POPOP诱导环糊精形成纳米管的研究

用紫外吸收光谱、稳态荧光、荧光各向异性和动态光散射等方法研究了2,2′-p-亚苯基-双(5-苯基噁唑) (POPOP)分子与环糊精(CD)的相互作用. 结果表明, POPOP分子在浓度较低时与β-CD形成1:2的包合物, 在浓度较高时可以进一步诱导β-CD形成纳米管结构. 同时发现, POPOP分子也可以诱导γ-CD形成纳米管结构. 对比于β-CD, POPOP分子在γ-CD水溶液中的荧光发射峰, 不仅有明显的红移而且也缺失了精细结构, 呈现较宽的大包峰. 这是由于POPOP分子成对进入γ-CD空腔形成了激基缔合物的缘故. pH和温度效应实验进一步表明, POPOP诱导β-CD形成的纳米管在pH大于12和温度高于331 K的环境下不能稳定存在.     

荧光光谱法研究维生素B_1与β-环糊精及其衍生物的包合作用

采用荧光光谱法研究了β-环糊精(β-CD)、甲基-β-环糊精(M-β-CD)、羟丙基-β-环糊精(HP-β-CD)、磺丁基-β-环糊精(SBE-β-CD)对维生素B_1的包合作用.在固定维生素B_1浓度和改变环糊精及其衍生物浓度的情况下,维生素B_1的荧光发射波长的变化以及荧光强度的增强表明了包合物的形成,用荧光双倒数法计算了环糊精及其衍生物与维生素B_1的包合常数.实验结果表明:在pH=7.4的体系中,β-环糊精对维生素B_1的包合能力最强,且四种环糊精与维生素B_1的包合物的包合比均为1∶1.     

非水溶性卟啉NTPPH_2和ATPPH_2与环糊精超分子体系的光谱学研究

在中性磷酸盐缓冲溶液中,用紫外-可见分光光度法和荧光光谱法研究了非水溶性卟啉5-(4-硝基苯基)-10,15,20-三苯基卟啉(NTPPH2)和5-(4-氨基苯基)-10,15,20-三苯基卟啉(ATPPH2)与α-CD、β-CD和γ-CD三种环糊精相互作用形成的超分子体系。结果表明,NTPPH2与α-CD、β-CD和γ-CD均形成了1:1的包结物,ATPPH2与β-CD形成1:2的包结物,与α-CD和γ-CD则形成了1:1的包结物。其中α-CD与NTPPH2和ATPPH2的包结常数最大。本文探讨了卟啉环上给电子基团和吸电子基团对包结的影响,为卟啉和环糊精相互作用及超分子体系的机理研究提供了基础。     

相溶解度法研究环糊精对蒽醌药物的增溶作用

通过相溶解度法,测定1,2-二氨基蒽醌、1,4-二氨基蒽醌和1,8-二羟基蒽醌在不同温度、不同浓度的β-环糊精(β-CD)、羟丙基-β-环糊精(HP-β-CD)以及羟乙基-β-环糊精(HE-β-CD)中的溶解度,绘制相溶解度曲线,并进行回收率及稳定性实验.实验结果表明:1,2-二氨基蒽醌、1,4-二氨基蒽醌和1,8-二羟基蒽醌的溶解度均随3种环糊精浓度的增加而呈线性增加,相溶解度曲线为AL型,蒽醌与环糊精形成的包合物类型为1∶1型,3种环糊精对蒽醌均有增溶作用,增溶效应顺序为HP-β-CDHE-β-CDβ-CD,与HP-β-CD作用顺序为1,2-二氨基蒽醌1,4-二氨基蒽醌1,8-二羟基蒽醌.     

荧光光谱法研究氢溴酸右美沙芬与β-环糊精及其衍生物的相互作用

应用荧光光谱法研究了β-环糊精(β-CD)及其衍生物甲基-β-环糊精(Me-β-CD)、磺丁基-β-环糊精(SBE-β-CD)与氢溴酸右美沙芬(DH)的包合作用。实验固定DH浓度和改变β-环糊精及其衍生物浓度,根据DH的发射波长的变化及荧光强度增敏现象确定了包合物的形成,根据双倒数法计算包合常数。实验结果表明:在pH为7.4的条件下,有三种环糊精对药物有明显的作用,这三种环糊精与氢溴酸右美沙芬形成了包合物且包合比均为1∶1。     

