Modified gamma-cyclodextrins and their rocuronium complexes

A series of per-6-substituted cyclodextrin derivatives was synthesized as synthetic host molecules for rocuronium, a steroidal muscle relaxant. By forming host-guest complexes with rocuronium, these cyclodextrin derivatives reverse the muscle relaxation induced by rocuronium in vitro and in vivo. The isothermal microcalorimetry data are consistent with the biological data supporting the encapsulation mechanism of action. Binary and biphasic complexes are reported with NMR experiments clearly showing free and bound rocuronium. [structure: see text]     

Ditopic binding of cyclodextrin-included ligands in trigonal silver(I) complexes

The X-ray crystal structures of trigonal silver(I) cyclodextrin complexes of introverted bidentate sulfur (1) and phosphorus (2) ligands give a clear indication on how a cyclodextrin-included ligand may bind in a ditopic fashion both the encapsulated metal ion and the cyclodextrin inner wall. In the solid state, the silver-coordinated water molecule of complex [Ag(H₂O)(1)]BF₄ induces a major distortion of the macrocyclic structure, along with dramatic conformational changes in the two opposite glucose units with which it is hydrogen bonded. In complex [AgBr(2)], the included bulky bromide anion, which lacks hydrogen bonding capability, does not affect the overall circular shape of the cyclodextrin receptor. A ¹H-¹⁹F HOESY experiment conducted on the silver(I) complex of 1 in CDCl₃ showed that in this solvent, the water molecule is displaced by the BF₄ counterion at the metal coordination site, the cavity being here no longer distorted.     

Simultaneous determination of rocuronium and its eight impurities in pharmaceutical preparation using high-performance liquid chromatography with amperometric detection

A sensitive and selective HPLC method with amperometric detection (HPLC-ED) for the determination of rocuronium bromide and its eight impurities has been developed. The analysis was performed on Hypersil 100 Silica column 5 microm (250 mm x 4.6 mm; Thermo Electron). The mobile phase consisting of 4.53 g l(-1) solution of tetramethylammonium hydroxide adjusted to pH 7.4 with 85% phosphoric acid:acetonitrile (1:9), was found the best for the separation and determination of the studied compounds. The chromatograms were recorded over 10 min using the amperometric detection at a potential +0.9 V of the glassy carbon electrode versus the reference electrode Ag/AgCl. The limit of quantitation was 45 ng ml(-1) for rocuronium and from 25 to 750 ng ml(-1) for the examined impurities. The proposed HPLC-ED method was successfully applied to the analysis of rocuronium and its impurities in Esmeron solution for injection.     

Effect of cyclodextrin complexation in bromine addition to unsymmetrical olefins: evidence for participation of cyclodextrin hydroxyl groups

Multiple recognition by cyclodextrin in a bimolecular reaction, namely bromination of styrene, methyl cinnamate, phenylacetylene and allylbenzene, has been studied. Bromohydrin is obtained as a major product along with dibromide in the bromination of styrene and methyl cinnamate. The percentage of bromohydrin decreases as the cavity size increases. With phenylacetylene, bromophenylacetylene and phenacyl bromide are obtained in addition to the dibromides. In the bromination of cyclodextrin complexes of allylbenzene, the product distribution is the same as in solution bromination. The observed results demonstrate the efficiency of cyclodextrin in stabilizing the open carbocationic intermediate and thus provide chemical evidence for the participation of cyclodextrin hydroxyl groups.     

