usually in the forms of ion channels and ion pumps, have been increasingly applied to realize active ion transport. However, progress in attaining effective light-driven active transport of ions (protons) has been constrained by the inherent limitations of membrane materials and their chemical and topological structures. Recent advances in the construction of photo-responsive physical ion pump in all-solid-state membranes could potentially lead to new classes of membrane-based materials for active ion transport. In this concept, the development of the state-of-the-art technologies for manufacturing artificial light-driven active ion transport systems are presented and discussed, which mainly involves the utilization of solar energy to realize two types of active ion transport, chemically and physically active ion transport. Afterward, we summarize the key factors towards culminating highly effective and selective membranes for active ion transport. To conclude, we highlight the promising application perspectives of this light-driven active ion transport technique in the field of energy conversion, bio-interfaces and water treatment.     

Advances in Artificial Cell Membrane Systems as a Platform for Reconstituting Ion Channels

An artificial cell membrane that is composed of bilayer lipid membranes (BLMs) with transmembrane proteins incorporated within them represents a well‐defined system for the analysis of membrane proteins, especially ion channel proteins that are major targets for drug design. Because the BLM system has a high compatibility with recently developed cell‐free expression systems, it has attracted attention as a next‐generation drug screening system. However, three issues associated with BLM systems, i. e., their instability, the need for non‐volatile organic solvents and a low efficiency of ion channel incorporation, have limited their use as a drug screening platform. In this personal account, we discuss our recent approaches to address these issues based on microfabrication. We also discuss the potential for using the BLM system combined with cell‐free expression systems as a drug screening system for future personalized medicine.     

Triazole‐Tailored Guanosine Dinucleosides as Biomimetic Ion Channels to Modulate Transmembrane Potential

A “click” ion channel platform has been established by employing a clickable guanosine azide or alkyne with covalent spacers. The resulting guanosine derivatives modulated the traffic of ions across the phospholipid bilayer, exhibiting a variation in conductance spanning three orders of magnitude (pS to nS). Förster resonance energy transfer studies of the dansyl fluorophore with the membrane binding fluorophore Nile red revealed that the dansyl fluorophore is deeply embedded in the phospholipid bilayer. Complementary cytosine can inhibit the conductance of the supramolecular guanosine channels in the phospholipid bilayers.     

Ion channels from linear and branched bola-amphiphiles

The synthesis and characterization of the ion channel activity of three new bola-amphiphiles is described. These compounds are conceptually derived from a previously reported bis-cyclophane bola-amphiphile through opening of the cyclophanes to acyclic structures and were found to readily form ion channels in planar bilayer membranes as assessed by bilayer clamp single-channel analysis. All three compounds behaved very similarly: the dominant channels formed by all three are Ohmic with specific conductance of 10 +/- 1 pS (NaCl electrolyte) and 39 +/- 1 pS (CsCl electrolyte). Single-ion permeability ratios, determined from dissymmetric electrolyte experiments, showed the selectivity P(Cs(+)) > P(Na(+)) > P(Cl(-)). Less frequently, lower conductance channels were also observed to act independently of the dominant channels. The lifetimes of the dominant channels range from 70 to 280 ms for the three compounds with some very long-lived openings (20-40 s) observed for two of the three. The lower conductance states have shorter lifetimes. This study demonstrates that bis-macrocyclic compounds are not essential for channel formation by bola-amphiphiles, and opens a new class of channel-forming compounds for structure-activity optimization.