Characterization of Sesquiterpene Polygodial-Beta Cyclodextrin Inclusion Complex

Polygodial is a sesquiterpene drimane isolated from the genus Drimys, whichexhibits anti-asthmatic, anti-allergic, anti-inflammatory and antinociceptive effects.We have prepared a polygodial--cyclodextrin inclusion complex for furtherpharmacological studies. The inclusion complex was synthesized by co-precipitationand analyzed by Thermogravimetric Analysis, showing a decrease in the number ofwater molecules of hydration in relation to the native -cyclodextrin. DifferentialThermogravimetric Analysis indicated a peak corresponding to the evaporation ofpolygodial. With Differential Scanning Calorimetry, the melting peak to polygodial was not observed, however, there was an increase in the energy of vaporization of the water molecules in relation to native -cyclodextrin. Using a Scanning Electron Microscopy a clear difference in the morphology of crystals of the inclusion complex and native -cyclodextrin could be seen. The association constant between polygodial and -cyclodextrin, measured by UV spectroscopy was 1,006 M^-1 at 37 °C, pH 7.0 and ionic strength 0.2 M, following stoichiometry 1:1.     

In vitro Release Study of Tretinoin from Tretinoin/Cyclodextrin Derivative Complexes

The effects of -cyclodextrin, hydroxypropyl -cyclodextrin and dimethyl -cyclodextrin complexes on the in vitro release of tretinoin gels were investigated. The experiments were carried out in a Franz cell using a silicone membrane as a barrier for the diffusion of the vehicle. Two types of vehicle were compared: a hydroalcoholic gel in which both tretinoin and the inclusion complexes are soluble, and an aqueous gel in which only the complexes are soluble but tretinoin is dispersed. As expected, the release rate of free tretinoin in the hydroalcoholic gel is much faster than in the aqueous gel. However, with the aqueous gel, the cyclodextrin complexation enhances the diffusion rate of the active drug through the membrane, especially with the hydroxypropyl cyclodextrin inclusion compound. The release of tretinoin is related not only to the stability constant of the inclusion, but also to the binding properties of the inclusion compounds to the vehicle.     

Photochemical addition of diethyl ether to β,β,β',β'-tetrakis(trifluoromethyl)divinyl ether

The 1:1 adducts of diethyl and ,,','-tetrakis(trifluoromethyl)divinyl ether (1),i.e., 3,5-(ee)-bis[2,2,2-trifluoro-1-(trifluoromethyl)ethyl]-2,6-dimethyl-1,4-dioxane (2) (3 isomers) and 4-ethoxy-1,1,1-trifluoro-2-trifluoromethyl-3-[3,3,3-trifluoro-2(trifluoromethyl)propenyloxy]pentane (3), have been obtained by UV-irradiation of a solution of divinyl ether1 in diethyl ether. The X-ray structural investigation of the all-(e)-isomer of dioxane (2) has been carried out.Deceased.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 1, pp. 85–88, January, 1994.     

A Novel Cyclodextrin-containing Glass Thermoplastic System (GTS) for Formulating Poorly Water Soluble Drug Candidates: Preclinical and Clinical Results

We present a novel solid solution/dispersion technology with glass thermoplastic properties that provide good dissolution rates and oral bioavailabilities for poorly water-soluble weak bases. In this process, a thermoplastic gum was prepared by mixing a polyhydroxy acid such as citric acid or tartaric acid with a weakly basic drug, hydroxypropyl--cyclodextrin (HP--CD) and a cellulose polymer such as hydroxypropylmethylcellulose (HPMC) in a protic solvent. Removal of the solvent gave a material which could be loaded into hard gelatin capsules. Several model compounds were processed in this manner including methylene blue and itraconazole. The resulting data indicated that dissolution properties of GTS's based on methylene blue was pH independent and rapid with 80% dissolved within 30 min. Three GTS formulations of itraconazole containing 100 mg of the drug and 500 mg of citric acid as well as various concentrations of HP--CD and HMPC were found to dissolve rapidly (100% in 45 min). One of these formulations was selected for human pharmacokinetic evaluation and demonstrated significant oral bioavailability relative to unmanipulated drug.The studies suggest that the components of the GTS provide for solubilization through complexation and reduced pH and that the cellulose polymer acts to inhibit recrystallization of the supersaturated solution formed. The rationaldevelopment of the GTS dosage form can be useful for generating acceptable formulations for poorly water-soluble drug candidates.     

