二聚炔雌醇分子钳对氯基酸甲酯手性识别的理论研究

采用分子模拟研究了二聚炔雌醇分子钳（1～3）与D-和L-苯丙氨酸甲酯的相互作用,比较了形成配合物前后分子钳的结构变化以及与手性苯丙氨基酸甲酯相互作用能大小,其计算结果与实验结果一致。理论研究表明主客体分子间存在着的空间匹配、Van der Waals作用力和静电作用是分子识别的推动力,这为认识和预测分子钳的手性识别能力提供了理论依据。     

脱氧胆酸类分子钳对氨基酸甲酯的手性识别

紫外光谱法;脱氧胆酸类分子钳对氨基酸甲酯的手性识别     

锌卟啉对氨基酸甲酯手性分子识别的理论研究

用Tripos力场和分子力学方法研究了手笥锌卟啉的最低能量构象,并用分子动力学模拟了锌卟啉对氨基酸甲酯的识别过程,发现锌卟啉与D-氨基酸酯结合能力强于L-氨基酸,这与热力学实验结果一致.     

氨基甲酸酯型脱氧胆酸分子钳对氨基酸甲酯的手性识别 研究

以脱氧胆酸为spacer,通过三光气桥连各种芳胺,合成了新的氨基甲酸酯型分子钳受体1～4,这些化合物的结构经IR,^1HNMR和元素分析所证实。利用差光谱滴定法考察了其与D/L氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1～4对所考察的氨基酸甲酯均具有识别能力,其对D-氨基酸甲酯的识别优于对L-氨基酸甲酯的识别。从主客体间的大小形状匹配及几何互补关系等方面对这些受体的识别能力及对映选择性进行了讨论。     

酯键型鹅去氧胆酸分子钳对氨基酸甲酯的手性识别

利用紫外可见光谱差光谱滴定法考察了新型鹅去氧胆酸分子钳1～6对D／L氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1～6对所考察的氨基酸甲酯均具有识别能力,其对D-氨基酸甲酯的识别优于对L-氨基酸甲酯的识别。受体与底物间的大小、形状匹配,微环境效应等对识别性能均有重要影响。识别作用的主要推动力来自受体与底物之间的互补氢键,受体与底物芳环之间的π-π堆叠作用等非共价键作用力的协同作用。     

手性芳酰胺类分子钳对氨基酸衍生物的对映选择性识别

在微波辐射条件下,以联苯二甲酸为间隔基,L-氨基酸甲酯为手臂,合成了3个新型芳酰胺手性分子钳。这些化合物的结构经1HNMR,IR,MS和元素分析确证。利用差紫外光谱滴定法考察了其与D/L氨基酸甲酯的对映选择性识别性能。结果表明,分子钳2a~2c对所考察的氨基酸甲酯均具有识别能力,其对D-氨基酸甲酯的识别优于对L-氨基酸甲酯的识别。从主客体间的大小形状匹配及几何互补关系等方面对这些受体的识别能力及对映选择性进行了讨论。     

联苯二甲酸类手性分子钳的微波合成

在微波辐射条件下, 以联苯二甲酸为间隔基, L-氨基酸甲酯为手臂, 合成了7个新型手性分子钳. 其结构经¹H NMR, IR, MS和元素分析所证实. 与常规加热的一般合成方法相比, 该法明显地提高了反应速度和产率. 初步的实验结果表明, 这类分子钳人工受体对D/L-氨基酸甲酯具有良好的对映选择性识别性能.     

Salen Zn对氨基酸甲酯体系的手性分子识别研究

用光谱滴定法测定了手性SalenZn与D-和L-氨基酸甲酸客体在CHCl3中的分子识别反应的缔合常数,其大小顺序为K(LeuOMe)>K(ValOMe)>K(AlaOMe);K(ThrOMe)>K(SerOMe)>K(TyrOMe);且X(D型)>K(L型).根据van'tHoff方程确定了反应体系的热力学函数,并对体系的熵-焓补偿关系和对映体选择性进行了讨论.用分子力学和量子化学方法,对体系 的识别行为进行了计算研究,从理论上对实验现象及识别过程的规律性给予了合理解释.     

邻苯二甲酰亚胺酰胺类手性分子钳的合成及其光学性能

邻苯二甲酸酐分别与甘氨酸和丙氨酸反应,得到两个邻苯二甲酰氨基酸(2a和2b);2经过酰氯化后再与邻苯二胺偶联,合成了两个钳形分子(1a和1b),其结构经1H NMR, 13C NMR, IR和元素分析表征.利用紫外和荧光光谱研究了1的光学性能.     

胆甾类分子钳对氨基酸衍生物的对映选择性识别

用差紫外光谱滴定法考察了以脱氧胆酸作spacer的手性分子钳1～3对一系列α-氨基酸甲酯的对映选择性识别性能。结果表明,分子钳1和2与客体氨基酸甲酯形成1:1型超分子配合物,并显示较好的手性识别能力。分钳3对所考察的氨基酸甲酯均没有明显的识别作用。讨论了主-客体间尺寸/形状匹配、几何互补等因素对形成超分子配合物的影响,并利用计算机模拟作辅助手段对实验结果和现象进行了解释。     

Design and synthesis of chiral single-armed molecular tweezers derived fromα-hyodeoxycholic acid

A novel type of molecular tweezers with different chiral center and cleft has been designed and prepared by usingα-hyodeoxycholic acid as spacer and D/L-amino acid methyl ester as chiral arm attached at 3-position.Their structures were elucidated by ~1H NMR,FTIR and elemental analysis.Their recognition properties for various D/L-amino acid methyl esters were also investigated.The preliminary results indicated that these chiral single-armed molecular tweezers exhibited good recognition ability for D/L-ami...     

