囊泡表面分子间通讯交流体系的构建: 利用受体的分子识别行为调控酶的活性

在人工双层膜囊泡表面, 构建了一个通过人工受体的分子识别行为控制酶反应活性的超分子体系. 体系以生物体细胞信号转导系统为模拟原型, 由作为受体的烷基胺、被受体识别的信号分子吡哆醛衍生物、乳酸脱氢酶、受体和酶之间的媒介物Cu^2＋以及作为体系载体的合成肽脂囊泡五个成分构成．通过UV-vis光谱法及动态光散射测定对体系进行了评价, 结果表明: 随着受体疏水参数增大, 其对信号分子的识别能力增强, 二者呈良好的线性关系; 通过信号分子与囊泡表面静电相互作用的研究表明信号分子具有选择性; 媒介物与信号分子–受体可形成化学计量比为1∶2的配合物, 其形成能力比媒介物与酶的结合能力更强．作为结论, 体系中烷基胺受体对磷酸吡哆醛信号分子的识别有效控制了处于囊泡表面的乳酸脱氢酶的活性．     

仿生信号转导系统中的化学振荡:囊泡表面引入DPIP后诱发的机械-光信号转换(英文)

在一个已构建的以细胞肌醇磷脂信号转导途径为原型的仿生信号转导系统中,处于合成肽脂质囊泡表面的乳酸脱氢酶LDH被激活后,催化乳酸脱氢反应过程中,使辅酶NADH氧化为NAD,在此过程中引入DPIP.利用DPIP,在囊泡表面形成了一个由机械信号到光信号转换的化学振荡体系,该体系以DPIP和NADH摩尔比为1∶10的比例进行振荡,其平均循环周期为32min,大于无肽脂质囊泡存在的体系之平均循环周期时间。结果表明:囊泡表面引入DPIP后,在整个系统受到机械刺激信号时,可以引发一个溶液从蓝色到无色,再由无色到蓝色,循环往复的化学振荡.由于LDH结合在囊泡表面,这可能降低了其对NADH的活化作用,从而令化学振荡的平均循环周期时间加长.     

含Schiff碱基囊泡双分子膜的聚集结构与相变

研究表面活性剂分子在水溶液中的聚集行为对模拟生物膜功能和研究分子间相互作用具有重要意义"'．用于形成囊泡双分子层的表面活性剂主要是类似天然磷脂的双烷基链两亲分子,单烷基链两亲分子在引人刚性基团时亦可形成双分子膜k'．含SChiff碱基两亲分子在水溶液中的聚集性质及间、尾链长度对SChiff碱基构象的影响已有报道"'．本文报道了这类分子的另一种重要成膜性质,即改变制备条件,可选择性地得到不同聚集结构和相变温度的双分子膜·实验中所用成膜分子为：CH。（CH。）。;OPh-N-CH－PhO（CH;）n;N"（CH。）。Br－（m-4;n-…     

甲基丙烯酸3-磺酸钾丙酯-苯乙烯共聚物与N,N,N-三甲基十六烷基溴化铵相互作用研究

两亲分子由于具有自组装性质,如表面活性剂分子自组装形成胶束,囊泡,天然的磷脂分子自组装形成脂质体,继而参于生物膜的形成,这是大家所熟悉的．高分子两亲分子尤其是两亲性两嵌段高分子具有自组装性质,并形成规整性好的聚集体［１～３］．聚电介质 表面活性剂体系...     

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。     

磁性非对称双链长表面活性剂囊泡凝胶

合成了一系列含磁性反离子的非对称双疏水链长的阳离子表面活性剂,其中三氯一溴铁合十六烷基戊基二甲基铵(C_(16)C_5DMA~+[FeCl_3Br]-~)与偶氮羧酸钠盐(AzoNa_4)在酸性条件水溶液中形成磁性囊泡凝胶。运用cryo-透射电镜(TEM)、冷冻蚀刻TEM(FF-TEM)、流变仪、傅里叶变换红外光谱(FT-IR)和超导量子干涉(SQUID)等表征技术对囊泡凝胶进行了结构和性质研究,结果发现:凝胶含有曲率多变的融合性的双层囊泡,这些双分子层结构模构了自然界中各种物象的结构轮廓,展现了不可预测的多变曲率和良好柔性。聚集体双分子层膜内由长短不对称烷基链采取交错相扣的双分子层排列模式,这种构建模式结构稳定,短烷基链可游离出囊泡双分子层并伸向外部水相介质。两个相邻囊泡间的短链在疏水相互作用下形成非共价的囊泡"补丁",疏水的囊泡"补丁"克服相邻囊泡之间的斥力而融合。磁性反离子[FeCl_3Br]~-不仅赋予囊泡磁性,且在囊泡的形成过程中调控烷基链的组装。这种多形态融合性囊泡为揭示膜曲率的调节机制和构建人工细胞提供实验数据和理论参考。     

