向日葵状葫芦脲的合成与超分子自组装

葫芦脲(CB[n],n为最小重复单元数)是一类由苷脲与甲醛经缩合环化而形成的大环分子,因具有良好的分子识别性能及配位性能,在分离、催化、医药、互锁分子及超分子体系构建等领域有着广泛的应用。本课题组在苷脲分子中间的桥上增加一个碳原子,得到苷脲类似物丙基二脲(TD),TD进一步与甲醛缩合环化得到一系列向日葵状葫芦脲类似物(TD[n])。与传统苷脲相比,TD容易在碳原子上衍生化,衍生物对成环反应的影响较小,容易获得TD[n]。相比CB[n]的n最小值为5,TD[n]的n最小值减小到4,TD[4]是目前为止文献报道的葫芦脲家族的最小成员。此外,这些TD[n]有的对金属离子具有很好的选择配位能力,有的对质子化有机胺具有强的外结合性能,它们分别构建了一系列一维、二维或刺激响应型超分子聚合物。研究结果为TD[n]在超分子化学等领域的进一步应用打下坚实的基础。     

葫芦脲大环官能团功能化

新型大环化合物的设计与合成一直以来都是超分子化学的研究热点。冠醚、环糊精、杯芳烃和葫芦脲等经典大环分子,以及柱芳烃等新兴大环分子的发展丰富了超分子化学的研究内容。其中,官能团功能化的大环化合物被广泛应用于化学传感器、分子机器、仿生系统、超分子催化、刺激响应体系、功能材料以及药物传递等众多领域。葫芦脲大环具有一个刚性的疏水空腔,由于其独特而优秀的水相识别能力而备受关注。然而,相对于其他大环化合物,葫芦脲由于其官能团功能化难题而发展相当缓慢。近年来,葫芦脲大环官能团功能化的研究获得了巨大的突破,将葫芦脲大环的主客体识别性质从传统的超分子化学拓展到生物化学、材料化学以及药物化学等交叉研究领域。本文重点总结葫芦脲大环官能团功能化现阶段的研究进展,并对其合成方法进行简单明晰的总结与展望。     

常见大环自组装构建分子胶囊

分子胶囊以其独特的分子结构在控制药物释放、催化、材料科学和生物医药等领域具有潜在的应用价值.分子胶囊可由不同的分子模块通过共价键或非共价键构建.着重描述了由常见的大环主体(环糊精、杯芳烃、杯吡咯、卟啉、环三藜芦烯和葫芦脲)通过自组装形成的分子胶囊.这些分子胶囊通过非共价键(氢键、静电作用、疏水作用及范德华力等)连接,使得分子胶囊具有可控的可调节的分子结构.通过这些独特的分子结构,分子胶囊可在溶液或固相中包裹各种各样的有趣的客体.     

环三藜芦烃的分子识别与组装

环三藜芦烃是一类基于藜芦醚与甲醛缩聚物的大环主体分子,其具有独特的C3对称结构和刚性的富电子空腔,在超分子化学、材料科学等方面具有潜在的应用价值,受到人们越来越多的重视.本文主要概述了近年来环三藜芦烃及其衍生物在分子识别与超分子组装方面的一些研究进展.     

带极性侧链的环[6]芳酰胺的球形自组装

环芳酰胺是一类基于三中心氢键促进,经寡聚前体一步大环合成法得到的刚性大环分子.通过紫外-可见(UV-Vis)光谱、动态光散射(DLS)、扫描电镜(SEM)、透射电镜(TEM)和原子力显微镜(AFM)等实验手段,详细考察了侧链为三甘醇单甲基醚链,由六个苯环单元组成的环[6]芳酰胺的自组装行为.实验结果表明,该大环在1,2-二氯乙烷中发生自组装,其组装聚集体随温度升高产生从聚集体到单分子的解聚变化,至70℃时几乎完全解聚;在由良溶剂(二氯甲烷)和不良溶剂(芳烃类)组成的混合溶剂中,带有三甘醇醚链的环[6]芳酰胺化合物1自组装成微球,结合热稳定性实验和TEM证实是实心微球而非囊泡.进一步发现微球形成和形貌依赖于混合溶剂中不良溶剂的极性和种类,芳烃类溶剂有利于微球形成,而烷烃和极性溶剂则不利,后者更倾向于形成膜的结构.     