Optical resolution of racemic amino acid derivatives with molecularly imprinted membranes bearing oligopeptide tweezers

Molecularly imprinted polymeric membranes were prepared from various oligopeptide tweezers by the adoption of N‐α‐tert‐butoxycarbonyl‐D ‐tryptophan (Boc‐D ‐Trp) or N‐α‐tert‐butoxycarbonyl‐L ‐tryptophan (Boc‐L ‐Trp) as a print molecule. The chiral recognition ability of the formed molecular recognition sites was dependent on the absolute configuration of the print molecule adopted in the membrane preparation (molecular imprinting) process, whereas the candidate oligopeptide tweezers consisted of the L ‐amino acid residues. In other words, the membranes imprinted by the D ‐isomer recognized the D ‐isomer in preference to the corresponding L ‐isomer, and vice versa. The affinity constant between the target molecule and the chiral recognition site from the oligopeptide tweezers was higher than that from a single‐strand oligopeptide derivative. Those membranes selectively transported the enantiomer, which was preferentially incorporated into the membrane by dialysis. The permselectivities for these membranes exceeded their adsorption selectivities. © 2004 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 385–396, 2005     

脱氧胆酸手性分子钳的微波合成及其对中性分子的识别性能研究

在微波辐射条件下,以脱氧胆酸甲酯为间隔基,高产率合成了5个脱氧胆酸手性分子钳人工受体,其结构经IR,1HNMR,MS及元素分析确证。用差紫外光谱法测定了其对中性分子的识别性能。实验结果表明,这类分子钳人工受体对所考察的客体分子有良好的识别作用,主客体间形成1∶1型主客体配合物,受体5d对苯胺的结合常数高达14171.39 M-1。     

Investigation of chiral recognition by molecular micelles with molecular dynamics simulations

Molecular dynamics simulations were used to characterize the binding of the chiral drugs chlorthalidone and lorazepam to the molecular micelle poly-(sodium undecyl-(L)-leucine-valine). The project’s goal was to characterize the nature of chiral recognition in capillary electrophoresis separations that use molecular micelles as the chiral selector. The shapes and charge distributions of the chiral molecules investigated, their orientations within the molecular micelle chiral binding pockets, and the formation of stereoselective intermolecular hydrogen bonds with the molecular micelle were all found to play key roles in determining where and how lorazepam and chlorthalidone enantiomers interacted with the molecular micelle.     

Using molecular dynamics simulations to identify the key factors responsible for chiral recognition by an amino acid-based molecular micelle

Molecular dynamics (MD) simulations were used to investigate the binding of six chiral compounds to the amino acid-based molecular micelle (MM) poly-(sodium undecyl-(L)-leucine-leucine) or poly(SULL). The MM investigated is used as a chiral selector in capillary electrophoresis. The project goal was to characterize the chiral recognition mechanism in these separations and to move toward predictive models to identify the best amino acid-based MM for a given separation. Poly(SULL) was found to contain six binding sites into which chiral compounds could insert. Four sites had similar sizes, shapes, and electrostatic properties. Enantiomers of alprenolol, propranolol, 1,1′-bi-2-naphthyl-2,2′-diyl hydrogen phosphate, 1,1′-bi-2-naphthol, chlorthalidone, or lorazepam were separately docked into each binding pocket and MD simulations with the resulting intermolecular complexes were performed. Solvent-accessible surface area calculations showed the compounds preferentially associated with binding sites where they penetrated into the MM core and shielded their non-polar atoms from solvent. Furthermore, with five of the six compounds the enantiomer with the most favorable free energy of MM association also experienced the most favorable intermolecular hydrogen bonding interactions with the MM. This result suggests that stereoselective intermolecular hydrogen bonds play an important role in chiral discrimination in separations using amino acid-based MMs.GRAPHICAL ABSTRACT     

Towards the design of neutral molecular tweezers for anion recognition

Molecular tweezers are simple molecular receptors that can be characterized by the presence of two flat pincers separated by a more or less rigid tether. They have the ability to form complexes with a substrate molecule by gripping the substrate between the tips of the tweezers in a similar manner to that of mechanical tweezers. Kl?rner et al. synthesized one of the structurally simplest molecular tweezers, which is reported to bind electrodeficient aromatic and aliphatic substrates as well as organic cations. Complexes between these molecular tweezers and electron-rich aromatic, aliphatic, or anionic substrates have not been observed. Inspired by several recent reports that describe the interaction of hexafluorobenzene with electron-rich sites of molecules, we conducted a theoretical study to show the possibility of building molecular tweezers, based on those synthesized by Kl?rner, which were able to bind to anions and thus increase their potential as molecular receptors. We characterized complexes formed between several fluorinated derivatives of simple tweezers and an iodine anion, and analyzed the nature of the intermolecular interactions as well as the energetics for the process of complexation. The stabilization trend reflected by the energetic results when fluorine substituents were added to benzene rings confirms our hypothesis about the possibility of obtaining neutral tweezers composed of aromatic rings that can bind anions.     

胆甾类人工受体的分子识别研究进展

人工受体分子识别研究是生物有机化学的前沿领域之一。综述了近年来以胆甾 为构筑单元建造的人工受体在分子识别方面的研究进展。