甲基丙烯酸3—磺酸钾丙酯—苯乙烯共聚物与N,N,N—三甲基十六烷基化铵相 …

两亲分子由于具有自组装性质,如表面活性剂分子自组装形成胶束,囊泡,天然的磷脂分子自组装形成脂质体,继而参于生物膜的形成,这是大家所熟悉的．高分子两亲分子尤其是两亲性两嵌段高分子具有自组装性质,并形成规整性好的聚集体［１～３］．聚电介质表面活性剂体系...     

拉链型脂肽的温控开关效应

亮氨酸拉链型脂肽是由两条肽链以螺旋结构依靠疏水作用并列结合形成的二聚体,当温度升至其相变温度时,其螺旋结构解旋继而变为无序链状结构。利用该类脂肽的温敏性能,本文设计、合成得到一组具有温敏性的拉链型脂肽,将其与磷脂混合制备温敏性脂质体。用圆二色谱测定磷脂双分子层上脂肽的二级结构,动态光散射测定脂肽-脂质体的粒径及电位;荧光偏振法测定脂质体膜的流动性;采用紫外分光光度计考察阿霉素(DOX)在37.0、45.0°C下的释放行为。结果表明,含有脂肽的脂质体具备较好的温敏性,胆固醇含量、脂质体膜的流动性,对脂肽的温控开关效应有一定的影响。脂肽-脂质体作为一种新型的温敏性药物载体展现了其较好的应用前景。     

脂肪酸盐-烷基吡啶盐混合体系的双水相

研究了脂肪酸盐和烷基吡啶盐混合水溶液中双水相的形成规律和性质．考察了形成双水相的组成范围和烷基碳链长的影响。测定了两相的密度及化学组成．应用电子显微镜观察了两相的微观结构．结果表明,两相均存在囊泡结构．两相含水均在95％以上．上相为表面活性剂富集的囊泡絮凝相,浓度远远大干下相,相差均在二十倍以上．下相为含有分散的囊泡的表面活性剂稀溶液．     

支撑磷脂双层膜的研究进展

支撑磷脂双层膜(supported phospholipid bilayers,SPBs)是细胞膜研究中普及的模型,是固定生物活性物质的理想材料,不仅可以保持生物分子的活性,还能有效抑制其他生物分子的非特异性吸附,在跨膜蛋白、仿生膜、水处理、生物医学和生物传感器等研究领域具有广泛的应用前景。本文介绍了支撑磷脂双层膜的表征方法和制备方法,包括Langmuir Blodgett(LB)膜提拉法、囊泡融合法和LB膜提拉法与囊泡融合联合法;详细阐述了囊泡融合法制备SPBs的机理;综述了囊泡融合法制备SPBs的影响因素,包括囊泡浓度、缓冲溶液、温度、囊泡和基底表面电荷等因素;列举了支撑磷脂膜的应用,并展望了支撑磷脂双层膜的研究趋势。     

无相移滤波技术用于分析化学信号处理

把无相移滤波技术引入了分析化学信号处理领域。其方法为：先将输入序列按顺序滤波，然后将所得结果逆转后反向通过滤波器，再将所得结果逆转后输出。通过对色谱信号的实验研究表明，与普通的数字滤波方法相比较，无相移滤波不但具有普通数字滤波的优点，而且不会产生滤波前后的相位偏移，具有良好的应用前景，尤其对于需要准确计算保留时间的场合，用此预处理方法非常适合。     

Artificial Signal Transduction

Communication between and inside cells as well as their response to external stimuli relies on elaborated systems of signal transduction. They all require a directional transmission across membranes, often realized by primary messenger docking onto external receptor units and subsequent internalization of the signal in form of a released second messenger. This in turn starts a cascade of events which ultimately control all functions of the living cell. Although signal transduction is a fundamental biological process realized by supramolecular recognition and multiplication events with small molecules, chemists have just begun to invent artificial models which allow to study the underlying rules, and one day perhaps to rescue damaged transduction systems in nature. This review summarizes the exciting pioneering efforts of chemists to create simple models for the basic principles of signal transduction across a membrane. It starts with first attempts to establish molecular recognition events on liposomes with embedded receptor amphiphiles and moves on to simple transmembrane signaling across lipid bilayers. More elaborated systems step by step incorporate more elements of cell signaling, such as primary and secondary messenger or a useful cellular response such as cargo release.     

