Short synthesis of skeleton-modified cyclodextrin derivatives with unique inclusion ability

[reaction: see text] Skeleton-modified cyclodextrin (CD) derivatives, in which an alpha-(1,4)-glucosidic bond is converted into a beta-(1,4)-glucosidic bond, were conveniently synthesized by cleavage of a single glucosidic bond in permethylated and 2,6-di-O-methylated alpha- and beta-CDs and subsequent recyclization via the trichloroacetoimidate intermediates. The selective cleavage of an alpha-(1,4)-glucosidic bond of permethylated alpha- and beta-CDs was accomplished by stirring in 30% aq HClO(4) at 25 degrees C to give the corresponding maltohexaose and maltoheptaose derivatives, respectively. The cleavage of a glucosidic bond of hexakis(3-O-benzyl-2,6-di-O-methyl)-alpha-CD was successfully carried out in a mixed 60% aq HClO(4) and 1,4-dioxane solution (1:20). In the case of heptakis(3-O-benzyl-2,6-di-O-methyl)-beta-CD, the solvent-free reaction with p-toluenesulfonic acid was found to be effective for selective cleavage of one glucosidic bond. The permethylated beta-CD derivative with a beta-(1,4)-glucosidic bond (4b) exhibited higher inclusion ability toward sodium m-nitrobenzoate than the parent permethylated beta-CD, while these hosts showed the same inclusion ability toward sodium p-nitrobenzoate. On the other hand, the beta-(1,4)-type permethylated alpha-CD derivative 4a exhibited lower inclusion ability toward sodium p- and m-nitrobenzoates than the parent permethylated alpha-CD. Interestingly, host molecules 4a and 4b showed inclusion selectivity for sodium m-nitrobenzoate as compared with the corresponding para-isomer, in contrast to permethylated CDs which possessed para-isomer selectivity. On the other hand, host molecules 4a and 4b showed para-isomer selectivity toward sodium nitrophenoxide guests, indicating that the inclusion selectivity was remarkably influenced by the guest hydrophilic groups. (1)H NMR studies on complexes of those beta-(1,4)-type CD derivatives with p- and m-nitrobenzoates and p- and m-nitrophenolates were carried out to estimate their structures.     

A facile synthesis of novel cyclodextrin derivatives incorporating one beta-(1,4)-glucosidic bond and their unique inclusion ability

Novel cyclodextrin derivatives incorporating one (1,4)-glucosidic bond are easily synthesized in three steps from permethylated alpha- and beta-cyclodextrins, and such host molecules show inclusion selectivity for sodium m-nitrobenzoate over the corresponding p-isomer, in contrast to the cases of the parent permethylated alpha- and beta-cyclodextrins.     

Molecular Recognition and Cooperative Binding Ability of Fluorescent Dyes by Bridged Bisβ-cyclodextrin)s Tethered with Aromatic Diamine

A novel bridged bis(β-cyclodextrin),m-phenylenediimino-bridged bis(6-imino-6-deoxy-β-cyclodextrin) (2), was synthesized by the reaction of m-phenylenediamine and 6-deoxy-6-formyl-β-cyclodextrin. The inclusion complexation behavior of the novel bridged bis(β-cyclodextrin) 2,as well as native β-cyclodextrin (1),p-phenylenediamino-bridged bis(6-amino-6-deoxy-β-cyclodextrin) (3) and 4,4'-bianilino-bridged bis(6-amino-6-deoxy-β-cyclodextrin) (4) with representative fluorescent dye molecules, i.e., acridine red (AR), neutral red (NR), Rhodamine B (RhB), ammonium 8-anilino-1-naphthalenesulfonate (ANS) and sodium 6-toluidino-2-naphthalenesulfonate (TNS), was investigated at 25 °C in aqueous phosphate buffer solution (pH 7.20) by means of fluorescence, and circular dichroism, as well as 2D NMR spectrometry. The spectrofluorometric titrations have been performed to calculate the complex stability constants (K_S) and Gibbs free energy changes (Δ G°) for the stoichiometric 1 : 1 inclusion complexation of 1–4 with fluorescent dye molecules. The results obtained demonstrated that bis(β-cyclodextrin)s 2–4 showed much higher affinities toward these guest dyesthan native β-cyclodextrin 1. Typically, dimer 2 displayed the highest binding ability upon inclusion complexation with ANS, affording 35 times higher K_S value than native β-cyclodextrin. The significantlyenhanced binding abilities of these bis(β-cyclodextrin)s are discussed from thebinding mode and viewpoints of size/shape-fit concept and multiple recognition mechanism.     

