侧链携带金刚烷的聚(N-异丙基丙烯酰胺)与环糊精二聚体构筑可控超分子体系

合成了侧链携带金刚烷的温敏性聚合物(Pnipam-Ad)及环糊精二聚体(trans-Azo β-CD Dimer),利用Pnipam-Ad侧链的金刚烷与trans-Azo β-CD Dimer的主客体识别作用构筑了超分子体系.以二维核磁共振谱(2D NMR)、粘度法等手段对Pnipam-Ad与trans-Azo β-CD Dimer之间的主客体包结作用进行了研究,两者之间的缔合受Pnipam-Ad和trans-Azo β-CD Dimer浓度及trans-Azo β-CD Dimer光异构的影响.此外,trans-Azo β-CD Dimer对Pnipam-Ad聚合物链的物理交联作用使两者混合溶液的最低临界溶解温度(LCST)低于纯P(NIPAM)的LCST.     

基于环糊精二聚体与紫精聚合物的包结作用制备超分子水凝胶

制备了对苯二甲酸连接的环糊精二聚体(α,α-CD Dimer)及紫精聚合物(VP), 利用α,α-CD Dimer与VP之间的主客体识别作用构筑了一种超分子水凝胶. ¹H NMR测定结果表明α,α-CD Dimer和VP的主客体相互作用是通过α-CD空腔和VP形成包结络合物进行的. 环糊精二聚体α,α-CD Dimer和聚合物VP凝胶体系的构筑受环糊精二聚体类型的影响, 同时该超分子水凝胶对有竞争作用的客体分子表现出响应性, 该超分子水凝胶在竞争性客体分子存在的条件下, 可发生小分子诱导的凝胶与溶胶转化行为. 此外, 该凝胶体系还具有良好的热稳定性.     

气相中环糊精与甘氨酰-苯丙氨酰-苯丙氨酸和甘氨酸三肽非共价复合物的质谱研究

为了探索环糊精和寡肽的非共价相互作用, 一定化学计量比的α-, β-, γ-环糊精(CD)分别和甘氨酸三肽(GGG)、甘氨酰-苯丙氨酰-苯丙氨酸三肽(GFF)在室温下反应达到平衡并用正离子模式质谱检测. 实验结果显示GGG, GFF均可以和α-, β-, γ-CD生成1:1配合比的非共价复合物. 碰撞诱导解离实验进一步验证了α-, β-, γ-CD与GGG, GFF非共价复合物的形成. 质谱滴定法测得的结合常数结果表明环糊精和两种三肽形成非共价复合物的结合强度均按照γ-, β-, γ-CD的次序逐渐增大. GGG和α-, β-, γ-CD复合物的结合常数分别为2799.96, 2528.73, 1697.11 L·mol^-1, GFF和α-, β-, γ-CD复合物的结合常数分别为2773.94, 2134.03, 1330.68 L·mol^-1. 对于α-, β-或γ-CD, 含有苯基的GFF+CD复合物的结合强度要小于相应的脂肪族的GGG+CD复合物, 表明虽然在气相GFF+CD复合物的构象与溶液中的构象有所变化, 但是苯基仍然参与和环糊精疏水腔体的键合作用.     

齐墩果烷型和乌苏烷型五环三萜同分异构体配位色谱法分离机理（英文）

本文主要研究了配位色谱法分离齐墩果烷型和乌苏烷型五环三萜同分异构体的分离机理。基于计算模拟分析,β-环糊精（β-CD）和其衍生物为适宜的配位剂。采用HPLC法测定了包合物的表观形成常数,并制备了asiaticoside-B与β-CD包合物。实验结果显示:流动相中添加葡萄糖基-β-环糊精（Glu-β-CD）时,同分异构体的分离度为11.95,比添加β-CD或添加甲基-β-环糊精（DM-β-CD）时（分别为9.61和9.89）都略高些。假定五环三萜类化合物与β-CD形成1：1的包合物,对于asiaticoside-B,流动相中添加Glu-β-CD时,表观形成常数（K_F）为2534 L/mol,比添加β-CD或添加DM-β-CD时（分别为1467和1373 L/mol）都略大些。根据asiaticoside-B与β-CD包合物的红外光谱解析及计算模拟,推测asiaticoside-B的E环上甲基部分进入了β-CD的空腔内,而其羰基基团没有进入β-CD的空腔内,其糖苷部分与亲水性的β-CD空腔外部形成氢键作用力。因此,配位色谱法分离齐墩果烷型和乌苏烷型五环三萜同分异构体的分离机理可以推测如下：齐墩果烷型和乌苏烷型五环三萜同分异构体E环上甲基的不同空间位阻导致了同分异构体的不同色谱分离行为。     

