Efficient Regioselective Synthesis of Mono-2-O-Sulfonyl-cyclodextrins by the Combination of Sulfonyl Imidazole and Molecular Sieves

Abstract

Cyclodextrins are cyclic oligosaccharides consisting of six or more α-1,4-linked D-glucopyranose units, which possess primary hydroxyl groups at the C-6 positions and secondary hydroxyl groups at the C-2 and C-3 positions. Because cyclodextrins have a hydrophobic and optically active interior, they have been utilized as transporters of hydrophobic molecules and small molecular mimics of enzymes. The chemical modification of cyclodextrins has been investigated in order to improve these characteristics. Sulfonations of the primary or secondary hydroxyl groups of cyclodextrin have been applied for further functionalization of cyclodextrin, and several methods for regioselective sulfonations have been developed. Among these strategies, selective monotosylation of the C-6 hydroxyl group is done relatively easily by reaction of α or β-cyclodextrin and p-toluenesulfonyl chloride in pyridine^1,2 or in alkaline aqueous solution.^3,4 However, sulfonation of the secondary hydroxyl groups is more difficult and new sulfonation methods must be developed to provide precursors for cyclodextrin analogues such as amino and sulfide analogues. Several strategies for the sulfonation of one C-2 hydroxyl group have been reported. However, because reaction conditions can require specific sulfonation reagent,⁵ alkaline condition,^3-7 strict anhydrous conditions,^8,9 or use of protected C-6 hydroxyl groups,^10,11 the methodology is not convenient to employ.     

Chemical clockwise tridifferentiation of alpha- and beta-cyclodextrins: bascule-bridge or deoxy-sugars strategies

The selective and efficient functionalisation of large concave molecules is a chemical challenge opening the door to various applications, such as artificial enzymes. We propose here a method, based on deprotection of benzylated cyclodextrins, to selectively access a variety of complex structures with two or three new different functionalities on the primary platform. Our strategy is based on a mechanistic hypothesis involving the approach of an aluminium reagent between the primary oxygen atom and the endocyclic one of the same sugar unit. Due to its cyclic directionality, a change in steric hindrance on a given position of the cyclodextrin has a different effect on the clockwise or the counterclockwise directions. This concept is illustrated and exploited in two complementary ways: deoxygenation of the primary position of two diametrically opposed sugars induces a debenzylation reaction on the neighbouring clockwise sugars of alpha- and beta-cyclodextrins. Reversible capping, or bascule-bridging, of the same pair of sugars has the same effect on the debenzylation of alpha-cyclodextrin, but induces an important change of the geometry of beta-cyclodextrin, hence allowing the selective access to yet another functionalisation pattern. A combined use of deoxygenation and bascule-bridging allows the access to an alpha-cyclodextrin with its three pairs of primary functions differentiated and ready for further modifications. Bascule-bridge or deoxy-sugars are two complementary means to operate steric decompression and induce selective reactions to efficiently access a number of new patterns of functionalities on concave molecules.     

Full Functionalization of the Imidazole Scaffold by Selective Metalation and Sulfoxide/Magnesium Exchange

A simple, flexible, and straightforward method for the functionalization of all the positions of the imidazole heterocycle through regioselective arylations, allylations, acylations, and additions to aldehydes is disclosed. Starting from the readily available key imidazole 1 , highly functionalized imidazole derivatives have been synthesized in a regioselective manner from directed metalations and a sulfoxide/magnesium exchange. Moreover, the selective N3‐alkylation followed by deprotection of N1 (trans‐N‐alkylation) allows the regioselective N‐alkylation of complex imidazoles.     

