合成双分子膜多元体系的激发态能量转移

发现在４－（４－癸氧基联苯－４－氧基三甲基）溴化铵双分子膜体系内，从联苯给体通过结合在膜表面上的达旦黄传递到罗丹明Ｂ受体的三元激发态的能量转移效率较高．探讨了囊泡在此能量转移过程中的特殊功能作用和能量转移的机制．同时还观察到了在此体系内通过静电相互作用，组织在囊泡表面上的达旦黄、荧光黄、罗丹明Ｂ和四苯基卟啉间的多元能量转移，这种能量转移可改善光的输出，扩展光波的覆盖范围．     

除草剂西玛津与过氧化氢酶的相互作用

应用荧光光谱法和微透析液相色谱法研究了水溶液中除草剂西玛津与过氧化氢酶分子间的相互作用。结果表明 ,除草剂对过氧化氢酶的荧光有较强的猝灭作用 ,且静态猝灭是引起荧光猝灭的主要原因。从荧光猝灭和以Scatchard方程拟合微透析液相色谱法的测定结果求出除草剂和CAT的结合常数及结合位点数分别为K =1.5 5× 10 4 L/mol,n =0 .94。并依据能量转移机制 ,求出了西玛津和CAT相互结合时 ,给体 受体间距离r为 0 .164nm。西玛津与过氧化氢酶的相互结合作用以静态猝灭过程为主 ,且其猝灭机制是通过能量转移产生的。西玛津可能与CAT的Tyr2 14发生结合作用     

用荧光猝灭和荧光加强两种理论研究喹诺酮类新药与白蛋白的作用

应用荧光加强和荧光猝灭两种理论公式, 对四种喹诺酮类药物与人血清和牛血清白蛋白的作用作进行了对比研究, 对药物与白蛋白的结合特点和通常的表征量(解离常数、 猝灭常数、 猝灭效率、 能量转移效率、 给体 受体作用距离等)进行了深入地分析; 在白蛋白与药物结合类型上, 四种药物对HSA和BSA的猝灭实验结果表明, 这种由给体-受体结合引起的猝灭作用类型不是由生物大分子血清白蛋白单方面决定的, 而是由血清白蛋白与药物、 即给体与受体两者的分子结构和相互匹配共同决定的.     

金丝桃苷与牛血清白蛋白相互作用的研究

采用荧光共振能量转移法研究了金丝桃苷与牛血清白蛋白的相互作用.金丝桃苷对牛血清白蛋白(BSA)的荧光猝灭类型是静态猝灭,25℃时的结合位点数为0.5451.并依据F(o)ster非辐射能量转移理论,研究了给体(牛血清白蛋白)--受体(金丝桃苷)间的结合距离R.和能量转移效率E分别为2.04nm和0.66.同时,采用同步...     

用荧光猝灭和荧光加强两种理论研究头孢类药物与白蛋白的作用

应用荧光加强和荧光猝灭两种理论公式，对七种头孢类抗菌药物与人血清和牛血清白蛋白的作用作进行了对比研究，对药物与白蛋白的结合特点和通常的表征量：解离常数、猝灭常数、猝灭效率、能量转移效率、给体-受体作用距离等，进行了深入地分析。     

分子光谱法研究铝酞菁与牛血红蛋白的相互作用

利用紫外可见吸收光谱和荧光光谱研究了在生理pH条件下铝酞菁与牛血红蛋白(BHb)的相互作用.实验结果表明:铝酞菁分子与BHb发生反应生成基态复合物,导致BHb内源荧光的猝灭,该猝灭属于静态猝灭.测定了不同温度下该反应的表观结合常数、结合位点数及结合热力学参数,热力学参数的变化表明铝酞菁与BHb之间以静电和疏水作用力为主;根据Frster能量转移理论,测得供体与受体间结合距离r和能量转移效率E;并用同步荧光光谱法探讨了铝酞菁对BHb构象的影响.     

单宁酸与牛血红蛋白相互作用的光谱研究

利用荧光光谱技术研究了单宁酸与牛血红蛋白分子的相互作用。实验结果表明:单宁酸分子与BHb发生反应生成基态复合物,导致BHb内源荧光的猝灭,该猝灭属于静态猝灭。测定了不同温度下该反应的表观结合常数、结合位点数及结合热力学参数,热力学参数的变化表明上述作用过程是一个熵增加、自由能降低的自发分子间作用过程,单宁酸与BHb之间以疏水和氢键作用力为主;根据Frster能量转移理论,测得供体与受体间结合距离r和能量转移效率E;并用同步荧光光谱法探讨了单宁酸对BHb构象的影响。     