羟丙基-β-环糊精对γ-山竹黄酮的包合作用研究

采用荧光光谱法研究了羟丙基-β-环糊精(Hp-β-CD)在生理pH条件和中性条件下对γ-山竹黄酮(γ-MAG)的包合行为和增溶效果,并探讨了温度对表观包合稳定常数的影响.利用溶液-搅拌法制备了包合物,并用红外吸收光谱法、差示扫描量热分析法对其进行了表征.结果表明:在胃液pH和中性条件下,Hp-β-CD 均能与γ-MAG形成稳定的包合物,包合比分别为 1∶ 1和2∶ 1,表观包合稳定常数K分别为1.57×103 L/mol和2.7×106 L2/mol2,在中性条件下更容易形成包合物.而在肠液pH条件下,Hp-β-CD与γ-MAG没有包合现象.温度对表观包合稳定常数的影响不大.Hp-β-CD与γ-MAG形成包合物后,使 γ-MAG的溶解度增加了约31倍.     

β-环糊精及其衍生物对灯盏花乙素增溶作用的研究

采用相溶解度法研究了β-环糊精(β-CD),及其衍生物羟丙基-β-环糊精(HP-β-CD)、磺丁基醚-β-环糊精(SBE-β-CD)、单6-脱氧-氨基-β-环糊精(NH2-β-CD)和单6-脱氧-乙二胺-β-环糊精(en-β-CD)对灯盏花乙素的增溶作用,并测定了主-客体分子形成包合物的平衡常数。结果表明,当灯盏花乙素与上述5种环糊精形成可溶性包合物时,对应的相溶解度曲线均为AL型,说明其与环糊精的包合比均为1∶1;多种弱相互作用力协同作用于环糊精的包结配位过程,环糊精衍生物的取代基影响了主-客体配位能力。5种环糊精主体化合物对灯盏花乙素客体分子的增溶能力的大小为:en-β-CD>NH2-β-CD>HP-β-CD>SBE-β-CD>β-CD。     

环糊精的微环境效应——Ⅱ.环糊精对萘嵌戊烯光化学二聚反应的影响

我们研究了β-环糊精(β-CD)和γ-环糊精(γ-CD)对萘嵌戊烯的包结作用,发现γ-CD可以和萘嵌戊烯形成1:2宿主-客体包结络合物,从而促进客体光化学二聚生成顺式二聚体。而β-CD和萘嵌戊烯只形成1:1包结络合物,因而阻止客体光化学二聚反应的发生。在萘嵌戊烯的β-CD水溶液中,加入丙烯腈,可以生成顺式交叉加成产物。     

偶氮苯衍生物-β-环糊精包合物的自组装行为

研究了4-N（2’-巯基-乙基）羧基酰胺偶氮苯（Azo）与β-环糊精（β-CD）形成的包合物在金表面上的自组装行为．X射线光电子能谱（XPS）结果证实,Azo和Azo与β-CD形成的包合物均可在金表面上自组装形成单分子层膜．在包合物形成的自组装膜中,Azo与β-CD的摩尔比约为1：1．Azo自组装膜的电化学反应表现速率常数（Kobs）随组装时间的延长而明显减小,反映出自组装膜的排列随时间延长而趋于更加致密,从而抑制了偶氮苯基团的电化学诱导构型转化,降低了其电活性．而Azo与β-CD包合物自组装膜的Kobs值随组装时间变化不大,在组装76h以后,包合物自组装膜的Kobs比单纯偶氮苯自组装膜的Kobs高2个数量级以上．表明环糊精能够将偶氮苯分子隔开,从而抑制了偶氮苯在自组装膜中的聚集作用,有效地提高其电化学活性．     

二丁基羟基甲苯包合物的制备、表征及应用研究

本文采用冷冻干燥法制备获得二丁基羟基甲苯(BHT)的羟丙基-β-环糊精包合物(HP-β-CD IC)、二甲基-β-环糊精包合物(DM-β-CD IC)和磺丁基-β-环糊精包合物(SBE-β-CD IC)。相溶解度法确定了二者形成化学计量比为1:1的包合模型;粉末X射线衍射、差示扫描量热、核磁共振氢谱及扫描电镜等技术给出其可能的结合模式,并通过AutoDock分子模拟对接理论研究佐证了实验结果的可靠性;实验结果证明,三种包合物稳定性顺序为SBE-β-CD/BHT ICDM-β-CD/BHT ICHP-β-CD/BHT IC,其中SBE-β-CD/BHT包合物增溶效果最显著。1,1-二苯基-2-苦肼基(DPPH)法考察BHT三种包合物抗氧化活性的结果是:三种包合物均表现出良好的清除效果,且与BHT相当。利用β-CD衍生物的包合技术改善BHT的水溶性,是一种拓展BHT应用领域的有效策略。     