Derivatized cyclodextrins for the separation of enantiomers in capillary electrophoresis

The use of cyclodextrin derivatives for the efficient separation of enantiomeric drugs is described. Hydroxypropylation, methylation or carboxymethylation of the cyclodextrin not only result in a better solubility of the cyclodextrin in aqueous solutions, but also favor, via additional hydrogen bonding, the stabilization of one of the cyclodextrin-analyte complexes. The influence of the background electrolyte on peak shape is also described here. Carboxymethylated cyclodextrin can be used in similar manner to uncharged cyclodextrins at low pH values (below 4). At pH values above 5, however, its charge also allows the separation of uncharged enantiomers as in a micellar-like system.     

Cyclodextrins as Building Blocks for Supramolecular Structures and Functional Units

Cyclodextrins are frequently used as building blocks, because they can be linked both covalently and noncovalently with specificity. Thus one, two, three, seven, fourteen, eighteen, or twenty substituents have been linked to one β-cyclodextrin molecule in a regioselective manner. Furthermore, Cyclodextrins may serve as organic host molecules. Their internal cavity is able to accommodate one or two guest molecules. Conversely, suitable guest molecules can be used to thread one, two, or many (one hundred or more) cyclodextrin rings. The resulting supramolecular structures are often formed in solution, which allows characterization by high-resolution spectroscopic methods. Chemical conversion of these structures provides molecular architectures such as catenanes, rotaxanes, polyrotaxanes, and tubes, which are not readily prepared by other methods. The particular properties of Cyclodextrins can also be employed, for example, for the chromatographic separation of complex mixtures of substances, even racemates, by molecular recognition. Cyclodextrins and their derivatives have been found to be remarkably active catalysts as well. Finally, since Cyclodextrins can favorably influence the release of drugs, many new applications will certainly be developed in the near future.     

1,2‐Thiazines: One‐Pot Syntheses Utilizing Mono and Diaza Analogs of Sulfones

A one‐pot Michael addition/cyclization/condensation reaction sequence for the regioselective synthesis of 1,2‐thiazines, starting from propargyl ketones and NH‐sulfoximines or NH‐sulfondiimines, has been developed. Under mild and operationally simple reaction conditions previously unprecedented 1,2‐thiazine 1‐imide and 1‐oxide derivatives are formed in good to excellent yields. The products represent heterocyclic building blocks, readily modifiable by a regioselective C?H bond functionalization, classical cross‐coupling reactions, and deprotection.     

Novel stationary phases for high-performance liquid chromatography analysis of cyclodextrin derivatives

Novel stationary phases were prepared for separation of cyclodextrins and cyclodextrin derivatives by bonding substituted aromatic groups (phenyl and naphthyl) to the silica gel matrix. Both the electron-withdrawing (nitro) and the hydrogen-donor/acceptor (amide or carbamide) substituents of the phenyl group play essential role in the separation of cyclodextrins and cyclodextrin derivatives. On the basis of the comparison of experimental data obtained on different columns the N-(4-nitrophenyl)-carbamide group bonded silica gel stationary phase was selected as the most effective one for analysis of cyclodextrin derivatives. Improved separation potency was observed for hydroxypropylated, methylated and several other cyclodextrin derivatives compared with the previously and presently used stationary phases. Owing to the strong retention of cyclodextrins and its derivatives on the selected column, detection of their decomposition products was easily achieved. Determination of unsubstituted, natural cyclodextrin as an impurity in the cyclodextrin derivatives was implemented. Identification and characterization of cyclodextrin derivatives in industrial products could also be performed.     