光谱法与分子模拟技术研究丽春红2R与牛血清蛋白的相互作用

采用荧光光谱、同步荧光光谱、紫外-可见吸收光谱及分子模拟技术研究了模拟生理条件下丽春红2R(P2R)与牛血清白蛋白(BSA)的相互作用。实验结果表明,P2R-BSA体系的荧光猝灭机制为内源荧光猝灭,猝灭原因为静态猝灭和非辐射能量转移;计算了不同温度下体系的结合常数Ka及结合位点数n;根据热力学参数推断出作用力类型;求出室温下荧光给体-受体间的结合距离;同步荧光法证实丽春红2R对BSA构象未产生影响;分子模拟研究结果表明二者间的主要作用力为氢键和疏水作用力。     

基于上转换荧光共振能量转移的Hg~(2+)侧流检测模型的设计和应用

本工作利用荧光共振能量转移(FRET)过程,以上转换荧光纳米材料(UCNPs)作为能量供体,以金纳米粒子(AuNPs)作为能量受体,通过适配体识别Hg~(2+),在硝化纤维素膜(NC)上制备侧流检测试纸条。Hg2+的参与会拉近能量供受体距离,引起检测区UCNPs的荧光猝灭。通过检测区的荧光猝灭效率,可判断样品中的Hg~(2+)浓度。该传感器在缓冲溶液中的检测线性范围为0.1~100nmol/L;检出限为0.1nmol/L。本研究成功证实了上转换荧光共振能量转移体系在侧流模型应用的可行性。     

血清白蛋白与巴比妥钠相互作用的光谱研究

采用荧光光谱、紫外-可见光谱研究了药物巴比妥钠(BBTS)和牛血清白蛋白(BSA)的相互作用机理,运用热力学方法确定了巴比妥钠和牛血清白蛋白相互作用力的类型主要是疏水力,该过程是一个熵增加、Gibbs自由能降低的自发超分子作用过程,根据Stern-Volmer方程和Lineweaver-Burk双倒数曲线方程求出了其结合常数在高温时比在低温时小,用F ster非辐射能量转移理论计算了二者结合时给体和受体之间的距离r=2.76 nm,能量转移效率E=0.332,证实了巴比妥钠和牛血清白蛋白之间的作用是生成复合物的静态猝灭过程,说明了猝灭机制是通过能量转移产生的。     

ENERGY TRANSFER AND ENERGY LOSSES IN BILAYER MEMBRANE VESICLES (LIPOSOMES)

Abstract. The efficiency of singlet-singlet energy transfer was studied in bilayer lipid membrane vesicles (liposomes) for the following donor-acceptor systems: (1) p -terphenyl (TP) and diphenyloctatetraene (DPO); (2) DPO and chlorophyll a (Chl a ); and (3) β-carotene and Chl a. The energy transfer efficiency φ_DA was measured by sensitized fluorescence of the acceptor. Fractional quenching of the donor φ_Q was found from the donor fluorescence in absence and presence of the acceptor. For TP-DPO and for DPO-Chl a , the transfer efficiency increased with increasing acceptor concentration but was essentially independent of the donor concentration. No energy transfer from β-carotene to Chl a could be detected. In liposomes, φ_DA differed only slightly from φ_Q at all donor and acceptor concentrations, thus demonstrating the absence of any appreciable energy losses. For solutions of the same donor-acceptor pairs in cyclohexane φ_Q was considerably larger than φ_DA. The difference represents energy lost, principally by internal conversion, due to collisional quenching. The principal function of the lipid membrane appears to be the suppression of such losses. In addition, the rate of energy transfer in lipid membranes is about double that in solutions (at the same intermolecular distance) due to more favorable orientation.     

Efficient Light‐Harvesting Systems with Tunable Emission through Controlled Precipitation in Confined Nanospace

Light harvesting is a key step in photosynthesis but creation of synthetic light‐harvesting systems (LHSs) with high efficiencies has been challenging. When donor and acceptor dyes with aggregation‐induced emission were trapped within the interior of cross‐linked reverse vesicles, LHSs were obtained readily through spontaneous hydrophobically driven aggregation of the dyes in water. Aggregation in the confined nanospace was critical to the energy transfer and the light‐harvesting efficiency. The efficiency of the excitation energy transfer (EET) reached 95 % at a donor/acceptor ratio of 100:1 and the energy transfer was clearly visible even at a donor/acceptor ratio of 10 000:1. Multicolor emission was achieved simply by tuning the donor/acceptor feed ratio in the preparation and the quantum yield of white light emission from the system was 0.38, the highest reported for organic materials in water to date.     