Spectral modulation of a charge transfer reaction of 2-methoxy-4-(N,N-dimethylamino)benzaldehyde inside cyclodextrin nanocage

This article reports modulation of intramolecular charge transfer (ICT) reaction of 2-methoxy-4-(N,N-dimethylamino)benzaldehyde (2-MDMABA) encapsulated within the cyclodextrin nanocavities investigated by steady state and time resolved measurements. The ICT emission, absent in bulk water, originates in the presence of α-, β- and γ-CD with the huge enhancement of local emission. From the Benesi–Hildebrand plot, the stoichiometry of the host–guest inclusion complex is found to be 1:1 for β- and γ-CD whereas 1:1 and 1:2 guest to host complexation occur at low and high concentration of α-CD, respectively. The association constants of the inclusion complexes have also been estimated from the Benesi–Hildebrand plot. The greater binding capability of 2-MDMABA with β-CD than that of other two CDs is further supplemented by time resolved study.     

A kinetic and thermodynamic study of the α-cyclodextrin mediated reaction of a range of p-substituted phenyl methyl sulfides with binding and non-binding peroxyacids

This paper presents a thermodynamic study of the rate and equilibria processes involved in the α-cyclodextrin mediated reaction of a range of 4-substituted phenyl methyl sulfides with two peroxyacids of different binding affinities. The results for the inclusion processes show that the formation of 1:1 and 2:1 (host:guest) complexes between α-cyclodextrin and phenyl methyl sulfides are generally enthalpically controlled, particularly so for the 2:1 complexes, as might be expected for a ternary complex. The data from this series of sulfides is presented as enthalpy-entropy compensation plots, yielding slopes of unity for each inclusion process. The formation of a 1:1 complex between cyclodextrin and the strongly associating 3-chloroperbenzoic acid (MCPBA) is also enthapically controlled. The other peroxyacid used, peroxomonosulfate, does not bind to α-cyclodextrin to any measurable degree. As described in our original study of this reaction system (Davies and Deary in J Chem Soc Perkin Trans 2:2423–2430, 1996), catalysis by α-cyclodextrin is effected by activation of the peroxide as a result its inclusion within the cyclodextrin cavity; hence for reactions of phenyl methyl sulfides with MCPBA, catalysis is observed, but is absent for PMS. In this study the reaction rates are analysed using the transition state pseudo-equilibrium approach of Tee (Carbohydr Res 192:181–195, 1989), whereby the transition state pseudoequilibrium constant K _TS reflects the stabilisation imparted to the transition state by the association with one molecule of cyclodextrin. Enthalpy- entropy compensation plots for K _TS give slopes close to unity; this is the first reported example of such plots being applied to transition state pseudoequilibrium constants.     

Pharmacology and structures of the free base of the anaesthetic kazcaine and its complex with β-cyclodextrin

The base form of the local anaesthetic kazcaine (BFK, [1-(2-ethoxyethyl)-4-ethynyl-4-benzoyloxypiperidine, C₁₈H₂₃NO₃]) and β-cyclodextrin (β-CD) co-crystallized as BFK:β-CD inclusion complex in 1:2 M ratio from a mixture of water and ethanol while the filtered mother liquor yielded crystals of free BFK. X-ray diffraction showed that the crystals of BFK and its inclusion complex with β-CD belong to monoclinic (P2₁/c) and triclinic (P1) space groups, respectively. The crystals of free BFK are stabilized by pairs of C–H?O, C–H?π and ≡C–H?O type interactions and van der Waals contacts. In the 1:2 BFK:β-CD complex the two β-CD molecules are in hydrogen-bonding contact with their primary hydroxyl groups, the 1-(2-ethoxyethyl)-4-ethynyl-piperidine moiety being located in one and the benzoyloxy group of BFK in the other β-CD. This crystal structure is of the channel-type, the β-CD molecules of the 1:2 BFK:β-CD complex interacting with their secondary hydroxyl groups. The pharmacological activities of the 1:2 BFK/β-CD inclusion complex have been determined in mice, rats, porpoises and rabbits and compare favourably with those of kazcaine, procaine, dicaine, lidocaine and trimecaine. The methods used include terminal (superficial), infiltration, conduction anaesthesia, and acute toxicity.     