Improvement of Solubility and Dissolution of 19-Norprogesterone via Inclusion Complexation

In an effort to modify the solubility and dissolution rate of the contraceptive steroid, 19-norprogesterone in order to improve its bioavailability, the cyclodextrin complexation approach was chosen. In solution, the complex formation with -cyclodextrin (-CD), hydroxyethyl -cyclodextrin (HE--CD) and hydroxypropyl -cyclodextrin (HP--CD) was confirmed by using solubility, UV, IR and ¹H-NMR spectrophotometric techniques. The phase solubility diagrams were categorized as A_L-type. The complexing affinity of the CDs investigated were ranked as follows: -CD > HP--CD > HE--CD. The complexation thermodynamic parameters were obtained from the temperature dependence of the dissociation constants. In the solid state, differential scanning calorimetery (DSC) and optical microscopy methods were utilized to characterize the complexes. Dissolution studies showed that such molecularly encapsulated forms offered a marked improvement in the dissolution rate compared to the parent drug.     

Improvement in the Physicochemical Properties of Ketoconazole through Complexation with Cyclodextrin Derivatives

Highly-soluble cyclodextrin derivatives, such as hydroxypropyl--cyclodextrin(HP--CD) and methyl--cyclodextrin (MEB), were tested as solubilizingagents for ketoconazole, with the aim of improving the physicochemical andbiopharmaceutical properties of this lipophilic imidazole antifungal agent. Productswere prepared in four molecular ratios by physical mixing, kneading and spray-dryingmethods. The kneaded products in a ratio of 1:2 and the spray-dried products exhibitedthe highest dissolution rates. The phase solubility diagrams of ketoconazole with thesecyclodextrins at 25 °C in water and in simulated intestinal medium wereconstructed. A solubility diagram of A_L type was obtained with HP--CD, and one of A_P type with MEB. The complexes were characterized by thermal methods(DSC, TG, DTG and DTA). Multicomponent systems were prepared with tartaric acid.The effects of water-soluble polymers, e.g., polyvinylpyrrolidone, on the aqueous solubility of ketoconazole were investigated. Particle size distribution, surface area, partition coefficient, heat of dissolution and wettability studies were also carried out. The formation of inclusion complexes was observed by means of thermoanalytical studies.     

Theoretical Insights into the Formation, Structure, and Energetics of Some Cyclodextrin Complexes

To investigate the physicochemical aspects relevant for the formation of various cyclodextrin inclusion complexes and to search for corresponding general structure–complex-stability relationships, stability data of 1 : 1 complexes for 179, 310, and 51 guest molecules with unsubstituted -, -, and -cyclodextrin were collected. Statistical analysis using structure-based parameters such as molecular size, hydrophobicity, rotatable bonds, electronic properties, and the presence or absence of more than 150 various functional or structural moieties were performed. The complexation thermodynamics could be well described within the framework of our recently introduced molecular size-based model for nonassociative liquids. With increasing guest size, 1 : 1 complex stability, as measured by ln K or G⁰, increases linearly up to a size limit characteristic for each CD, and the corresponding slopes and intercepts are in agreement with those predicted by the model. For larger structures, values level off and are scattered around an average value depending on shape, goodness of fit, and possibly lipophilicity and some specific effects (e.g. such as those caused by presence of phenol functionality). The complexation between -cyclodextrin and certain large steroidal guest molecules, especially a brain-targeted estradiol chemical delivery systems (E₂-CDS) that is under clinical development, was investigated in details based on fully relaxed semiempirical AM1 quantum chemical calculations. A deformation index (DI) of the CD ring computed using these fully optimized host-guest geometries could be used to characterize the conformational change of the guest.     

Reaction of β-Cyclodextrin with N-2,3-Epoxypropylphthalimide. Preparation, Characterisation and Study of a New Substituted Cycloheptaamylose. Effects on the Water Solubility of Drugs

The reaction of -cyclodextrinwith N-2,3-epoxypropylphthalimide yielded a set of newamorphous host compounds with high solubility whichwas transmitted to the corresponding host-guestcomplexes. The structure was determined by comparing the 1H- and 13C-NMR spectra with those of theparent compound, the degree of substitution by integration of the corresponding NMR signals, and C, H,and N elemental analysis.     