双敏感性环糊精超分子聚集体的制备及其性能研究

利用光敏感性环糊精衍生物与温度敏感性聚合物主客体间的包结络合作用制备了具有光/温度双敏感性的环糊精超分子聚集体. 首先制备了主体分子光敏感性4-羟基肉桂酸-β-环糊精(4HCA-CD); 再以末端带金刚烷基团(AD)的三硫酯作为链转移剂, 用可逆加成-断裂链转移自由基聚合(RAFT)法制备温度敏感性双臂聚合物AD-PNIPAM-AD; 用傅里叶变换红外光谱(FT-IR)、核磁共振氢谱(¹H NMR)证明了化合物的结构. 利用β-CD的疏水空腔和AD之间的络合性能, 制备了4HCA-CD/AD-PNIPAM-AD双敏感性超分子复合物, 通过二维核磁(2D NMR)对其包结性能进行了探究, 结果证实金刚烷包结于环糊精的空腔中. 所得4HCA-CD/AD-PNIPAM-AD复合物具有光敏感性, 用紫外光照射后, 复合物的分子量增大近一倍. 而且, 4HCA-CD/AD-PNIPAM-AD复合物可以自组装形成超分子聚集体, 其粒径随温度的升降发生可逆的减小或增大.     

一种新型酶生物燃料电池阳极构建及性能研究

通过酸化碳纳米管(CNTs)和β-环糊精(β-CD)之间的范德华力作用, 实现CNTs的β-CD功能化. β-CD具有内腔疏水、外壁亲水的环状结构, 其内腔容易与二茂铁(Fc)形成稳定的主客体包合结构, 实现Fc在碳纳米管上的高效固载; 再将CNTs-β-CD-Fc复合物与葡萄糖氧化酶(GOD)混合, 采用戊二醛实现酶分子间的交联, 形成GOD/CNTs-β-CD-Fc复合物, 然后将其涂覆到玻碳电极(GC)上, 得到一种新型的酶生物燃料电池阳极(GOD/CNTs-β-CD-Fc/GC). 采用同步热分析法、傅里叶变换红外光谱和透射电子显微镜对所制备的CNTs-β-CD-Fc复合物进行了表征, 采用循环伏安法研究了GOD/CNTs-β-CD-Fc/GC电极对葡萄糖氧化的催化性能. 结果表明: 在同等实验条件下, 没有固载Fc的GOD/CNTs- β-CD/GC电极基本无催化电流, 而GOD/CNTs-β-CD-Fc/GC电极表现出比GOD/CNTs-Fc/GC电极更为优越的电催化性能. 进一步以GOD/CNTs-β-CD-Fc/GC电极或GOD/CNTs-Fc/GC电极为酶阳极, 商用催化剂E-TEK Pt/C电极(E-TEK Pt/C/GC)为阴极, 构建葡萄糖/氧气生物燃料电池(EBFC), 结果表明前者的最大功率密度(33 μW·cm^-2, 0.18 V)几乎是后者的三倍(11.7 μW·cm^-2, 0.16 V). 通过记录开路电位随时间的变化研究了EBFC的稳定性, 以GOD/CNTs-β-CD-Fc/GC电极为阳极的EBFC在连续工作9 h后仍保留了92%的开路电位, 表明该电池具有良好的连续工作稳定性. 我们提出的这种新型生物燃料电池阳极的构造方法, 为构建高性能、高稳定性的葡萄糖/氧气EBFC提供了新的思路.     

柚皮苷印迹β-环糊精聚合物的制备及性能研究

以柚皮苷(NG)为印迹分子, β-环糊精为功能体, 六亚甲基二异氰酸酯为交联剂, 采用乳液聚合法制备了对NG具有特定识别能力的吸附材料: 棒状印迹聚合物. 扫描电镜及比表面分析仪测试结果表明印迹聚合物具有较大的孔隙及比表面积|红外及核磁共振谱研究证实了识别位点来自β-环糊精与NG羟基间的氢键作用. 采用平衡吸附实验方法研究了聚合物的吸附性能和选择性能. 实验结果表明, 棒状印迹聚合物(RMIP)对NG具有较高的亲和性和选择性. Scatchard分析表明, MIP在识别NG过程中存在2类结合位点: K_D1＝0.016 mmol/L, B_max1＝15.31 μmol/g, K_D2＝0.24 mmol/L, B_max2＝98.41 μmol/g. 当NG浓度为 0.02 mg/mL时, MIP及相应NIP对 NG的分配系数 K_{D 分别为4.38和2.86, 印迹因子α为1.53.}     