Inclusion complexes between cyclic siloxanes and cyclodextrins: synthesis and characterization

Molecular inclusion complexes between cyclodextrins and cyclic siloxanes were prepared and characterized via a combination of liquid and solid state NMR, FT-IR, TGA, powder X-ray diffraction, SEM–EDS and elemental analyses. The crystalline complexes adopted the channel-type conformation. Depending from the size of both the cyclic sugar cavity and the silicon guest, various yields (between 0 and 41%) and host–guest molar ratios (between 1:1 and 4:1) were obtained. α-cyclodextrin (α-CD) and β-cyclodextrin (β-CD) were observed to form crystalline inclusion complexes only with D₃ (cyclic dimethyltrisiloxane) due to steric effects, whereas the larger γ-cyclodextrin (γ-CD) formed inclusion complexes both with D₃, D₄ (cyclic dimethyltetrasiloxane) and D₅ (cyclic dimethylpentasiloxane). This study is believed to be the first step towards the selective removal of cyclic siloxanes impurities from commercial PDMS preparations.     

The geometry and vibrational frequencies of formyl cyanide,CHOCN

The structure of the recently prepared formyl cyanide molecule has been determined by ab initio calculations up to the level of split valence plus polarization with inclusion of electron correlation (6-31G¹MP3). The 6-31G¹MP3 geometry is: r_e(CN) = 1.160, r_e(C-C) = 1.476, r_e(CO) = 1.207, r_e(CH) = 1.098 Å, α_e(C-CN) = 178.32°, α_e(CCO) = 121.63°, and α_e(HCO) =     

Enantioseparation of 1-(p-bromophenyl)ethanol by crystallization of host–guest complexes with permethylated β-cyclodextrin: crystal structures and mechanisms of chiral recognition

It is shown that racemic 1-(p-bromophenyl)ethanol (p-Br-PE) can be quantitatively resolved by successive recrystallizations of (1:1) supramolecular complexes formed with permethylated β-cyclodextrin (TMβ-CD). The two enantiomerically pure complexes were characterized by physical methods and their crystal structures were determined. The comparison of both inclusion geometries and packing modes in these structures revealed distinct structural features allowing the enantioseparation of the guest to be understood. Chiral discrimination mechanisms are discussed in terms of the capability of TMβ-CD to induce the formation of stereospecific host–guest complexes by simple crystallization in aqueous medium.     

An NMR study of inclusion complexes formed by α-cyclodextrin and (R)- or (S)-α-lipoic acid

A ¹H NMR study that explored the ability of α-cyclodextrin (α-CD) to preferentially bind (R)-α-lipoic acid is presented. The interaction between α-CD and (R)-α-lipoic acid was found to be stronger than that between α-CD and (S)-α-lipoic acid. Structures for the (R)-α-lipoic acid/α-CD and (S)-α-lipoic acid/α-CD inclusion complexes were constructed using restraints derived from ROESY spectra and MM2 molecular mechanics calculations. The models built for both complexes have the 1,2-dithiolane ring and the carboxyl moiety of α-lipoic acid oriented toward the secondary and primary hydroxy sides of α-CD, respectively.     

