唑类超分子药物研究与应用

基于非共价键力的超分子化学发展非常迅猛,在化学、物理、材料科学、信息科学以及医药等领域显示出广泛的应用前景和巨大的开发价值.唑类化合物如咪唑、噻唑、噁唑、吡唑、三唑、四唑和咔唑等具有特殊的含氮芳杂环结构,可通过非共价键力与无机物和/或有机物形成络合物超分子,表现出广泛的生物活性.近些年来,唑类超分子在医药领域发展迅速,已成为研究热点领域之一.结合本课题组相关研究工作,参考国内外近五年文献,系统地综述了唑类超分子作为药物在抗癌、抗细菌、抗真菌、杀虫、抗糖尿病、降血压、消炎等方面的研究与应用,并展望了其未来可能的发展趋势.     

1,2,3-三唑类化合物在分子识别中的应用

分子识别是超分子化学研究的重要内容,包括阳离子识别、阴离子识别和中性分子识别等.1,2,3-三唑因为其独特的结构和化学特性,广泛应用于超分子化学的各个领域.按照阳离子识别、阴离子识别以及中性小分子和生物大分子识别等类型,综述了近年来三唑类化合物在分子识别领域中的应用情况.     

仿生研究在靶向药物设计中的应用

仿生模拟研究一直是近20余年仿生化学十分活跃的热点领域.咪唑及三唑等唑类化合物因其具有较强的络合Fe,Zn,Cu,Co等金属离子的能力,且咪唑环作为组氨酸的一部分频繁出现在众多生物活性中心中,如血红蛋白、血蓝蛋白、蚯蚓血红蛋白、羧肽酶A、锌脂等,发挥着氧化还原、电子传递、氧气的传输及储存、催化水解等各种生化反应和转换,故广泛使用以咪唑等唑类化合物为基体构筑酶和受体的活性中心及作用部位的人工仿生分子在仿生研究中异常活跃,如对细胞色素P-450酶、羧肽酶A等多种金属酶和非金属酶或受体的模拟研究,进行仿生催化、仿生分子识别与络合等取得许多重要结果.     

肼类衍生物在五元唑类杂环合成中的应用进展

简要概述了肼类衍生物的结构及反应活性,总结了近十年来肼类衍生物分别在合成五元唑类杂环如吡唑、噻唑、1,3,4-噁二唑、1,3,4-噻二唑以及三唑类化合物,及其相关的稠杂环如吡唑并某环、s-三唑[3,4-b][1,3,4]-噻二唑、s-三唑[3,4-b][1,3,4]-噻二嗪,以及含有1,2,4-三唑的稠杂环化合物等合成中的应用进展.     

噁唑类化合物合成研究新进展

含N和O原子的噁唑环是十分重要的五元杂环,其特殊的结构使噁唑类化合物表现出许多独特的性能和生物活性,在医药、农药、材料等多方面具有广阔的潜在应用.因此,噁唑类化合物的合成备受关注,相关研究众多,发展迅速.根据我们唑类的研究工作,并参考国内外近5年文献,系统地综述了噁唑类化合物,包括噁唑、噁唑啉、噁唑烷酮、稠环噁唑类等的合成研究近况.     

四唑类化合物的合成及应用研究新进展

四唑是一种重要的五元芳杂环,具有多氮富电子的平面结构特征.这种特殊的结构使得四唑类化合物作为药物、炸药、功能材料等在医学、农学、材料科学等众多领域具有广泛的应用前景.相关研究十分活跃,已取得了许多重要进展.结合作者唑类方面的研究,参考国内外近五年文献,系统地综述了四唑类化合物的合成及其在医药、农药、材料等领域的应用研究新近况.     

噻唑类化合物应用研究新进展

噻唑环是一类重要的含氮硫杂原子的五元芳杂环,其特殊的结构使得噻唑类化合物在化学、药学、生物学和材料科学等诸多领域具有广阔的应用前景,显示出巨大的开发价值,受到广泛关注.本文结合作者的研究工作,参考国内外近五年文献,系统地综述了噻唑类化合物在医药、农药、材料、生物染色剂和超分子化学领域应用研究进展.     