Nanoparticle Vesicles Through Self Assembly of Cyclodextrin‐ and Adamantyl‐Modified Silica

Stable nanoparticle vesicles were for the first time prepared from adamantyl‐ and cyclodextrin (CD)‐modified silica nanoparticles forming host–guest interactions in aqueous solution. Adamantyl‐functionalized nanoparticles were obtained from thiol‐isocyanate reaction of thiol‐modified nanoparticles with 1‐adamantyl isocyanate. The CD modified silica particles were isolated from a reaction of mono‐6‐para‐toluenesulfonyl‐β‐cyclodextrin with the thiol functionalized silica under microwave conditions in basic media. The obtained particles were characterized in respect of agglomeration and self‐assembly behavior in aqueous solution by dynamic light scattering and transmission electron microscopy. The found vesicle structures are exceptionally stable even after evaporation of water. Such inorganic hollow spheres formed through self‐assembly processes may be important for chemical storage and transport. The technique of chemically‐driven assembly is an attractive option to form useful complex structures by tunable agglomeration.

     

Binding ability and self-assembly behavior of linear polymeric supramolecules formed by modified beta-cyclodextrin

[structure: see text] The binding ability and self-assembly behavior of molecular interpenetration by newly synthesized mono[6-O-(4-formyl-phenyl)-beta-cyclodextrin has been investigated, revealing the formation mechanism of modified cyclodextrin from solution aggregation to solid linear polymeric supramolecules.     

A Hybrid Supramolecular Polymeric Hydrogel with Rapid Self‐Healing Property

A hybrid supramolecular polymeric hydrogel is conveniently constructed via host–guest interaction of a host cyclodextrin polymer (poly‐CD) with a guest α‐bromonaphthalene polymer (poly‐BrNp) and mixing with 6‐thio‐β‐cyclodextrin (β‐SH‐CD) modified gold nanoparticles (GPCDs) in aqueous solution. According to the dynamic oscillatory data, the hydrogel exhibits markedly enhanced stiffness compared with the GPCD‐free one (both G′ and G“ values are almost twice as high as those of the original GPCD‐free hydrogel) due to the introduction of the inorganic gold nanoparticles. This hybrid supramolecular polymeric hydrogel has a rapid and excellent self‐healing property (only about 1 min, and the G′ and G” of the self‐healed hydrogel almost turned back to their original levels after 1 hour) in air (without adding any solvent or additive).     

Synthesis,structures, and properties of new sterically hindered hydrazine-based catecholaldimines

New sterically hindered catecholaldimines derived from hydrazine were synthesized in high yields. Two procedures for the synthesis of sterically hindered catecholaldimines were developed: by the reaction of 4,6-di-tert-butyl-2,3-dihydroxybenzaldehyde with hydrazines (hydrazine hydrate, phenyl-, 1,1-diphenyl-, and (diphenylmethylene)hydrazines, acetyl and benzoyl hydrazides) or by the reaction of 3,5-di-tert-butyl-6-(hydrazonomethyl)catechol with a carbonyl compound (the reaction with 4-N,N-dimethylaminobenzaldehyde). The X-ray diffraction analysis and IR, UV, and NMR spectroscopic studies showed that these compounds exist in the catecholic form both in solution and the crystalline state.     

Dopamine Oxidation at Per(6‐deoxy‐6‐thio)‐α‐Cyclodextrin Monolayer Modified Gold Electrodes

The gold electrode is functionalized by sequential self‐assembly of a monolayer of the title thiolated cyclodextrin with and without dopamine included in the cavities. The structure of α‐cyclodextrin modified gold electrode is carefully characterized using STM and AFM. Surface complexation of dopamine is examined and its association constant is evaluated. Chemical reactions accompanying the electrode process of dopamine, which interfere in the electrochemical dopamine determination, are described and the conditions to avoid them are proposed. Dopamine incorporated in the α‐cyclodextrin sites anchored to the electrode surface was found to provide electrochemical contact of the electrode with the solution‐resident dopamine. Dopamine present in the α‐cyclodextrin cavities has different properties compared to dopamine in the bulk buffer solution and can act as a mediator for the dopamine molecules diffusing to the electrode. This unique mediation effect leads to improvement of the sensitivity of dopamine determination using the α‐cyclodextrin modified electrode and a procedure for the determination of dopamine in large excess of ascorbate is proposed.     