Metal-organic frameworks from chiral square-pyramidal copper(II) complexes: Enantiospecific inclusion and perfectly polar alignment of guest and host molecules

The physical properties of [CuL¹₂(H₂O)] (1) and [CuL²₂(H₂O)] (2) and preparation and crystal structures of the inclusion compounds 1·(P)-C₂H₄Br₂, 2·(M)-C₂H₄Br₂, 1·CH₃CN and 2·CH₃CN are described. HL¹ and HL² (H represents the dissociable phenolic proton) are the N,O-donor chiral reduced Schiff bases N-(2-hydroxy-5-nitrobenzyl)-(R)-α-methyl-benzylamine and N-(2-hydroxy-5-nitrobenzyl)-(S)-α-methylbenzylamine, respectively. All the compounds crystallize in the non-centrosymmetric space group C2. In the crystal lattice, the host [CuLⁿ₂(H₂O)] (1 and 2) molecules connected by O−H?O and C−H?O interactions form perfectly polar two-dimensional networks. In these chiral and polar host frameworks, enantiospecific inclusion with polar ordering of the right-handed (P) and the left-handed (M) gauche form of 1,2-dibromoethane as well as polar alignment of acetonitrile molecules are observed. The host and guest molecules are linked by C−H?O interactions. The O-atoms of the nitro substituent on the ligands of 1 and 2 act as the acceptors in all these intermolecular O−H?O and C−H?O interactions. The structures reported in this work provide rare examples of enantiospecific trapping of the chiral rotamers of 1,2-dibromoethane as well as perfectly polar alignment of both guest and host molecules.     

Molecular Recognition of Bridged Bis （β－cyclodextrin） s Linked by Phenylenediseleno Tether on the Primary or Secondary Side with Fluorescent Dyes

A novel β‐cyclodextrin dimer, 2, 2′‐o‐phenylenediseleno‐bridged bis (β‐cyclodextrin) (2), has been synthesized by reaction of mono‐[2‐O‐(p‐tolylsulfonyl)]‐β‐cyclodextrin and poly(o‐phenylenediselenide). The complexation stability constants (K₂) and Gibbs free energy changes (‐ΔG°) of dimer 2 with four fluorescence dyes, that is, ammonium 8‐anilino‐1‐naphthalenesulfonate (ANS), sodium 6‐(p‐toluidino)‐2‐naphthalenesulfonate (TNS), Acridine Red (AR) and Rhodamine B (RhB) have been determined in aqueous phosphate buffer solution (pH = 7.2, 0.1 mol‐L^?1) at 25 °C by means of fluorescence spectroscopy. Using the present results and the previously reported corresponding data of β‐cyclodextrin (1) and 6, 6′‐o‐phenylenediseleno‐bridged bis (β‐cyclodextrin) (3), binding ability and molecular selectivity are compared, indicating that the bis (β‐cyclodextrin)s 2 and 3 possess much higher binding ability toward these dye molecules than parent β‐cyclodextrin 1, but the complex stability constant for 2 linked from the primary side is larger than that of 3 linked from the secondary side, which is attributed to the more effective cooperative binding of two hydrophobic cavities of host 3 and the size/shape‐fit relationship between host and guest. The binding constant (K₂,) upon inclusion complexation of host 3 and AR is enhanced by factor of 27.3 as compared with that of 1. The 2D ¹H NOESY spectrum of host 2 and RhB is performed to confirm the binding mode and explain the relative weak binding ability of 2.     

Inclusion complexes of cyclodextrins with 4-amino-1,8-naphthalimides (part 2)

Fluorescence spectroscopy was used to characterize inclusion compounds between 4-amino-1,8-naphthalimides (ANI) derivatives and different cyclodextrins (CDs). The ANI derivatives employed were N-(12-aminododecyl)-4-amino-1,8-naphthalimide (mono-C₁₂ANI) and N,N′-(1,12-dodecanediyl)bis-4-amino-1,8-naphthalimide (bis-C₁₂ANI). The CDs used here were α-CD, β-CD, γ-CD, HP-α-CD, HP-β-CD and HP-γ-CD. The presence of CDs resulted in pronounced blue-shifts in the emission spectra of the ANI derivatives, with increases in emission intensity. This behavior was parallel to that observed for the dyes in apolar solvents, indicating that inclusion complexes were formed between the ANI and the CDs. Mono-C₁₂ANI formed inclusion complexes of 1:1 stoichiometry with all the CDs studied. Complexes with the larger CDs (HP-β-CD, HP-γ-CD and γ-CD) were formed by inclusion of the chromophoric ANI ring system, whereas the smaller CDs (α-CD, HP-α-CD and β-CD) formed complexes with mono-C₁₂ANI by inclusion of the dodecyl chain. Bis-C₁₂ANI formed inclusion complexes of 1:2 stoichiometry with HP-β-CD, HP-γ-CD and γ-CD, but did not form inclusion complexes with α-CD, HP-α-CD and β-CD. The data were treated in the case of the large CDs using a Benesi-Hildebrand like equation, giving the following equilibrium constants: mono-C₁₂ANI:HP-β-CD (K ₁₁ = 50 M^?1), mono-C₁₂ANI:HP-γ-CD (K ₁₁ = 180 M^?1), bis-C₁₂ANI:HP-β-CD (K ₁₂ = 146 M^?2), bis-C₁₂ANI:HP-γ-CD (K ₁₂ = 280 M^?2).     