Formation of nanotubes and secondary assemblies of cyclodextrins induced by BBOT

The study of cyclodextrin nanotubes is a significant topic among the self-assembly behaviors of cyclodextrins. We report herein the interaction of 2,5-bis(5′-tert-butyl-2-benzoxazoyl)thiophene (BBOT) with α-, β-, γ-cyclodextrins (CDs). It has been discovered that the reaction patterns of BBOT with CDs are remarkably different. β-CD forms a simple inclusion complex with BBOT in a stoichiometry of 1:2 (guest:host). β-CD forms a 1:1 inclusion complex with BBOT at its low concentration. At higher concentration of BBOT, the nanotube and secondary assembly of β-CD are formed. As for γ-CD, the nanotube and secondary assembly are formed within the whole concentration range of BBOT studied. The structure of γ-CD nanotubes is different from that of β-CD nanotubes to a certain extent.

     

Inclusion complexes of cyclodextrins with 4-amino-1,8-naphthalimides (part 2)

Fluorescence spectroscopy was used to characterize inclusion compounds between 4-amino-1,8-naphthalimides (ANI) derivatives and different cyclodextrins (CDs). The ANI derivatives employed were N-(12-aminododecyl)-4-amino-1,8-naphthalimide (mono-C₁₂ANI) and N,N′-(1,12-dodecanediyl)bis-4-amino-1,8-naphthalimide (bis-C₁₂ANI). The CDs used here were α-CD, β-CD, γ-CD, HP-α-CD, HP-β-CD and HP-γ-CD. The presence of CDs resulted in pronounced blue-shifts in the emission spectra of the ANI derivatives, with increases in emission intensity. This behavior was parallel to that observed for the dyes in apolar solvents, indicating that inclusion complexes were formed between the ANI and the CDs. Mono-C₁₂ANI formed inclusion complexes of 1:1 stoichiometry with all the CDs studied. Complexes with the larger CDs (HP-β-CD, HP-γ-CD and γ-CD) were formed by inclusion of the chromophoric ANI ring system, whereas the smaller CDs (α-CD, HP-α-CD and β-CD) formed complexes with mono-C₁₂ANI by inclusion of the dodecyl chain. Bis-C₁₂ANI formed inclusion complexes of 1:2 stoichiometry with HP-β-CD, HP-γ-CD and γ-CD, but did not form inclusion complexes with α-CD, HP-α-CD and β-CD. The data were treated in the case of the large CDs using a Benesi-Hildebrand like equation, giving the following equilibrium constants: mono-C₁₂ANI:HP-β-CD (K ₁₁ = 50 M^?1), mono-C₁₂ANI:HP-γ-CD (K ₁₁ = 180 M^?1), bis-C₁₂ANI:HP-β-CD (K ₁₂ = 146 M^?2), bis-C₁₂ANI:HP-γ-CD (K ₁₂ = 280 M^?2).     

Complexation of triptolide and its succinate derivative with cyclodextrins: affinity capillary electrophoresis, isothermal titration calorimetry and 1H NMR studies

The complexation of the triptolide PG490 and its succinate derivative PG490-88Na with various cyclodextrins was studied using three complementary techniques: affinity capillary electrophoresis (ACE), isothermal titration calorimetry (ITC) and nuclear magnetic resonance (NMR). The apparent binding constants of the complexes formed between the drugs and 8 CDs (α-CD, β-CD, γ-CD, HP-α-CD, HP-β-CD, HP-γ-CD, CM-β-CD and amino-β-CD) were determined by ACE through linear Scott's plots. The apparent and averaged binding constants of the complexes formed between PG490-88 and β-CD, γ-CD, HP-α-CD, HP-β-CD or HP-γ-CD are contained in the narrow range 135-167 M(-1). For the anionic CM-β-CD and cationic amino-β-CD, these constants are 38 and 278 M(-1), respectively, which is in accordance with electrostatic repulsions or attractions with the succinate moiety. ITC and NMR investigations for the binding constants determinations were performed for 2 CDs allowing high complexation: HP-β-CD and amino-β-CD. The three techniques provided similar results. ITC and NMR, in contrast to ACE, allowed to study the complexes formed between the neutral compound PG490 and neutral cyclodextrins. A more advanced characterization of the PG 490-88Na/amino-β-CD complex, which displays the highest apparent binding constant, was undertaken using NMR spectroscopy. The 1:1 stoichiometry of the complex was established by (1)H NMR 1D and selective 1D TOCSY experiments using the continuous variation method. Moreover, the 1D and 2D ROESY experiments revealed the inclusion of the isopropyl moiety of the triptolide derivative in the hydrophobic CD cavity. Altogether, the data provide strong evidences that the two triptolide compounds can be efficiently complexed with CD.     