Synthesis of Organoselenium‐Modified β‐Cyclodextrins Possessing a 1,2‐Benzisoselenazol‐3(2H)‐one Moiety and Their Enzyme‐Mimic Study

Six novel H₂O‐soluble β‐cyclodextrin derivatives containing a 1,2‐benzisoselenazol‐3(2H)‐one moiety were synthesized by a convenient method in 25–60% yield and characterized by MS, elemental analysis, IR, ¹H‐NMR, and UV/VIS spectroscopy. The conformations of these β‐cyclodextrin derivatives 1 – 6 were analyzed by circular dichroism and fluorescence‐lifetime experiments. The superoxide dismutase (SOD) activities of 1 – 6 were determined by auto‐oxidation of pyrogallol at 25.0° in buffer solution (pH 8.2), giving relatively high SOD activities of up to 121–330 U/mg. Also, the glutathione peroxidase (GPX) activities of hosts 1 – 6 , determined by the method of Wilson at 37° in buffer solution (pH 7.0), show good GPX activities in the range of 0.34–0.86 U/μmol. The mimicking results of the bifunctional artificial enzyme models 1 – 6 were globally compared with regard to their structural and conformational difference.     

A new and efficient method for the synthesis of rocuronium bromide

Rocuronium bromide has been used as an aminosteroid non-depolarizing neuromuscular blocker and muscle relaxant.In this work,a new and efficient route for preparing a key intermediate 2β-(4-morpholinyl)-16β-(1-pyrrolidinyl)-5α-androstan-3α,17β-diol(6) was developed through a ring-opening of epoxide followed by introducing and pyrrolidine.Compound 6 can easily provide rocuronium bromide and the overall yield of compound 6 in 5 steps increased to 57.8%,which was higher than currently reported methods.Extraordinarily,this method would avoid the generation of disubstituted impurities E and F which are difficult to remove.     

Cyclodextrin-modified MCM-41 for selective double bond migration

Cyclodextrin-modified MCM-41 with relatively high surface area above 1,100 m²/g has been prepared via simple hybridization of cetyltrimethylammonium bromide and cyclodextrin. The modified MCM-41 showed fairly good catalytic performance (high activity and selectivity) in the double bond migration of 2-butene into 1-butene.     

Mucoadhesive Sustained Drug Delivery System Based on Cationic Polymer and Anionic Cyclodextrin/Triclosan Complex

In this study the interactions between a cationic polymer and an anionic cyclodextrin were investigated. The system has the potential for use in a sustained release dosage forms for use on mucous membranes. As mucous membranes are negatively charged the objective of this study was to investigate whether a drug delivery system based on a cationic polymer and an anionic cyclodextrin would be more mucoadhesive than a system containing a cationic polymer and a neutral cyclodextrin. For this purpose the cationic polymer hexadimethrine bromide (HDMBr) and anionic sulfobutylether -cyclodextrin (SBECD) were utilized as well as the neutral hydroxypropyl-cyclodextrin (HPCD). Triclosan was used as a model drug. The drug delivery system was formulated as a solution or semi-solid and its adhesion to porcine buccal mucosa and cation exchange media was measured. In addition the release of triclosan from the system was quantified. No difference was observed between the two systems when they were applied to the mucosal surface. However, the formulations showed improved adhesion, compared to the neutral cyclodextrin/drug delivery system, when they could also reach the underlying surface of the excised tissue. The drug delivery system was much better retained on the cation exchange media than the uncharged system. Significant interactions were observed between the negatively charged cyclodextrin and the positively charged polymer. The results indicate that the interactions could be used to obtain a mucoadhesive sustained drug delivery system under certain circumstances. The positive charge of HDMBr did not have the expected effect on the buccal mucosa and it can be concluded that although a positive charge is likely to promote mucoadhesion, other attributes of polymers, such as molecular weight and viscosity, may have equally beneficial effect.     