Orthogonal Signal Correction for Voltammetry

The paper presents orthogonal signal correction (OSC) as a useful algorithm to remove undesired signals distortions, connected with the application of solid electrodes in voltammetry which currently replace toxic mercury sensors due to metal toxicity. It was proven that the influence of additive, multiplicative and typical non‐linearity perturbations of the signal for a calibration model may be substantially limited. Additionally, a noticeable arrangement of the curves was observed which improves the exploration of the analytical system under consideration. The ability of OSC to remove undesirable background effects and improve the quality of results was demonstrated with simulated and experimental data sets.     

NMR Signal Enhancement by Effective SABRE Labeling of Oligopeptides

Signal amplification by reversible exchange (SABRE) can enhance nuclear magnetic resonance signals by several orders of magnitude. However, until now this was limited to a small number of model target molecules. Here, a new convenient method for SABRE activation applicable to a variety of synthetic model oligopeptides is demonstrated. For the first time, a highly SABRE‐active pyridine‐based biocompatible molecular framework is incorporated into synthetic oligopeptides. The SABRE activity is preserved, demonstrating the importance of such earmarking. Finally, a crucial exchange process responsible for SABRE activity is identified and discussed.     

小波变换与分析化学信号处理

介绍了小波变换的基本理论并对小波变换的常用算法和应用进行了评述。由于小波变换的时2频局部化性质, 使其成为信号处理的强有力工具。在分析化学领域中, 小波变换在流动注射分析、伏安分析、高效液相色谱、红外光谱、质谱、核磁共振谱、可见-紫外光谱、光声光谱、扩展X-射线吸收精细结构(EXAFS) 谱等分析化学信号的平滑滤噪、数据压缩、重叠信号解析等方面都有成功的应用。     

信号处理方法在电分析化学中的应用

评述了数字信号处理方法在电分析化学中进展，着重介绍了这些方法的基本原理及其在电分析化学中的应用．     

Signal amplification by allosteric catalysis

In this article we unify a series of recent studies on bio- and chemosensors under a single signaling strategy: signal amplification by allosteric catalysis (SAAC). The SAAC strategy mimics biological signal transduction processes, where molecular recognition between an external signal and a protein receptor is allosterically transduced into catalytically amplified chemical information (usually second messengers). Several recent biosensing and chemosensing studies apply this nature-inspired strategy by using engineered allosteric enzymes, ribozymes, or regulatable organic catalysts. The factors pertinent to achieving high sensitivity and specificity in SAAC strategies are analyzed. The authors believe that these early studies from a variety of research groups have opened up a new venue for the development of sensing technologies where molecular recognition and catalysis can be coupled for practical purposes.     

Signal suppression/enhancement in HPLC-ESI-MS/MS from concomitant medications

This paper presents a study of the signal suppression and enhancement effects in assays based on HPLC-ESI-MS/MS detection. The major focus was to investigate the effect of signal suppression/enhancement of typical co-administered (concomitant) medications, i.e. naproxen and ibuprofen. The results demonstrate that the analyte and internal standard can experience signal enhancement up to a factor of ca 2.9 if the test analyte or internal standard co-elute with concomitant. Experimental results also demonstrate that the analyte and internal standard signal increased by a factor of ca 2.0 in the negative ion mode at physiological relevant levels of naproxen (100 microg/mL) and by a factor of ca 1.6 in the negative ion mode at physiological relevant level of ibuprofen (10 microg/mL) in both neat and plasma samples. Signal enhancement significantly increased when concomitant medications ionized in the same ion mode as the analyte and internal standard. To overcome signal enhancement or potential suppression from concomitant medications, a comprehensive HPLC method needs to be developed with sufficient separation of concomitant medication from the analyte and internal standard. Other means to reduce signal enhancement or potential suppression include switching ionization polarity and performing comprehensive sample clean-up to remove concomitant medications before analysis.