含两个识别点的侧链准聚轮烷的制备

合成了侧链含烷基链(C₇)及偶氮基团(Azo)两个疏水基团修饰的聚合物4,并基于环糊精与两个疏水基团C₇、Azo的不同结合能力,制备了含两个识别点的侧链准聚轮烷.首先,在聚合物4的溶液中加入α-环糊精(α-CD),α-CD分别包结在C₇及Azo部分,得到了侧链准聚轮烷;第二步,在365 nm的紫外光光照下,聚合物4侧链端基的trans-Azo异构为cis-Azo,α-CD从Azo部分解离,但α-CD仍包结在C₇部分,得到了侧链聚轮烷;第三步,在侧链聚轮烷溶液中加入β-环糊精(β-CD),β-CD包结在cis-Azo部分,得到了α-CD、β-CD分别包结两个疏水识别点的侧链准聚轮烷.     

酸敏感型嵌段共聚物mPEG-acetal-PIB的合成、表征及用于构筑水凝胶敷料

利用点击化学(“Click”)反应, 成功制备了一种通过酸敏感缩醛基团键合的两亲性嵌段共聚物, 聚乙二醇单甲醚-acetal-聚异丁烯(简写为mPEG-acetal-PIB). 通过核磁共振氢谱(¹H NMR)、红外光谱(FT-IR)和凝胶渗透色谱(GPC)对聚合物的结构、分子量及分子量分布进行表征. 利用芘荧光探针法、动态激光光散射(DLS)和透射电子显微镜(TEM), 研究共聚物在水溶液中组装的临界聚集浓度(CAC), 胶束的粒径大小、分布以及形貌. 利用DLS跟踪测试聚合物胶束在酸性条件下的粒径变化, 验证mPEG-acetal-PIB的酸敏感性质. 随后, 在体系中引入α-环糊精(α-CD), 诱导形成超分子水凝胶. 利用X射线衍射(XRD)分析PEG与α-CD的包结络合作用, 流变仪测试水凝胶的凝胶化时间和黏弹性. 通过体外细胞毒性试验(MTT法)证明嵌段共聚物mPEG-acetal-PIB及水凝胶均具有良好的生物相容性. 这种水凝胶能够保持创面湿润, 具有温和的冷却作用, 并且由于其带有酸敏感基团, 能够在偏酸性环境降解, 减少炎症发生率, 在水凝胶创伤敷料中具有潜在的应用.     

水溶性β-环糊精聚合物和疏水改性聚丙烯酰胺的主客体相互作用

主体环糊精聚合物(β-CDE)与客体疏水改性丙烯酰胺共聚物P(AM/POEA)构成超分子结构的高分子识别体系. 这种客体聚合物是含有少量疏水体(x_POEA＜0.01)的水溶性聚合物, NMR测定结果表明β-CDE和P(AM/POEA)的主客体相互作用是通过环糊精空腔和疏水体POEA形成包结络合物进行的. 在P(AM/POEA)聚合物水溶液中加入β-CDE, 由于主客体聚合物相互作用出现粘度的大幅上升, 增粘的幅度可通过改变聚合物浓度和疏水体含量来调节, 同时对盐浓度和温度的影响也进行了研究. 通过透射电镜直观观察的结果表明, 此类缔合聚合物体系的主客体相互作用生成实心球状多分子聚集体.     

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.     

Mass spectrometry and molecular modeling studies on the inclusion complexes between alendronate and β-cyclodextrin

Complexation of alendronate sodium (AlnNa) with β-cyclodextrin (β-CD) was studied by means of ESI-mass spectrometry. The experimental results show that stable 1:1 inclusion complexes between selected bisphosphonates and β-CD were formed. In addition, complexes with different stoichiometry were observed. DFT/B3LYP calculations were performed to elucidate the different inclusion behavior between alendronate and β-CD. Molecular modeling showed that the inclusion complex of Aln-β-CD where the two phosphonate groups bound to the central carbon atom of bisphosphonate were inserted into the cavity of β-CD from its “top” side was thermodynamically more favorable than when they were inserted from its “bottom” side; the complexation energy was ?74.05 versus ?60.85 kcal/mol. The calculations indicated that the formation of conventional hydrogen bonds was the main factor for non-covalent β-CD:Aln complex formation and stabilization in the gas phase.     