葫芦脲：分子识别与组装

综述了葫芦脲这一类合成受体的最新研究进展，包括葫芦脲的分子设计与合成 ，离子和分子识别，键合的热力学性质，分子组装及其功能的最新研究概况。     

基于中性芳环间电子供体-受体相互作用驱动的有机超分子组装

综述了近年来中性单体分子之间的供体-受体相互作用在超分子自组装研究中的应用.首先介绍了应用广泛的典型中性芳环富电子和缺电子体系的种类,然后重点介绍了DAB和DAN作为富电子单元,PDI和NDI作为缺电子单元的供体-受体相互作用在互相锁链的超分子体系,非天然分子折叠体和二聚体组装方面的应用进展.     

[60]富勒烯的超分子自组装研究进展

超分子自组装是发展超分子电子学的重要途径。随着纳米科学和技术的迅速发展,自组装技术已成功地应用于纳米尺度物质的维数、形貌和功能等的调控。作为构筑分子水平上一维、二维、三维有序功能结构和高有序分子聚集态结构的关键技术,超分子自组装技术有力地推动了具有优良光、电、磁性能的分子材料和纳米功能材料更深层次的研究。本文综述了超分子自组装在富勒烯科学领域的基础研究和应用,特别是对有利于自组织和自组装功能的富勒烯基衍生物的设计与合成、超分子作用力引导的具有特定结构的分子体系的可控自组装、以及富勒烯分子聚集态结构材料的光物理过程、超分子中电子转移和能量转移现象进行了描述;并对卟啉、四硫富瓦烯、碗烯和杯芳烃等一系列富π电子化合物和大环主体分子等包含[60]富勒烯的主体化合物的超分子作用和超分自组装体以及通过氢键、π-π作用、静电力和范德华力和金属配位作用形成的[60]富勒烯超分子自组装体进行了总结,对未来发展进行了展望。     

杯[4]吡咯大环化合物的合成和性能

通过改进的吡咯与酮缩合反应制备了一系列杯[4]吡咯大环主体分子,并由元素分析、IR、^1H NMR,MS确证结构。作为一类新型的阴离子和中性分子的受体,其性能通过光谱滴定实验进行了初步研究。     

葫芦[n]脲超分子水凝胶的研究进展

超分子化学的发展一直是众多研究者所关注的一大热点,葫芦[n]脲作为第四代大环主体分子,拓宽了超分子化学领域的发展.水凝胶是一种具有可拉伸性、生物相容性、环境响应性等多种优异性能的软材料.人们充分利用葫芦[n]脲优异的分子识别能力和配位能力,研究出了一系列具有特殊功能的超分子水凝胶材料.本文在结合葫芦[n]脲特点的基础上...     

Cucurbit[8]uril rotaxanes

The synthesis of [2]rotaxanes, each comprising a viologen core threaded through a cucurbit[8]uril (Q8, Figure 1) macrocycle and stoppered by tetraphenylmethane groups, and their binding to second guests as inclusion complexes in organic and aqueous media are described. Stoppering was observed to have little effect on binding. Chemical modification of the threaded guest was used to control solubility and binding characteristics, thus demonstrating a novel approach to making artificial receptors with readily modifiable properties.     