The complexation efficiency

Studies have shown that cyclodextrins form both inclusion and non-inclusion complexes and that several different types of complexes can coexist in aqueous solutions. In addition, both cyclodextrins and cyclodextrin complexes are known to form aggregates and it is thought that these aggregates are able to solubilize drugs through micellar-type mechanism. Thus, stability constants determined from phase-solubility profiles are rarely true stability constants for of some specific drug/cyclodextrin complexes. A more precise method for evaluation of the solubilizing effects of cyclodextrins is to determine their complexation efficiency (CE). CE can be determined by measuring the solubility of a given drug at 2–3 cyclodextrin concentrations in pure water or a medium constituting the pharmaceutical formulation such as parenteral solution or aqueous eye drop formulation. Based on the CE value the drug:cyclodextrin ratio in the complexation medium can be determined as well as the increase in the formulation bulk in a solid dosage form. Determination of CE is a simple method for quick evaluating the solubilizing effects of different cyclodextrins and/or the effects of excipients on the solubilization. Here we report the CE of 43 different drugs with mainly 2-hydroxypropyl-β-cyclodextrin but also with randomly methylated β-cyclodextrin as well as few other cyclodextrins. Calculation of CE, drug:cyclodextrin molar ratio and the increase in the formulation bulk is discussed, as well as the influence of the intrinsic solubility and drug lipophilicity on the CE.     

基于环糊精的高度支化聚合物*

环糊精（CD）与高度支化聚合物都存在空腔结构,若将两者结合起来可构筑出含有两种不同疏水空腔且具有特异物理化学功能的高分子体系,并有望在分子包合与识别、药物控释、基因传输等领域得到新的应用。本文根据高度支化聚合物与环糊精结合方式的不同,从以环糊精为核的高度支化聚合物、外端悬挂环糊精的高度支化聚合物、高度支化聚合物的结构单元与环糊精包合、环糊精与客体分子包合后自组装成高度支化聚合物,以及用功能化的环糊精单体合成超支化聚合物等5个方面对其研究进展进行了总结和评述,并在此基础上展望了该类聚合物的研究方向和发展趋势。     

Cyclodextrins and the liquid-liquid phase distribution of progesterone, estrone and prednicarbate

The purpose of the present work was to investigate the interaction of drugs and octanol with hydroxypropyl β- (HPβCD) and γ- (HPγCD) cyclodextrin, sulfobutyl ether β-cyclodextrin (SBEβCD) and randomly methylated-β-cycoldextrin (RMβCD) and to describe the interaction by theoretical models. The poorly soluble steroid drugs progesterone, estrone and prednicarbate were used as model compounds in this study. Hexane and chloroform were also investigated in combination with HPβCD. Octanol formed a complex with all cyclodextrins and the saturation of the aqueous solution with this solvent therefore had a significant effect on the solubilization and extraction potential of cyclodextrins. Hexane had less affinity for cyclodextrins, but the drugs were poorly soluble in this solvent and it could therefore not be used in phase-distribution investigations. Previously we have derived equations that can be used to account for the competitive interaction between two guest compounds that compete for space in the cyclodextrin cavity. These equations were rearranged to calculate the complexation efficacy from phase-solubility data. An equation was derived that obtains intrinsic solubility (S ₀) and intrinsic partition coefficient (P) from the slopes of the phase-solubility and phase-distribution profiles. Investigation of the data showed that the results could not be sufficiently explained by the “classical” drug/cyclodextrin complex model that recognizes the possibility of competitive interactions but ignores any contribution from higher order complexes or aggregation of the cyclodextrin complexes. Relative difference in solubilization potential of different cyclodextrins cannot be translated to relative differences in extraction efficacy. Thus, for these three steroid compounds, RMβCD and SBEβCD gave the best solubilization potential whereas the best extraction efficacy was observed with HPγCD.     

Cyclodextrin Molecular Reactors

The ability of cyclodextrins to form inclusion complexes with hydrophobic species in aqueous solution makes them well-suited to the development of molecular reactors, to be used as miniature reaction vessels in order to control the outcomes of chemical transformations at the molecular level. In this manner, reaction rates can be increased and products may be obtained that are different to those normally accessible from reactions in free solution. Examples used to illustrate these effects include: the application of cyclodextrins to control the regioselectivity of bromination of aromatic substrates with pyridinium dichlorobromate: the use of a metallocyclodextrin to increase the rate of hydrolysis of a phosphate triester by almost five orders of magnitude; the development of modified cyclodextrins to increase the rates and reverse the regioselectivity of nitrile oxide cycloadditions ; and the use of a cyclodextrin dimer to change the ratio of formation of indigoid dyes by a factor of more than 3500.     