Study of energy transfer from 7-amino coumarin donors to the rhodamine 6G acceptor in lecithin vesicles and sodium taurocholate-lecithin mixed aggregates

The energy transfer using 7-amino coumarin dyes as the donor and rhodamine 590 (Rh6G) as the acceptor was investigated in lecithin vesicles and sodium taurocholate (NaTC)-lecithin mixed aggregates using steady-state and time-resolved fluorescence spectroscopy. All energy transfer parameters were calculated. The coumarin 153-Rh6G pair is the most efficient donor-acceptor pair as reflected by the value of k(ET). With addition of NaTC in lecithin, in the case of the coumarin 153-Rh6G pair, the energy transfer rate or efficiency does not change very much, whereas in the case of the coumarin 151-Rh6G pair, the energy transfer rate decreases 2-fold upon going from lecithin vesicles to NaTC-lecithin mixed aggregates where the molar ratio is 2.5. It is mainly due to the deeper location of coumarin 153 in the lipid bilayer or in mixed aggregates. Rotational relaxation data also support this idea.     

Enhanced Photoinduced Electron Transfer at the Surface of Charged Lipid Bilayers

Photocatalytic systems often suffer from poor quantum yields due to fast charge recombination: The energy‐wasting annihilation of the photochemically created charge‐separated state. In this report, we show that the efficiency of photoinduced electron transfer from a sacrificial electron donor to positively charged methyl viologen, or to negatively charged 5,5′‐dithiobis(2‐nitrobenzoate), increases dramatically upon addition of charged phospholipid vesicles if the charge of the lipids is of the same sign as that of the electron acceptor. Centrifugation and UV/Vis titration experiments showed that the charged photosensitizers adsorb at the liposome surface, that is, where the photocatalytic reaction takes place. The increased photoelectron transfer efficiency in the presence of charged liposomes has been ascribed to preferential electrostatic interactions between the photosensitizer and the membrane, which prevents the formation of photosensitizer–electron‐acceptor complexes that are inactive towards photoreduction. Furthermore, it is shown that the addition of liposomes results in a decrease in photoproduct inhibition, which is caused by repulsion of the reduced electron acceptor by the photocatalytic site. Thus, liposomes can be used as a support to perform efficient photocatalysis; the charged photoproducts are pushed away from the liposomes and represent “soluble electrons” that can be physically separated from the place where they were generated.     

Energy transfer--a tool for probing micellar media

The non-ionic polyoxyethylene chain-containing surfactant Triton X-100 (TX-100) forms well-defined micelles and reverse micelles in aqueous and hydrocarbon media, respectively. Nonradiative energy transfer between two charged fluorescent dyes, fluorescein (FL) and acridine orange (AO) has been used to probe the micelles and reverse micelles of TX-100. In the energy transfer system employed, FL acts as the donor and AO as the acceptor. This is borne out by the fluorescence spectral data. Time-resolved studies further corroborate the steady-state results. As the fluorescence emission spectra of the two dyes show a considerable amount of overlap, they are resolved into individual donor and acceptor components using the principal component analysis (PCA) method. This study also focuses on the more important role played by hydrophobic forces (compared with electrostatic interactions) in promoting energy transfer between charged species in micellar media.     

Photostimulated vectorial electron transfer across the bilayer membrane of lipid vesicles in a system with CdS nanoparticles as photosensitizer and 1,4--bis(1,2,6-triphenyl-4-pyridyl)benzene as a reversible two-electron carrier

Photostimulated vectorial electron transfer through the lecithin bilayer membrane was studied in a system based on lipid vesicles with CdS as a photosensitizer located either in the vesicle inner cavity or outside the vesicles. 1,4-Bis(1,2,6-triphenyl-4-pyridyl)benzene (benzoviologen) was used as an effective lipophilic highly reversible electron carrier incorporated into the bilayer membrane. A peculiarity of this electron carrier is its ability to be reversibly reduced on one and two electrons. The interface electron transfer across the border “vesicular cavity-membrane” was studied by stationary and pulse photolysis. The primary photoreduced form of benzoviologen appears to be that reduced by one electron; however, on stationary photolysis, most benzoviologen molecules appear to be affected by two-electron reduction, which can result from the low mutual mobility of CdS nanoparticles and benzoviologen molecules. The CdS photostimulated transmembrane electron transfer from the internal sacrificial donor to the external acceptor (as regards the vesicular cavity) was performed for [CoEDTA]⁻ as the final electron acceptor. The rate constants of electron transfer from the membrane-embedded two-electron reduced form of benzoviologen have been determined in the case of [CoEDTA]⁻ and O₂ as acceptors.     