Structure-Chemical Analysis of Multiple Complexations by Cyclodextrins

The interactions between cyclodextrin and substrates having two binding sites in aqueous solution are reviewed. For such substrates, multiple equilibria, NMR chemical shift variations with full binding, solution structures of complexes, and the effect of cavity size are analyzed quantitatively. After general treatments of multiple equilibria and chemical shifts are given, they are applied to three bivalent substrates of diheptanoyllecithin, dialkyldimethylammonium bromide, and oxyphenium bromide for demonstrating their usefulness. The solution structures of complexes play a crucial role in these basic researches as well as the applications of cyclodextrins, such as bitter taste reduction and stabilization of labile substrates.     

含氮基团修饰β-环糊精量子化学研究

用PM3半经验方法优化了5种不同含氮基团修饰环糊精的结构,并用HF方法在STO-3G和3-21G*两种基组水平上计算了它们的单点能.首次给出了这5种修饰环糊精的优化结构,同时计算结果采用极性基团会增加修饰环糊精的偶极距,优化的结构及计算出的物理性质表明修饰后产物明显与β-环糊精有明显的差别.     

Masking mechanisms of bitter taste of drugs studied with ion selective electrodes

The masking mechanisms of the bitter taste of propantheline bromide (PB) and oxyphenonium (OB) bromide by native and modified cyclodextrins, saccharides, surfactants, organic acids, nonionic and anionic polymers, and other compounds were investigated with ion selective electrodes. The intensity of the bitter taste for a mixed solution of cyclodextrin with PB or OB was quantitatively explained from the observed electromotive force with the following assumptions: the complex and the masking agent do not have any tastes and the bitter taste is independent of other tastes. Sodium dodecyl sulfate reduced the bitter taste remarkably, and this reduction was also explicable on the basis of the same mechanism. Sodium taurodeoxycholate enhanced the bitter taste, because of its strong bitterness, although it formed 1 : 1 complexes with PB and OB. The masking mechanism of saccharides was ascribed to overcoming the weak bitterness of the drug by the strong sweetness. Lambda-carrageenan suppressed the bitter taste remarkably. This suppression was ascribed to the binding of PB and OB to lambda-carrageenan, the effect of the solution viscosity on the bitter taste, and the covering of the bitter taste receptor by lambda-carrageenan. It was suggested that the moderate masking by other polymers was attributable to the effect of the solution viscosity or the receptor covering. Native and modified beta-cyclodextrins, sodium dodecyl sulfate, lambda-carrageenan, Tween 20, and sodium carboxymethyl cellulose are good masking agents for the bitter tastes of PB and OB. The drug ion selective electrode is a useful tool for understanding of the masking mechanism of the bitter taste, screening of masking agents, and estimation of appropriate concentrations of the masking agents.     

Inclusion Complexes of Ionic Liquids and Cyclodextrins: Are They Formed in the Gas Phase?

The interaction of imidazolium-based ionic liquids with α- and β-cyclodextrins was investigated by electrospray ionization mass spectrometry with variable collision induced dissociation energy and quantum chemical gas-phase calculations. The center-of-mass energy at which 50 % of a precursor ion decomposes (E_cm,1/2) was determined for the isolated [cyclodextrin + cation]⁺ or [cyclodextrin + anion]^– adduct ions of imidazolium-based ionic liquids with different alkyl chain lengths combined with a large set of anions, such as chloride, bromide, bis(trifluoromethylsulfonyl)imide, tetrafluoroborate, hexafluorophosphate, trifluoromethanesulfonate, methanesulfonate, dicyanamide, and hydrogensulfate. Moreover, both symmetric and asymmetric imidazolium cationic cores were evaluated. The relative interaction energies in the adduct ions were interpreted in terms of the influence of cation/anion structures and their inherent properties, such as hydrophobicity and hydrogen bond accepting ability, in the complexation process with the cyclodextrins. The trends observed in the mass spectral data together with quantum-chemical calculations suggest that in the gas phase, cations and anions will preferentially interact with the lower or upper rim of the cyclodextrin, respectively, as opposed to what has been reported in condensed phase where the formation of an inclusion complex between ionic liquid and cyclodextrin is assumed.