μ-Waves avoid large excesses of diisobutylaluminium-hydride (DIBAL-H) in the debenzylation of perbenzylated α-cyclodextrin

Regioselective double deprotection of cyclodextrins using diisobutylaluminium-hydride (DIBAL-H) has become an important tool in functional cyclodextrin synthesis. When conventionally heated a very large excess of reagent is necessary for the reaction to happen, when μ-waves irradiation is employed the quantity of DIBAL-H can be lowered down to 5 equiv. Reaction with a smaller quantity of DIBAL-H never achieved complete double debenzylation. These results also sustain the mechanistic hypothesis according to which a minimum of two aluminium atoms are necessary for each debenzylation to occur.     

Enantiomeric separations of drugs using mixtures of charged and neutral cyclodextrins

An overview on the use of mixtures of neutral and charged cyclodextrins as chiral additives for the enantioseparation of drugs by capillary electrophoresis is presented. These so called dual cyclodextrin systems can often provide unique selectivities. A brief theoretical background illustrating the influence of the chiral discrimination ability and the effective mobility of the two cyclodextrins on the overall selectivity of the enantiomeric separation is given. Typical examples of applications in the pharmaceutical field, based on the simultaneous use of a charged (cationic or anionic) and neutral cyclodextrins, are described.     

An Immobilized‐Dirhodium Hollow‐Fiber Flow Reactor for Scalable and Sustainable C−H Functionalization in Continuous Flow

A scalable flow reactor is demonstrated for enantioselective and regioselective rhodium carbene reactions (cyclopropanation and C?H functionalization) by developing cascade reaction methods employing a microfluidic flow reactor system containing immobilized dirhodium catalysts in conjunction with the flow synthesis of diazo compounds. This allows the utilization of the energetic diazo compounds in a safe manner and the recycling of the dirhodium catalysts multiple times. This approach is amenable to application in a bulk‐scale synthesis employing asymmetric C?H functionalization by stacking multiple fibers in one reactor module. The products from this sequential flow–flow reactor are compared with a conventional batch reactor or flow–batch reactor in terms of yield, regioselectivity, and enantioselectivity.     

A comparison of phosphated and sulfated beta-cyclodextrins as chiral selectors for capillary electrophoresis

The enantioseparation capabilities of three different functionalized beta-cyclodextrins, two sulfated beta-cyclodextrins with 4 and 15 nominal degrees of substitution and a phosphated beta-cyclodextrin with 8 degrees of substitution, were compared. While anodic detection was used with both sulfated cyclodextrins, the phosphated cyclodextrin required cathodic detection suggesting either lower ionization of the phosphated cyclodextrin or generally lower affinity of the analytes for the phosphated cyclodextrin. The effects of several experimental parameters were evaluated with respect to enantioseparation. The degrees of substitution of the cyclodextrin, pH of the background electrolyte as well as the concentration of the functionalized beta-cyclodextrin, each had a significant influence on the successful enantiomeric separation of the chiral drugs investigated.     

A comparison of phosphated and sulfated β-cyclodextrins as chiral selectors for capillary electrophoresis

The enantioseparation capabilities of three different functionalized β-cyclodextrins, two sulfated β-cyclodextrins with 4 and 15 nominal degrees of substitution and a phosphated β-cyclodextrin with 8 degrees of substitution, were compared. While anodic detection was used with both sulfated cyclodextrins, the phosphated cyclodextrin required cathodic detection suggesting either lower ionization of the phosphated cyclodextrin or generally lower affinity of the analytes for the phosphated cyclodextrin. The effects of several experimental parameters were evaluated with respect to enantioseparation. The degrees of substitution of the cyclodextrin, pH of the background electrolyte as well as the concentration of the functionalized β-cyclodextrin, each had a significant influence on the successful enantiomeric separation of the chiral drugs investigated.     