VECTORIAL ELECTRON TRANSPORT ACROSS LIPID VESICLE MEMBRANES DRIVE BY TWO PHOTOREACTIONS. II. PHOTOCHEMICAL REGENERATION OF REDUCED CYTOCHROME c BY FLAVIN TRIPLET STATE AND ETHYLENEDIAMINETETRAACETIC ACID IN THE INNER COMPARTMENT AND REDUCTION OF FERREDOXIN BY CHLOROPHYLL TRIPLET STATE IN THE OUTER COMPARTMENT

We have attempted to mimic natural photosynthesis with regard to the photogeneration of a powerful reductant, using a negatively charged lipid bilayer vesicle system incorporating two photoreactions sensitized by a flavin analog (flavin mononucleotide [FMN]) and chlorophyll (chl) in their respective triplet states. Ethylenediamine-tetraacetic acid (EDTA) in the inner aqueous compartment was used as a sacrificial electron donor to the FMN triplet, and ferredoxin in the outer aqueous compartment served as the final electron acceptor (mediated via triplet electron transfer chain in this multicomponent system to be elucidated. By itself, EDTA does not function as an effective donor to membran-bound oxidized chl (chl^+.), which is formed by electron transfer from triplet chl to the viologen follwed by transbilayer electron migration. This is a consequence of electrostatic repulsive interactions with the negatively charged membrane. This limitation is avoided when FMN is used as a photomediator between EDTA and chl^+.. The overall reaction is dramatically increased in rate by enclosing cytochrom c together with EDTA and FMN in the inner compartment. The rate constant of the key step in the reaction, i.e. elctron transfer from reduced cytochrome c, generated via photoreduction by the FMN/EDTA system, to chl^+. is increased 20-fold over that obtained with cytochrome c alone as the elctron donor. One of the important constraints that limited the net electron transfer across the bilayer to 50% of the added cytochrome, i.e. inhibition by oxidized cytochrome c formed in the inner compartment, is avoided by the inclusion of the second photoreaction in this system, thus allowing photoreduction of all of the added ferredoxin to be achieved. This system provides a model for a photochemical energy storage process that utilizes two photorections operating in series resulting in electron flow across a lipid bilayer membrane.     

Amphiphilic Fluorescence Resonance Energy-Transfer Dyes: Synthesis,Fluorescence, and Aggregation Behavior in Water

Amphiphilic pyrene/perylene bis-chromophore dyes were synthesized from unsymmetrically substituted perylene bisimide dyes, which were obtained through three synthetic methods. The optical and aggregation behaviors of these functional dyes were studied by means of UV/Vis absorption and fluorescence spectroscopy, dynamic light scattering, and TEM. These dyes are highly fluorescent and cover the whole visible-light region. A donor/acceptor dye displays intramolecular fluorescence resonance energy transfer (FRET), with a high efficiency of up to 96.4 % from pyrene to perylene bisimide chromophores, which leads to a high fluorescence color sensitivity to environmental polarity. Under a λ=365 nm UV lamp, the light-emitting colors of the donor/acceptor dye change from green to yellow with increasing solvent polarity, which demonstrates application potential as a new class of FERT probes. The donor/acceptor dye in water was assembled into hollow vesicles with a narrow size distribution. The bilayer structure of the vesicular wall was directly observed by means of TEM. These vesicular aggregates in water are fluorescent at λ=650–850 nm within the near-infrared region.     

Role of diffusion in excitation energy transfer and migration

Effect of diffusion on excitation energy transfer and migration in a dye pair sodium fluorescein (donor) and Rhodamine-6G (acceptor) has been studied for different viscosities by both steady state and time domain fluorescence spectroscopic measurements. The donor-donor interaction appears to be weaker as compared to donor-acceptor interaction and thus favors direct Forster-type energy transfer. Interestingly, at low viscosity (water in this case) transfer appears to be controlled by material diffusion/energy migration. Further, acceptor dynamics reveals the fact that direct Forster transfer dominates in viscous media.     

Long range energy transfer in conjugated polymer sequential bilayers

Steady-state and time-resolved photoluminescence have been used to investigate the optical properties of bilayer and blend films made from poly(9,9-dioctyl-fluorene-2,7-diyl) (PFO) and poly[2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene] (MEH PPV). Energy transfer has been observed in both systems. From steady-state photoluminescence measurements, the energy transfer was characterized by the effective enhancement of the MEH PPV emission intensity after exciting the donor states. Relatively faster decays for the PFO donor emission have been observed in the blends as well as in the bilayer structures, confirming effective energy transfer in both structures. In contrast to the bilayers, the time decay of the acceptor emission in the blends presents a long decay component, which was assigned to the exciplex formation in these samples. For the blends the acceptor emission is in fact a composition of exciplex and MEH PPV emissions, the later being due to Fo?rster energy transfer from PFO. In the bilayers, the exciplex is not observed and temperature dependence photoluminescence measurements show that exciton migration has no significant contribution to the energy transfer. The efficiency and very long range of the energy transfer in the bilayers is explained assuming a surface-surface interaction geometry where the donor/acceptor distances involved are much longer than the common Fo?rster radius.