含连三唑基均三唑、噻二唑、噁二唑类衍生物的电喷雾离子化质谱法测定

许多含三唑环和1,3,4-噻二唑环的化合物具有广谱和生物活性.如抗微生物、杀真菌、驱虫、止痛和消炎等作用,同时各种1,2,4-三唑和1,3,4-噁二唑衍生物也具有杀菌、抗微生物、植物生长调节等活性,从而引起化学家们对这几类化合物的广泛兴趣,并进行深入研究.最近,研究表明,将1,2,3-三唑引入某些活性分子可明显增强其药性.因而,对于1,2,3-三唑衍生物的合成及活性研究已成为唑类化合物研究的新热点.鉴于不同活性位点在同一分子中聚集,能明显改善化合物的生物活性这一特征,将2-苯基-1,2,3-三唑基引入到上述几类杂环体系中合成了一系列新的含连三唑基的1,3,4-噻二唑、1,3,4-噁二唑类衍生物,以期实现生物活性的叠加.     

轮烷类化合物的合成方法研究进展

轮烷类互锁分子因其多样的结构和性质,多年来一直是超分子化学领域的一个热点.综述了近年来轮烷类化合物的合成及制备方法,包括用传统的模板法(引入氢键、疏水作用、静电效应、配位和离子诱导等超分子作用)制备轮烷类化合物.除此之外,还介绍了利用“Click”化学、“穿线-收缩”、“穿线-膨胀”、自排序组织和自由基识别等新的合成手段来制备这类化合物.     

通过点击化学方法合成鹅去氧胆酸类分子钳及其识别性能研究

通过点击化学方法设计合成了12个新型的含有1,2,3-三唑结构的鹅去氧胆酸类分子钳人工受体.所有新目标物结构均经1H NMR,IR,MS及元素分析确证.利用紫外可见光光度滴定法测试了主体化合物对阳离子的识别作用.实验结果表明,主体分子对汞离子有良好的选择性识别性能.     

三唑类药物研究新进展

三唑类化合物作为药物广泛应用于临床,是目前药物研究开发的重点领域之一．越来越多的高活性、低毒性、不良反应少、多药耐药性小、生物利用率高、药代动力学性质好、药物靶向性强、给药方式多样化、广谱、高疗效的三唑类化合物作为候选药物或药物用于临床医治多种疾病,显示出了三唑类化合物在医药领域的巨大开发价值和潜在的宽广应用．本文结合自己的工作,参考国内外近五年文献系统地综述了三唑类化合物作为药物在整个医药领域的研究与开发近况,包括抗真菌、抗细菌、抗结核、抗癌、抗病毒、抗炎镇痛、抗惊厥等,并展望其发展趋势与前景．希望该评论有助于为高活性低毒性三唑类医药合理设计提供新思路．     

Macrocyclic supramolecular biomaterials in anti-cancer therapeutics

Macrocyclic supramolecular complexes demonstrate the dynamic potential to solve global biomedical challenges, a promising cancer treatment modality. The macrocyclic system is an important heterocyclic system widely present in natural products and synthetic molecules. The unique structural feature of macrocyclic supramolecular complexes with desirable donor & acceptor characteristics is beneficial for readily binding with various enzymes and receptors in biological systems through diverse weak interactions, thereby exhibiting broad bioactivities. Macrocyclic-related research and macrocyclic molecules-based medicinal chemistry developments have become rapidly developing areas of study. Numerous macrocyclic-based molecules as clinical drugs have been extensively used in the clinic to treat various diseases with high therapeutic potency. This critically analyzed work systematically reviews current developments of macrocyclic supramolecular complexes-based compounds in the range of medicinal chemistry as anticancer, anti-inflammatory, and other therapeutic agents, together with their potential applications in diagnostics and pathology. This review will be helpful for medicinal chemistry researchers to develop new thoughts in the quest for rational designs of more active and less toxic macrocyclic supramolecular complexes-based medicinal drugs, as well as more effective diagnostic agents and pathologic probes.     