The role of intra- and intermolecular hydrogen bonds in the formation of β-cyclodextrin head-to-head and head-to-tail dimers. The results of ab initio and semiempirical quantum-chemical calculations

The conformation of a free -cyclodextrin molecule optimized by the MNDO/PM3 quantum-chemical calculations has C₇ symmetry. The right orientation of the interglucose hydrogen bonds in -cyclodextrin, in which the 2-OH groups act as the proton donors and the O atoms of the nearby 3"-OH groups function as the proton acceptors, is advantageous for thermodynamic reasons. The ring of seven H bonds thus formed stabilizes the symmetrical form of -cyclodextrin. The -cyclodextrin head-to-head dimer has D ₇ symmetry and consists of molecules whose 2-OH groups partcipate as proton donors in the formation of fourteen complementary intermolecular hydrogen bonds. The energy of H bonds in the -cyclodextrin monomer and dimer was estimated to be 1.0--1.4 kcal mol^–1. Of the two possible -cyclodextrin dimers, the head-to-tail dimer is more thermodynamically stable. The thermodynamic preference of the right orientation of the inter-glucose H bonds in -cyclodextrin was confirmed by the MP2/6-31G(d,p)//6-31G(d,p) ab initio calculations for maltose (-glucodioside). The maltose molecule with inter-glucose H bonds of the type 2-OHO(3")-H is more stable than the structure with the H-(2)OH-O(3") orientation of H bonds with a difference of 2.7 kcal mol^–1. According to the MNDO/PM3 method, the maltose structure with the right H bond orientation is more stable by 3.1 kcal mol^–1.     

Molecular Interactions and Inclusion Phenomena in Substituted β-Cyclodextrins. Simple Inclusion Probes: H2O, C, CH4, C6H6, NH4 +, HCOO−

Using a simple molecular mechanics approach interaction energy profiles of simple probes (C, CH₄, C₆H₆, H₂O, NH₄ ⁺, and HCOO^-) passing through the center of the -CD ring cavity along the main molecular symmetry axis were first evaluated. Molecular Electrostatic Potential (MEP) values along the same path were also evaluated. The effect of the flexibility of the host -CD molecule together with solute-solvent (H₂O) interactions have been represented by averaging structures of MD calculations for -CD alone and -CD surrounded by 133 H₂O molecules. The effect of various substitutions of -CD has also been evaluated. Small symmetric hydrophobic probes (such as C, CH₄, C₆H₆) are predicted to form stable inclusion complexes with non-substituted and substituted -CDs, the probe position typically being near the cavity center. The stability of the inclusion complexes will increase with increasing size and aliphatic character of the probe. Small polar and charged probes (such as H₂O, NH₄ ⁺, HCOO^-) are predicted to prefer the interaction with the solvent (water) in the bulk phase rather than the formation of inclusion complexes with non-substituted and substituted -CDs. Guest–host interactions in the stable inclusion complexes with hydrophobic probes are almost entirely dominated by dispersion interactions. The MEP reaches magnitudes close to zero in the center of the non-substituted -CD ring cavity and in most of the studied substituted -CDs and shows maximum positive or negative values outside of the cavity, near the ring faces. Substitution of -CD by neutral substituents leads to enhanced binding of hydrophobic probes and significant changes in the MEP profile along the -CD symmetry axis.     

Effect of Cyclodextrins on the Chemical Stability of ST1435, a Contraceptive Steroid Progestin, in Aqueous Solution

The influence of cyclodextrins (CDs) on the chemical stability of the contraceptive steroid progestin, ST1435, in aqueous solution has been studied using reversed phase high performance liquid chromatography. The effects of CD structure, temperature, and CD concentration on the rate of degradation were investigated. It was found that the drug degraded to different extents following a pseudo-first order reaction mechanism. The presence of the host molecules affected the degradation rate as a result of complexation which might result in protection of the labile moiety of the drug molecule against degradation. Hydroxypropyl--cyclodextrin (HP--CD) and hydroxyethyl--cyclodextrin (HE--CD) retarded the degradation in contrast to -cyclodextrin (-CD) which accelerated the steroid degradation. The stabilizing action of HP--CD is larger than that of HE--CD. The degradation rate increased upon increasing temperature and the Arrhenius equation is valid. Lineweaver-Burk equation analysis indicated that the steroid included inside the CD cavity degraded three times more slowly than did the free ST1435 in solution. This equation further supported the formation of a 1 : 1 inclusion complex between ST1435 and HP--CD with a stability constant of 934.5 M-1 at 65°C.     