Crystal Structures of β‐Cyclodextrin Inclusion Complexes with 7‐Hydroxycoumarin and 4‐Hydroxycoumarin and Substituent Effects on Inclusion Geometry

Two inclusion complexes of β‐cyclodextrin‐7‐hydroxycoumarin ( 1 ) and β‐cyclodextrin‐4‐hydroxycoumarin ( 2 ) were prepared and their crystal structures were investigated by single crystal X‐ray crystallography under cryogenic condition. Both structures consist of stacks of face‐to‐face cyclodextrin dimers arranged in brickwork‐like pattern along the crystallographic a‐axis. For complex 1 , each of the two dimeric β‐cyclodextrins includes one 7‐hydroxycoumarin molecule that penetrates deeply into the cyclodextrin dimer and locates its lactonering at the center of the dimer cavity. For complex 2 , each cyclodextrin dimer accommodates three 4‐hydroxycoumarin molecules. One of them is sandwiched between two units of the cyclodextrin dimer, the other two are shallowly included in the cavities of the dimeric cyclodextrins respectively and protrude their lactone rings from the primary end of the cyclodextrin. The substituent effects of guest molecules on inclusion geometry of various coumarin molecules in β‐cyclodextrin were examined.     

基于环糊精的新材料的研究进展

从纳米粒子、水凝胶、纤维材料和环糊精高分子等方面介绍了近年来以环糊精为基础研制的新材料的研究进展。目前以环糊精为基础的纳米粒子材料有核壳结构的纳米粒子、环糊精的化学接枝与共聚、环糊精与无机非金属材料的复合和含环糊精的囊泡材料;以环糊精为基础的凝胶材料有水凝胶和有机凝胶两种材料;此外还有以环糊精为基础的纤维材料、环糊精高...     

Unusual Cyclodextrin Derivatives as a New Avenue to Modulate Self‐ and Metal‐Induced Aβ Aggregation

Mounting evidence suggests an important role of cyclodextrins in providing protection in neurodegenerative disorders. Metal dyshomeostasis is reported to be a pathogenic factor in neurodegeneration because it could be responsible for damage involving oxidative stress and protein aggregation. As such, metal ions represent an effective target. To improve the metal‐binding ability of cyclodextrin, we synthesized three new 8‐hydroxyquinoline‐cyclodextrin conjugates with difunctionalized cyclodextrins. In particular, the 3‐difunctionalized regioisomer represents the first example of cyclodextrin with two pendants at the secondary rim, resulting in a promising compound. The derivatives have significant antioxidant capacity and the powerful activity in inhibiting self‐induced amyloid‐β aggregation seems to be led by synergistic effects of both cyclodextrin and hydroxyquinoline. Moreover, the derivatives are also able to complex metal ions and to inhibit metal‐induced protein aggregation. Therefore, these compounds could have potential as therapeutic agents in diseases related to protein aggregation and metal dyshomeostasis.     

Chirality manipulation of supramolecular self-assembly based on the host-guest chemistry of cyclodextrin

Chiral materials have been of the interests of scientists for nearly a century. People have endeavored a great effort to manipulate the chirality of various self-assembled materials. Among these efforts, cyclodextrins are used only in recent years, although it has long been recognized that the chirality of cyclodextrin can be transferred to the guest. In this review, we for the first time summarize the recent advancement of the supramolecular chirality manipulation on the basis of the host-guest chemistry of cyclodextrins. By using the simple Harata-Kodaka's rule, natural cyclodextrins can be exploited in a dynamic manner to create chirality inversion materials through crystalline self-assembly, which is facile and environment-friendly. What is more, we also discussed the remarks on future outlooks at the end of this article and expect it to stimulate a rapid development on both the theory and application level.