Complex Formation of Hematoporphyrin with Cyclodextrins and 1,1′-Diheptyl-4,4′-bipyridinium Dibromide in Aqueous Solutions

At around 5×10^-6?mol?dm^-3 of hematoporphyrin (HP), an HP dimer exists as well as an HP monomer. The equilibrium constant for the dimerization of HP in pH 10.0 buffer has been evaluated to be 1.70×10⁵?mol^-1?dm³ from the HP concentration dependence of the absorption spectrum. In aqueous solution, HP forms 1:1 inclusion complexes with β-cyclodextrin (β-CD), γ-cyclodextrin (γ-CD), and heptakis(2,3,6-tri-O-methyl)-β-cyclodextrin (TM-β-CD). The fluorescence of HP is significantly enhanced by the addition of CDs. From simulations of the fluorescence intensity changes, the equilibrium constants for the formation of the CD–HP inclusion complexes have been estimated to be 200, 95.7, and 938?mol^-1?dm³ for β-CD, γ-CD, and TM-β-CD, respectively. HP forms a 1:1 complex with 1,1′-diheptyl-4,4′-bipyridinium dibromide (DHB) in aqueous solution. In contrast to the addition of CDs, the HP fluorescence is significantly quenched by the addition of DHB. The equilibrium constant for the formation of the HP–DHB complex has been evaluated to be 1.98×10⁵?mol^-1?dm³ from the fluorescence intensity change of HP. The addition of DHB to an HP solution containing β-CD induces a circular dichroism signal of negative sign, indicating the formation of a ternary inclusion complex involving β-CD, HP, and DHB. In contrast, there is no evidence for the formation of a ternary inclusion complex of HP with DHB and TM-β-CD.     

Inclusion of Paracetamol into β-cyclodextrin nanocavities in solution and in the solid state

We report on steady-state UV-visible absorption and emission characteristics of Paracetamol, drug used as antipyretic agent, in water and within cyclodextrins (CDs): β-CD, 2-hydroxypropyl-β-CD (HP-β-CD) and 2,6-dimethyl-β-CD (Me-β-CD). The results reveal that Paracetamol forms a 1:1 inclusion complex with CD. Upon encapsulation, the emission intensity enhances, indicating a confinement effect of the nanocages on the photophysical behavior of the drug. Due to its methyl groups, the Me-β-CD shows the largest effect for the drug. The observed binding constant showing the following trend: Me-β-CD>HP-β-CD>β-CD. The less complexing effectiveness of HP-β-CD is due to the steric effect of the hydroxypropyl-substituents, which can hamper the inclusion of the guest molecules. The solid state inclusion complex was prepared by co-precipitation method and its characterization was investigated by Fourier transform infrared spectroscopy, 1H NMR and X-ray diffractometry. These approaches indicated that Paracetamol was able to form an inclusion complex with CDs, and the inclusion compounds exhibited different spectroscopic features and properties from Paracetamol.     

Gamma-cyclodextrin on enhancement of water solubility and store stability of nystatin

The water solubility of nystatin was found enhanced by forming inclusion complex with gamma-cyclodextrin (γ-CD). Further discovery of a pleased surprise showed that the phase solubility curves of nystatin in β- and γ-CD aqueous solution were A_L type, while B_S type for α-CD, indicating 1:1 inclusion complexes were formed between β-CD, γ-CD and nystatin, but no inclusion complexes for α-CD, in addition, CDs with much larger ring would be more suitable for forming inclusion complexes with macrolide antibiotics. The aqueous solubility of nystatin in γ-CD solution was investigated increased with γ-CD concentration increasing. At the concentration of 24 g/100 ml for γ-CD aqueous solution, which is near to the saturated solution, water solubility of nystatin was found to be 104 μg/ml, which was 103 folds over original nystatin. Inclusion constants for γ-CD–nystatin complexes were 0.539 l/mmol, which is larger than that of β-CD–nystatin complex (0.375 l/mmol). The inclusion complex of γ-CD with nystatin was prepared and detected by infrared spectrum, results showing that the ester linkage and diene were included in the cavity of CDs, while conjugate arachidonic, carboxyl and amino group were left outside of CDs. Storing experiment showed that forming of the inclusion complexes greatly enhanced the stability of nystatin against light and oxygen.     