Electroepoxidation of natural and synthetic alkenes mediated by sodium bromide

Electroepoxidation of synthetic alkenes (styrene, trans-stilbene and trans-β-methylstyrene) and of some natural terpenes (limonene, terpinolene, geraniol, α-terpinene, γ-terpinene and α-terpineol) mediated by sodium bromide was performed in MeCN:H₂O (4:1) at platinum electrodes. The indirect electrochemical oxidation of the olefins led to the corresponding epoxides in yields ranging from 23% to 79%.     

Spectral study on the inclusion complex of cryptophane-E and CHCl3

Cryptophane-E was synthesized from vanillin by a three-step method, and its absorption and fluorescence spectroscopic properties were determined. Two absorption bands at about 245–260 and 280–290 nm were observed for cryptophane-E and the fluorescence emission maxima were at 320–330 nm depending on the solvent used. The interaction of cryptophane-E with CHCl₃ was studied in detail by absorption and fluorescence spectroscopies. The results showed that cryptophane-E and CHCl₃ can easily form a stable 1:1 host–guest inclusion complex. Their binding constant (K) was determined by Benesi–Hildebrand equation and the nonlinear least squares fit method. The binding constant is largest in ethyl acetate, followed by dioxane and with acetonitrile as the smallest. In addition, the effect of guest volume on the host–guest inclusion complex was investigated. Guest molecules including CH₂Cl₂ and CCl₄ were unable to form inclusion complex with cryptophane-E because of sizes mismatching with the host cavity.     

Host–guest complexation of omeprazole, pantoprazole and rabeprazole sodium salts with cyclodextrins: an NMR study on solution structures and enantiodiscrimination power

The application of different cyclodextrins (CDs) as NMR chiral solvating agents (CSAs) for the sodium salts of the proton-pump inhibitors omeprazole, pantoprazole (sesquihydrate) and rabeprazole was investigated. It was proved that the formation of diastereomeric host–guest complexes in D₂O solution between the CDs and those substrates permitted the direct ¹H NMR discrimination of the enantiomers of the sodium salts of these compounds without the need of previous working-up. Rotating frame nuclear overhauser effect spectroscopy (ROESY) was used to ascertain the solution geometries of the host–guest complexes. The results suggested a preferential binding of the benzimidazole moiety of the guest molecules within the macrocyclic cavity of α-CD, whereas the higher dimensions of β- and γ-CD also permitted the inclusion of the highly substituted pyridine moieties. Moreover, the solution stoichiometries and the binding constants of the complexes formed with pantoprazole at room temperature were determined by ¹H and ¹⁹F NMR titration. Diffusion-filtered Spectroscopy was applied to obtain clean spectra without the interference of the HOD signal.     