芴类化合物的研究新进展

芴及其衍生物是一类重要的具有刚性平面联苯结构的化合物,分子内含有较大的共轭体系,这种特殊的刚性稠环结构使芴类化合物表现出许多独特的光电性能及生物活性,在光电材料、医药等多领域具有潜在的广泛应用.更为重要的是芴类化合物易于进行结构修饰,在芴环上可方便地引入各种功能基,芴类衍生物的合成及其开拓芴类化合物潜在的新用途,成为近些年来十分活跃的研究领域,且发展迅速.结合自己的工作,参考国内外文献,全面综述了芴类化合物在有机电致发光材料、双光子吸收材料、光致变色材料、太阳能电池材料和生物医药等领域的研究与开发新进展,并对其发展趋势作了展望.     

超分子化学药物研究

超分子药物化学是超分子化学在药学领域的新发展．该领域研究活跃,发展迅速,是一个充满活力的新兴交叉学科领域,并正在逐渐变成一个相对独立的研究领域．迄今已有许多两个或两个以上分子通过非共价键力形成的超分子化学药物应用于临床．超分子化学药物可具有良好的安全性、低毒性、不良反应少、高生物利用度、药物靶向性强、多药耐药性小、生物相容性好、高疗效以及其开发成本低、周期短、成功可能性大等诸多优点而备受关注,显示出超分子化学药物具有很大的发展潜力．本文首次给出了超分子药物的定义．结合自己的工作,参考国内外文献综述了超分子化学药物在抗肿瘤、抗炎镇痛、抗疟、抗菌、抗真菌、抗结核、抗病毒、抗癫痫、作为心血管和磁共振成像药物等医药领域的研究与开发状况,并展望其发展趋势与应用前景．     

Review on supermolecules as chemical drugs

Supramolecular medicinal chemistry field has been a quite rapidly developing, increasingly active and newly rising interdiscipline which is the new expansion of supramolecular chemistry in pharmaceutical sciences, and is gradually becoming a relatively independent scientific area. Supramolecular drugs could be defined as medicinal supermolecules formed by two or more molecules through non-covalent bonds. So far a lot of supermolecules as chemical drugs have been widely used in clinics. Supermolecules as chemical drugs, i.e. supramolecular chemical drugs or supramolecular drugs, which might have the excellences of lower cost, shorter period, higher potential as clinical drugs for their successful research and development, may possess higher bioavailability, better biocompatibility and drug-targeting, fewer multidrug-resistances, lower toxicity, less adverse effect, and better curative effects as well as safety, and therefore exhibit wide potential application. These overwhelming advantages have drawn enormous special attention. This paper gives the definition of supramolecular drugs, proposes the concept of supramolecular chemical drugs, and systematically reviews the recent advances in the research and development of supermolecules, including organic and inorganic complex ones as chemical drugs in the area of antitumor, anti-inflammatory, analgesic, antimalarial, antibacterial, antifungal, antivirus, anti-epileptic, cardiovascular agents and magnetic resonance imaging agents and so on. The perspectives of the foreseeable future and potential application of supramolecules as chemical drugs are also presented. Supported by the Southwest University (Grant Nos. SWUB2006018 & XSGX0602), the Natural Science Foundation of Chongqing (Grant Nos. 2007BB5369 & 2006BB4341) and the Key Project from the Personnel Department of China (Grant No. 2002-99)     

The Halogen Bond: An Emerging Supramolecular Tool in the Design of Functional Mesomorphic Materials