Host–guest complexation of a nitroheterocyclic compound with cyclodextrins: a spectrofluorimetric and molecular modeling study

Nitroheterocyclic compounds (NC) were candidate drugs proposed for Chagas disease chemotherapy. In this study, we investigated the complexation of hydroxymethylnitrofurazone (NFOH), a potential antichagasic compound, with α-cyclodextrin (α-CD), β-cyclodextrin (β-CD), Hydroxypropyl-β-cyclodextrin (HP-β-CD), Dimethyl-β-cyclodextrin (DM-β-CD) and γ-cyclodextrin (γ-CD) by fluorescence spectroscopy and molecular modeling studies. Hildebrand–Benesi equation was used to calculate the formation constants of NFOH with cyclodextrins based on the fluorescence differences in the CDs solution. The complexing capacity of NFOH with different CDs was compared through the results of association constant according to the following order: DM-β-CD > β-CD > α-CD > HP-β-CD > γ-CD. Molecular modeling studies give support for the experimental assignments, in favor of the formation of an inclusion complex between cyclodextrins with NFOH. This is an important study to investigate the effects of different kinds of cyclodextrins on the inclusion complex formation with NFOH and to better characterize a potential formulations to be used as therapeutic options for the oral treatment of Chagas disease.     

Study of inclusion complex formation between a cationic surfactant, two cyclodextrins and a drug

In this study inclusion of hexadecyltrimethylammonium bromide (HTAB) with α-, and β-cyclodextrin (CD) in the presence and the absence of bromhexine (BH) was investigated using ion-selective electrode method. The association constants of HTAB with CDs were determined by potentiometry and were close to literature values. The obtained results indicated that α-CD formed 1:1 and 1:2 inclusion complexes, but β-CD formed only a 1:1 inclusion complex. In the presence of drug, the interaction between CDs and HTAB decreased, because both drug and HTAB could interact with CDs. The results showed that the interaction between drug and CDs are greater than HTAB and CDs. The stoichiometry of the inclusion complexes, the critical aggregation concentration (CAC), the monomer surfactant concentration of HTAB, [HTAB]_f, and also the effect of the inclusion complex on the micellization process of the HTAB were determined by conductivity measurements.     

Investigation on the inclusion behaviour of baicalein with β-cyclodextrin and derivatives and their antioxidant ability study

The formation of the complexes of baicalein (Ba) with β-cyclodextrin (β-CD) and β-CD derivatives (HP-β-CD and Me-β-CD) was studied by UV–vis absorption spectroscopy, fluorescence method, nuclear magnetic resonance spectroscopy and phase-solubility measurement. The solid–inclusion complexes of Ba with CDs were synthesised by the co-precipitation method. The characterisations of the solid–inclusion complexes have been proved by infrared spectra and differential scanning calorimetry. Experimental conditions including the concentration of various CDs and media acidity were investigated in detail. The results suggested that the inclusion ratio of HP-β-CD with Ba was the highest among the three kinds of CDs. The binding constants (Ks) of the inclusion complexes were determined by fluorescence method and phase-solubility measurement. Kinetic studies of DPPH√ with Ba and CDs complexes were also done. The results indicated that the Ba/HP-β-CD complex was the most reactive form.     

Spectroscopic study and antioxidant activity of the inclusion complexes of cyclodextrins and amlodipine besylate drug

The aim of the study was to synthesize and characterization the inclusion complexes of amlodipine besylate (AML) drug with β-cyclodextrin (β-CD) and γ-cyclodextrin (γ-CD) which has antioxidating activity property. The guest/host interaction of AML with β-CD and γ-CD in order to complexation drug in β-CD and γ-CD were investigated. The interaction inclusion complexes was characterized by fourier transform infrared and ultraviolet–visible spectroscopies. The formation constant was calculated by using a modified Benesi–Hildebrand equation at 25 °C. The stoichiometry of inclusion complexes was found to be 1:1 for β-CD and γ-CD with AML drug. The antioxidant activity of AML drug and its inclusion complexes were determined by the scavenging of stable radical 2,2′-diphenyl-1-picrylhydrazyl (DPPH^·). Kinetic studies of DPPH^· with AML and CDs complexes were done. The experimental results confirmed the forming of AML complexes with CDs also these indicated that the AML/β-CD and AML/γ-CD inclusion complexes was the most reactive than its free form into antioxidant activity.