Synthesis of the chiral selector heptakis(6‐O‐methyl)‐β‐cyclodextrin by phase‐transfer catalysis and hydrazine‐mediated transfer‐hydrogenation

The exhaustive primary‐side alkylation of cyclodextrins has never been achieved directly. The undesired and simultaneous derivatization of the secondary hydroxyl moieties generates intricate isomeric mixtures that are challenging to purify, analyse and characterize. The aim of this study was to develop a chromatography‐free and up‐scalable strategy towards the preparation of per‐6‐O‐methylated cyclodextrin and to test the compound as potential chiral selector. The target molecule was prepared according to a five‐step synthesis by using methyltriphenylphosphonium bromide as catalyst under heterogeneous conditions. The removal of benzyl moieties, used as temporary secondary‐side protecting groups, was attained by applying hydrazine‐carbonate in the presence of Pd/C. All the intermediates were obtained in high yields, thoroughly characterized and their purity was assessed by ad‐hoc developed HPLC methods. The per‐6‐O‐methylated β‐cyclodextrin showed promising chiral recognition ability as background electrolyte additive in cyclodextrin‐modified capillary electrophoresis using the recreational drug methylene‐dioxypyrovalerone as model compound. Additionally, a model for the inclusion geometry between the single isomer host and the selected drug was developed based on the extensive 2D NMR analysis. The versatility of the proposed synthetic strategy opens the way to the industrial production of homogeneously primary‐alkylated cyclodextrins and to their wide application in chiral separation of various drugs.     

Cyclodextrin-mediated regioselective photo-Fries reaction of 1-naphthyl phenyl acylates

1-Naphthyl phenyl acylates upon irradiation in solution yield eight products via β-cleavage process. However, excitation of these molecules as included in γ-cyclodextrin results in a single product (>95%). This medium dependent product selectivity is attributed to conformational and translational restrictions enforced on the reactant as well as intermediates by the cyclodextrin cavity.     

Electromembrane extraction combined with cyclodextrin-modified capillary electrophoresis for the quantification of trimipramine enantiomers

A sensitive, simple and reproducible method was developed for preconcentration and determination of trimipramine (TPM) enantiomers in biological samples using electromembrane extraction combined with cyclodextrin‐modified capillary electrophoresis (CE). During the extraction, TPM enantiomers migrated from a 5 mL sample solution through a thin layer of 2‐nitrophenyl octyl ether NPOE immobilized in the pores of a hollow fiber, and into a 20 μL acidic aqueous acceptor phase presented inside the lumen of the fiber. A Box–Behnken design and the response surface methodology (RSM) were used for the optimization of different variables on extraction efficiency. Optimized extraction conditions were: NPOE as supported liquid membrane, inter‐electrode distance of 5 mm, stirring rate of 1000 rpm, 51 V potential difference, 34 min as the extraction time, acceptor phase pH 1.0 and donor phase pH 4.5. Then, the extract was analyzed using optimized cyclodextrin (CD)‐modified CE method for the separation of TPM enantiomers. Best results were achieved using 100 mM phosphate running buffer (pH 2.0) containing 10 mM α‐CD as the chiral selector, applied voltage of 18 kV and 20°C. The range of quantitation for both enantiomers was 20–500 ng/mL. The method was very reproducible so that intra‐ and interday RSDs (n=6) were <6%. The limits of quantitation and detection for both enantiomers were 20 and 7 ng/mL, respectively. Finally, this method was successfully applied to determine the concentration of TPM enantiomers in plasma and urine samples without any pre‐treatment.