Amphiphilic Inclusion Spaces for Various Guests and Regulation of Fluorescence Intensity of 1,8‐Bis(4‐aminophenyl)anthracene Crystals

A host framework for inclusion of various guest molecules was investigated by preparation of inclusion crystals of 1,8‐bis(4‐aminophenyl)anthracene (1,8‐BAPA) with organic solvents. X‐ray crystallographic analysis revealed construction of the same inclusion space incorporating 1,8‐BAPA and eight guest molecules including both non‐polar (benzene) and polar guests (N,N‐dimethylformamide, DMF). Fluorescence efficiencies varied depending on guest molecule polarity; DMF inclusion crystals exhibited the highest fluorescence intensity (Φ_F=0.40), four times as high as that of a benzene inclusion crystal (Φ_F=0.10). According to systematic investigations of inclusion phenomena, strong host–guest interactions and filling of the inclusion space led to a high fluorescence intensity. Temperature‐dependent fluorescence spectral measurements revealed these factors effectively immobilised the host framework. Although hydrogen bonding commonly decreases fluorescence intensity, the present study demonstrated that such strong interactions provide excellent conditions for fluorescence enhancement. Thus, this remarkable behaviour has potential application toward sensing of highly polar molecules, such as biogenic compounds.     

α,ω-Bis(4-substituted-3-quinolinylthio)alkanes from reactions of thioquinanthrene with alkoxides

The reaction of thioquinanthrene 1 with sodium alkoxides and α,ω-dihaloalkanes leads to the formation of α,ω-bis[4-(4-methoxy-3-quinolinylthio)-3-quinolinylthio]alkanes 4 . The yield depends on the nature of α,ω-dihalo-alkanes. The effect of α,ω-dihaloalkanes of the following types: XCH₂X (X = Cl,Br,I), X(CH₂)₂X (X = Cl,Br,I), Br(CH₂)₃Br and Br(CH₂)₆Br were studied. The preparation of 4-alkoxy-3′-(ω-bromoalkylthio)-3,4′-diquinolinyl sulfide 3 and their transformation to α,ω-bis(4-alkoxy-3-quinolinylthio)alkanes 6 were studied as well.     

Synthesis and solution properties of sulfate-type hybrid surfactants with a benzene ring

Nine novel sulfate-type hybrid surfactants, C_mF_2m+1C₆H₄CH(OSO₃Na)C_nH_2n+1 (FmPHnOS: m=4, 6, 8; n=3, 5, 7; C₆H₄: p-phenylene), with a benzene ring in their molecules were synthesized. Alkanoyl chlorides were allowed to react with iodobenzene in the presence of aluminum chloride to give the corresponding aromatic ketones. The reaction of the ketones with perfluoroalkyl iodides yielded 1-[4-(perfluoroalkyl)phenyl]-1-alkanones as intermediates. The intermediates were allowed to react with methanol in tetrahydrofuran in the presence of sodium borohydride to yield 1-[4-(perfluoroalkyl)phenyl]-1-alkanols. The desired hybrid surfactants were obtained by the reaction of 1-[4-(perfluoroalkyl)phenyl-1-alkanols with sulfur trioxide/pyridine complex in pyridine and by the subsequent neutralization of the products with sodium hydroxide solution. When compared with the conventional hybrid surfactants, C_mF_2m+1C₆H₄COCH(SO₃Na)C_nH_2n+1 (FmHnS: m=4, 6; n=2, 4, 6; C₆H₄: p-phenylene), the new hybrid surfactants thus synthesized were found to have a comparable ability to lower the surface tension of water and a high hydrophilicity. The cmc of FmPHnOS obeyed Kleven’s rule and their occupied areas per molecule increased with increasing m and n with the values between 0.66 and 1.05 nm². The aggregation number for FmPHnOS micelles ranged from 6 to 45 and the hydrodynamic radius of the micelles was in the range of 1.4-3.1 nm.     

Chelating properties of permethylated 6A,6D-dideoxy-6A,6D-bis(1-imidazolyl)cyclodextrins towards Pt(II) and Ru(III)

Two imidazole-coordinating groups have been successfully grafted onto the C-6^A and C-6^D positions of permethylated α- and β-cyclodextrin scaffolds. Both water-soluble ligands L1 and L2 turned out to behave as good chelators when reacted with K₂PtCl₄. In the resulting diamagnetic cis-chelate complexes, the metal cation is pending above the cavity entrance. Paramagnetic ruthenium(III) chelate complexes have also been successfully synthesised from L1 and L2. In these more sterically demanding octahedral complexes, the imidazole groups coordinate the metal centre in a trans-fashion.