Owing to their dynamic attributes, non-covalent supramolecular interactions have enabled a new paradigm in the design and fabrication of multifunctional material systems with programmable properties, performances, and reconfigurable traits. Recently, the “halogen bond” has become an enticing supramolecular synthetic tool that displays a plethora of promising and advantageous characteristics. Consequently, this versatile and dynamic non-covalent interaction has been extensively harnessed in various fields such as crystal engineering, self-assembly, materials science, polymer chemistry, biochemistry, medicinal chemistry and nanotechnology. In recent years, halogen bonding has emerged as a tunable supramolecular synthetic tool in the design of functional liquid-crystalline materials with adjustable phases and properties. In this Concept article, the use of halogen bond in the field of stimuli-responsive smart soft materials, that is, liquid crystals is discussed. The design, synthesis and characterization of molecular and macromolecular liquid crystalline materials are described and the modulation of their properties has been emphasized. The power of halogen bonding in offering a large variety of functional liquid crystalline materials from readily accessible mesomorphic and non-mesomorphic complementary building blocks is highlighted. The article concludes with a perspective on the challenges and opportunities in this emerging endeavor towards the realization of enabling and elegant dynamic functional materials.     

Halogen bonding and chalcogen bonding mediated sensing

Sigma–hole interactions, in particular halogen bonding (XB) and chalcogen bonding (ChB), have become indispensable tools in supramolecular chemistry, with wide-ranging applications in crystal engineering, catalysis and materials chemistry as well as anion recognition, transport and sensing. The latter has very rapidly developed in recent years and is becoming a mature research area in its own right. This can be attributed to the numerous advantages sigma–hole interactions imbue in sensor design, in particular high degrees of selectivity, sensitivity and the capability for sensing in aqueous media. Herein, we provide the first detailed overview of all developments in the field of XB and ChB mediated sensing, in particular the detection of anions but also neutral (gaseous) Lewis bases. This includes a wide range of optical colorimetric and luminescent sensors as well as an array of electrochemical sensors, most notably redox-active host systems. In addition, we discuss a range of other sensor designs, including capacitive sensors and chemiresistors, and provide a detailed overview and outlook for future fundamental developments in the field. Importantly the sensing concepts and methodologies described herein for the XB and ChB mediated sensing of anions, are generically applicable for the development of supramolecular receptors and sensors in general, including those for cations and neutral molecules employing a wide array of non-covalent interactions. As such we believe this review to be a useful guide to both the supramolecular and general chemistry community with interests in the fields of host–guest recognition and small molecule sensing. Moreover, we also highlight the need for a broader integration of supramolecular chemistry, analytical chemistry, synthetic chemistry and materials science in the development of the next generation of potent sensors.

Sigma–hole mediated detection of anions is rapidly emerging as a new paradigm in supramolecular sensor chemistry. Herein, we provide an overview of this field including halogen bonding and chalcogen bonding optical, electrochemical and other sensors.     

具有生理活性的甾体酰胺类化合物

在甾体的甾核或支链上引入不同的官能团后可得到不同生理活性的化合物,它们有可能会成为人类治疗不同疾病的药物,因此甾体药物除了作为传统激素类药物使用外,在抗肿瘤药物、抗炎药物中的应用也成为甾体的重要研究内容之一。含有酰胺官能团的甾体化合物具有很好的生物活性。本文按照酰胺基团在甾体酰胺化合物中的位置进行分类,同时结合本课题组在甾体酰胺化合物的合成和生理活性研究方面所取得的一些成果,概述了近几年来新合成及发现的甾体酰胺类化合物及其衍生物的生理活性及研究进展,包括作为抗肿瘤药物的甾体酰胺化合物的设计、筛选、对5α-还原酶的抑制作用、抑制肿瘤细胞生长增殖活性及抗菌作用,并对此方面的发展趋势、应用前景作了展望。     

Shape‐Persistent Organic Cage Compounds by Dynamic Covalent Bond Formation

One area of supramolecular chemistry involves the synthesis of discrete three‐dimensional molecules or supramolecular aggregates through the coordination of metals. This field also concerns the chemistry of supramolecular cage compounds constructed through the use of such coordination bonds. To date, there exists a broad variety of supramolecular cage compounds; however, analogous organic cage compounds formed with only covalent bonds are relatively rare. Recent progress in this field can be attributed to important advances, not least the application of dynamic covalent chemistry. This concept makes it possible to start from readily available precursors, and in general allows the synthesis of cage compounds in fewer steps and usually higher yields.