Bromination of N-phenyloxypropyl-N'-ethyl-4,4'-bipyridium in cucurbit[8]uril molecular reactor

CB[n](n=6-8) is a family of synthetic macrocyclic host molecules composed of n glycoluril units, which can be employed as molecular reactor. N-phenyloxypropyl-N'-ethyl-4,4'-bipyridium (1) was designed to form a host-guest inclusion complex with CB[n](n=6-8), subsequently, the bromination reaction of 1 and its corresponding inclusion complexes was investigated in this work. In the case of 1/CB[8], the folded including mode is quite helpful to acquire 1-bormination product completely through intramolecular charge transfer (ICT), and CB[8] can provide a safe bromination environment for 1.     

八元瓜环与抗癌药物甲氨蝶呤的超分子相互作用

利用紫外吸收光谱法考察了八元瓜环(Q[8])与抗癌药物甲氨蝶呤(MTX)的相互作用;同时研究了甲氨蝶呤的不同质子化形式及体系温度对相互作用的影响;计算了相应的稳定常数及热力学参数等.实验结果表明,Q[8]与MTX作用比为1∶1,包结平衡常数为(7.64±1.52)×104 L/mol;龄前热力学参数测定结果表明,上述主...     

Cucurbit[5]uril, Decamethylcucurbit[5]uril and Cucurbit[6]uril. Synthesis, Solubility and Amine Complex Formation

A simple way to prepare cucurbit[5]uril is described. The macrocycles of the cucurbituril type are nearly insoluble in water. The solubilities of cucurbit[5]uril, decamethylcucurbit[5]uril and cucurbit[6]uril in hydrochloric acid, formic acid and acetic acid of different concentrations have been investigated. Due to the formation of complexes between cucurbit[n]urils and protons the solubility increases in aqueous acids. The macrocyclic ligands are able to form complexes with several organic compounds. Thus, the complex formation of the cucurbituril macrocycles with different amines has beenstudied by means of calorimetric titrations. The reaction enthalpy gives noevidence of the formation of inclusion or exclusion complexes. ¹H-NMR measurements show that in the case of cucurbit[5]uril and cucurbit[6]uril the organic guest compound is included within the hydrophobic cavity. Decamethylcucurbit[5]uril forms only exclusion complexes with organicamines. This was confirmed by the crystal structure of the decamethylcucurbit[5]uril-1,6-diaminohexane complex.     

Cucurbit[10]uril

Melamine diamine 1 is able to displace CB[5] from the CB[10].CB[5] complex resulting in CB[10].12 and precipitated CB[5].1. We were able to isolate free CB[10] by treatment of CB[10].1 with acetic anhydride followed by washing with MeOH, DMSO, and water. The spacious cavity of CB[10] is able to complex large guests, including a cationic calix[4]arene derivative in its 1,3-alternate form (CB[10].1,3-alt-3). The addition of adamantane carboxylic acid (4) to CB[10].3 triggers a conformational change during the formation of termolecular complex CB[10].cone-3.4.     

Study on the Interaction and Properties of Cucurbit[8]uril with Oroxin B

The interaction between cucurbit[8]uril(Q[8]) and oroxin B(ORB) was investigated by UV-visible(UV-Vis) spectroscopy, isothermal titration calorimetry(ITC), mass spectrum(MS) and nuclear magnetic resonance(NMR) spectroscopy. The results showed that ORB formed a 2:1 inclusion complex with Q[8] with a binding constant of 8.266×10⁵ L²·mol^-2. ORB had good scavenging ability for 2,2'-azinobis-(3-ethylbenzthiazoline-6-sulphonate)(ABTS) free radicals(IC₅₀=5.74 μmol/L) and the addition of Q[8] did not significantly affect the antioxidant activity of ORB(IC₅₀=5.76 μmol/L). A phase solubility experiment revealed a 1.86-fold increase in the solubility of ORB when c(Q[8])=100 μmol/L. In vitro drug release experiments showed that the release rate for ORB@Q[8] complex was lower than that of ORB in artificial intestinal juice, and higher than that of ORB in artificial gastric juice.