A spectroscopic and molecular modeling studies of the inclusion complexes of orciprenaline and terbutaline drugs with native and modified cyclodextrins

The inclusion complexation behavior of orciprenaline (ORC) and terbutaline (TER) with α-CD, β-CD, HP-α-CD and HP-β-CD are examined by absorption, fluorescence, life time and molecular modeling methods. ORC and TER forms 1:1 (CD/drug) inclusion complexes in lower CD concentrations and 1:2 (CD/drug) inclusion complexes with higher CD concentrations. The inclusion of both drugs with HP-CDs was stronger than that of native CDs. Both drugs exhibit dual emission (excimer) in the CD solution, whereas in water single emission is seen. The hydrogen bonding and van der Waals interaction between the drugs and the CD plays an important role in the inclusion complexes. Computational results show the side chain of the drugs encapsulated in the CD cavity. The molecular modeling results by PM3 were in good agreement with the experimental results.     

Effects of water and alcohol on the formation of inclusion complexes of d-limonene and cyclodextrins

Abstract

Systematic studies have been carried out on the role of water and alcohol in the formation of inclusion complexes between d-limonene and α-, β- and γ-cyclodextrin (CD) by a micro-aqueous method. The inclusion complex was barely formed at zero water content for all CDs. Above the specific water content for each CD, formation of the inclusion complex correlated well with an equation which was derived on the autocatalytic assumption for the inclusion phenomenon. The inclusion complex correlated well with an equation which was derived on the autocatalytic assumption for the inclusion phrnomenon. The minimum water content, which was defined as 1% of the maximum concentration of the inclusion complex formed, coincided with the number of water molecules inside the cavity of the CD. In the presence of ethanol, a significant amount of the inclusion complex was formed for β- and γ-CD/limonene systems, particularly at lower moisture content. However, for α-CD the inclusion fraction decreased significantly in the presence of ethanol. This means that ethanol inhibits the formation of the inclusion complex between x-CD and d-limonene. For other linear alcohols, the formation of the inclusion complex between d-limonene and β-CD increased with decreasing alkyl chain length. This suggests that the more hydrophilic and the smaller (in molecular size) the alcohol is, the more enhanced is the inclusion of d-limonene to β-CD.     

Dissolution enhancement of artemisinin with β-cyclodextrin

The main objective of this research is to improve the dissolution rate of artemisinin (ART) by fabrication with β-cyclodextrin (β-CD) as a hydrophilic carrier. Artemisinin nanoparticles and ART/β-CD complexes were successfully fabricated by means of evaporative precipitation of nanosuspension. Characterization of the samples was done by scanning electron microscopy (SEM), Fourier transform infrared (FT-IR), X-ray diffraction (XRD), differential scanning calorimetry (DSC) and dissolution tester. Percent dissolution efficiency, mean dissolution time, relative dissolution and similarity factor were calculated for the statistical analysis of dissolution data. FT-IR showed some interaction between ART and β-CD, which can be due to the formation of some ART/β-CD complexes. XRD study indicated the presence of two polymorphs of ART, i.e. orthorhombic and triclinic form. Original ART particles and ART nanoparticles fabricated were orthorhombic whereas the free ART in the ART/β-CD complexes (not forming complex with β-CD) was of triclinic form. The crystallinity of ART reduced and more and more ART/β-CD complexes were formed with increasing concentration of β-CD as indicated by the DSC, XRD and FT-IR studies. Artemisinin nanoparticles and ART/β-CD complexes showed significantly faster dissolution than the pure drug due to smaller size (larger surface area), formation of the inclusion complex with β-CD, formation of the triclinic form for remaining free ART (not forming complex with β-CD), and amorphous state formation. Evaporative precipitation of nanosuspension was able to successfully fabricate artemisinin in the nanoparticles and complex forms with significantly faster dissolution rates than that of the original artemisinin. The two polymorphic forms of ART were also fabricated and studied.     