The Heptakis-(2,6-di-O-methyl)-β-cyclodextrin Inclusion Complex with Acetic Acid

A novel monomer-type structure of heptakis-(2,6-di-O-methyl)--cyclodextrin in a typical monoclinic herringbone scheme has been determined by single crystal X-ray diffraction. Crystal data: space group P21, Z = 2, a = 15.165(6), b = 10.613(3), c = 23.188(8) Å, = 102.02(4)°, V = 3650(3) Å3 and R = 0.094 for 2933 observed MoK reflections with I > 3(I). A unique water molecule located in the intermolecular spaces, reinforces the cohesion between the herringbone chains. The analysis of the electron density distribution suggests that an acetic acid molecule is trapped within the macrocycle cavity, alternately with a water molecule.     

Complexation of the Non-steroidal Anti-inflammatory Drug Loxoprofen with Modified and Unmodified β-Cyclodextrins

The inclusion complex of the anti-inflammatory drug, loxoprofen, with -cyclodextrin-(CD), sulfated -CD, and glycerol ether -CD was studied by UV-VIS absorption and ¹H-NMR spectroscopy in solution. The inclusion complex of loxoprofen with -CDs was prepared by freeze-drying, and then characterized in the solid state by thermal analysis, X-ray diffraction, FT-IR and FT-Raman spectroscopy, and scanning electron microscopy (SEM). Furthermore, a physical mixture of loxoprofen/-CD (1/1, mol-%) in the solid state was also characterized. The solubility of the loxoprofen increased on addition of -CDs. The solubility enhancement of the loxoprofen with -CDs is in the following order: glycerol ether -CD > sulfated -CD > -CD.     

Determination of the stoichiometry and stability constants of theβ-cyclodextrin-dextromethorphan inclusion complexes by liquid chromatography and UV spectroscopy

The inclosion of dextromethorphan (DMN) by -cyclodextrin (-CD) was studied by using chromatography, UV spectroscopy and circular dichroism methods at 25 °C, pH 7.4 and 4.2. It was found that the CD : DMN complex has 1 : 1 stoichiometry. It is more stable at pH 7.4 than at pH 4.2. with constants respectively equal to 8000 ± 800 M^–1 and 5750 ± 500 M^–i, as determined by chromatography. The stability of the complex at pH 7.4 decreases as the temperature increases. From the van 't Hoff dependence the standard entropy and enthalpy changes were determined at this pH.     

Inclusion of Ring A of Cholesterol Inside the β-Cyclodextrin Cavity: Evidence from Oxidation Reactions and Structural Studies

The disposition of cholesterol inside the -cyclodextrin cavity(-CD) was deduced from oxidation of cholesterol secondary alcoholgroups by Ca(OCl)₂ and H₂O₂ in thepyridine–acetic acid system. The amount of cholest-4-ene-3-one formedwas found to be proportional to the concentration of -cyclodextrin,resulting in 56.1% of ketone. The oxidation rate was enhanced by-cyclodextrin and its methyl, polymer and 1 : 1copper(II)–-cyclodextrin derivatives. Detailed investigationsinvolving UV-visible, ¹³C- and ¹H-NMR(T₁, 1D NOE and ROESY) spectroscopic studies were carried out.A binding constant value of 15,385 ± 1500 M^-2 wasobtained for the 2 : 1heptakis-2,6-di-O-methyl--cyclodextrin(DM-CD) : cholesterolcomplex in chloroform from UV studies. Proton and solid state¹³C-CP MAS spectra of the -CD–cholesterol mixtureshowed large magnitude shifts for the protons from the wider end of the-CD cavity as well as those of ring A and ring B of cholesterol. Both1D NOE and ROESY measurements indicated the proximity between ring A andring B protons of cholesterol and the wider end protons of -CD andDM-CD. Besides, analysis of _c,_i and tau;_m from T₁measurements showed not only a lowering of rotational motions but a value of 0.016–0.048 for some of the cholesterol protons, typical of aweak complex. Based on these studies, a probable structure for the 2 : 1complex involving two molecules of -CD/DM-CD was proposed withportions of ring A and ring B being present inside the wider end of the-CD/DM-CD cavity and ring D and the side chain attached atposition 17, projecting into the wider end of the secondCD/DM-CD molecule.     