Enhancement of Dissolution Behavior of Aceclofenac by Complexation with β-Cyclodextrin-Choline Dichloride Coprecipitate

The objective of the present investigation was to study the effect of presence of choline dichloride (CDC) in β-cyclodextrin (β-CD) on in vitro dissolution of aceclofenac (AF) from molecular inclusion complexes. The molecular inclusion complexes of AF with β-CD coprecipitated with CDC in 1:1 and 1:2 M ratio were prepared using kneading method. In vitro dissolution of pure drug, physical mixtures, and cyclodextrin inclusion complexes (AF-β-CD-CDC) were carried out. Molecular inclusion complexes of aceclofenac with coprecipitated β-CD showed considerable increase in the dissolution rate in comparison with physical mixture and pure drug in 0.1 N HCl, pH 1.2 and phosphate buffer, pH, 7.4. Inclusion complexes with 1:2 M ratio showed maximum dissolution rate in comparison to other ratios. FTIR spectroscopy and differential scanning calorimetry studies indicated no interaction between AF and β-CD-CDC in complexes in solid state. Dissolution enhancement was attributed to the formation of water soluble inclusion complexes with the precipitated form of β-CD. The in vitro release from all the formulations was best described by first order kinetics (R ² = 0.9354 and 0.9268 in 0.1 N HCl and phosphate buffer, respectively) followed by Higuchi release model (R ² = 0.9029 and 0.9578 in 0.1 N HCl and phosphate buffer, respectively). In conclusion, dissolution of aceclofenac can be enhanced by using the β-CD-CDC coprecipitate as a host molecule.     

Characterization of permethylated β-cyclodextrin-peptide noncovalently bound complexes using electron capture dissociation mass spectrometry (ECD MS)

Electron capture dissociation mass spectrometry (ECD MS) was carried out for a number of β-permethylated cyclodextrin (CD)-peptide noncovalent complexes in a Fourier transform ion cyclotron resonance (FTICR) mass spectrometer. Examined peptides included Angiotensin II (DRVYIHPF), Substance P (RPKPQQFFGLM), and Bradykinin (RPPGFSPFR) and its analogs (PPGFSPFR and RPPGFSPF). ECD MS for doubly protonated complexes [M:CD+2H]²⁺ mainly yielded cleavage of the backbones of the constituent peptide with little disassembly of a peptide and β-CD. Analysis of ECD MS fragments indicated that a protonated basic amino-acid residue or N-terminal amino group interacted more favorably with β-CD than did aromatic group-containing amino-acid residues (inclusion complex). In contrast to the formation of inclusion CD complexes in solution, we observed no specific evidence from our ECD MS mass spectra to support the generation of phenyl inclusion complexes in the gas phase. For gas-phase peptides, we suggest that ion–dipole interaction is the main driving force for the formation of noncovalent β-CD complexes rather than phenyl inclusion interactions.     

Investigation of the complexation of essential oil components with cyclodextrins

The formation of inclusion complexes of six essential oil (EO) components (β-caryophyllene, cis-ocimene, trans-ocimene, sabinene hydrate (thujanol), γ-terpinene and α-terpineol) with six cyclodextrins (CDs) (α-CD, β-CD, γ-CD, HP-β-CD, RAMEB and CRYSMEB) was investigated by using static headspace-gas chromatography and UV–visible spectroscopy. Retention studies showed that CDs could efficiently reduce the volatility of EO components except for β-caryophyllene with α-CD. In this case, no inclusion complex was detected while for other compounds the formation of 1:1 inclusion complexes was observed. Results revealed that the inclusion stability mainly depends on geometric complementarity between encapsulated molecule and CD's cavity. Molecular modelling was used to investigate the complementarities between host and guest. Thus, CDs could efficiently be regarded as promising encapsulants for EO components leading to improve their application in cosmetic, pharmaceutical and agriculture fields.     

Diarylethylene guest anchored into a cyclodextrin molecular host: optical,quantum chemical studies and biological activity

The host–guest complexation between a novel guest namely; 2-(4-pyridinylbenzothiazolyl) ethane, PBE and β-cyclodextrin was studied using steady-state absorption and emission techniques. The fluorescence maximum is strongly blue-shifted with a great enhancement in the fluorescence intensity upon addition of β-CD, confirming the formation of inclusion complexes. The solid inclusion complex between PBE and β-CD has been prepared, characterised using FT-IR, X-ray diffraction and scanning electron microscope techniques. PBE is encapsulated with β-CD nanocavity and 1:1 PBE–β-CD host–guest interaction is identified. This is confirmed using semi-empirical quantum chemical calculations. PBE guest entered into the less polar cavity through the benzothiazole moiety. The negative values of enthalpy and free energy changes suggest that the encapsulation process is thermodynamically favourable. Additionally, the fluorescence is more sensitive to the micellar medium, whether it was cationic, anionic or neutral as well as metal ions like, Li⁺, Cu²⁺ and Fe³⁺. Finally, the antimicrobial activities of PBE guest and its inclusion complex with β-CD host are studied.