NMR Study of the Inclusion Complexes of Carboxy-Phenoxathiin Derivatives with β-Cyclodextrin

The inclusion complexes of the carboxylate forms of 3-carboxy-(I) and 2-carboxy-phenoxathiin (II) with -cyclodextrin were studied by bothone- and two-dimensional NMR spectroscopy. The analysis of the induced chemical shifts of theguests in the presence of different amounts of the host indicates the formation of complexes with 1:1stoichiometry and association averaged pK values of 3.75 (I) and 4.4 (II). Thequalitative analysis of cross peaks in the ROESY spectra support the inclusion of the guests in the cavitywith the substituted phenyl ring, the COO^- group being in the proximity of the primary rim.     

The Chlorhexidine: beta;-Cyclodextrin Inclusion Compound: Preparation, Characterization and Microbiological Evaluation

The 1 : 2 chlorhexidine : -cyclodextrin(Cx : CD) complex was prepared and characterised using X-ray crystallography, infrared spectroscopy, thermal analysis and nuclearmagnetic resonance. The minimum inhibitory concentration (MIC₅₀) of the chlorhexidine : -cyclodextrin inclusion compoundagainst Streptococcus mutans, Eubacterium Lentum, Fusobacterium nucleatum, Bacteroides fragilis andActinomices actinomycetemcomitans was determined. TheCx : CD inclusion compound inhibited the bacterial growth at a low concentration.     

Pressure Perturbation Calorimetry of Solvation Changes in Cyclodextrin Complexes

Solvation changes occurring during cyclodextrin host:guest complex formation were investigated using the new calorimetric technique of Pressure Perturbation Calorimetry (PPC). This can determine the thermal expansion coefficient of molecules in solution. PPC was used to measure the change in heat ( Q) that occurs upon application of pressure to three different solutions: guest (1-adamantanecarboxylic acid or 1-adamantanamine), -cyclodextrin, and -cyclodextrin/guest mixture. Q for the complex in solution was found to be smaller than anticipated from the sum of the heat changes of the separate components. Since Q is directly related to thermal expansivity (), the results imply that the complex expands less with temperature than expected. This reduction is most likely due to the removal of the solvation shell around the ligand and, to a lesser extent, expulsion of water molecules from the cyclodextrin cavity during complex formation.     

Reaktionsverhalten von β-Oxo-carbonsäurederivaten der Anthracenreihe bei der Synthese von Thiophenen

Summary -Oxo-1-anthracenepropionate (3) reacts step by step with phenylisothiocyanate and -CH-acidic halo compounds to keten-S,N-acetals4, followed by cyclocondensation to give the 4-(1-anthracenyl)-thiophene-3-carboxylates5. In contrast, the reaction of -oxo-9-anthracenepropionate (6) with isothiocyanates and -CH-acidic halo compounds yields 5-acyl-2-amino-3-(9-anthracenoyl)-4-hydroxy-thiophenes8. This is caused by the sterical hindrance of the keto group of the anthracene in position 9; thus, the cyclocondensation proceedsvia reaction of the ester group of the -oxo-propionate. In the same way, 9-acetylanthracene reacts with phenylisothiocyanate and -CH-acidic compounds to keten-S,N-acetals10 and, in an additional step, to 2-anilino-3-(9-anthracenoyl)-thiophenes11 and 2-(9-anthracenoyl)-methylene-3,4-diphenyl-2,3-dihydro-(1,3)-thiazole12, respectively. The structure of all new compounds was determinated by 2D NOESY NMR spectroscopy.

Herrn Prof. Dr. habil.G. Großmann zum 65. Geburtstag gewidmet     

Darstellung und Eigenschaften von 2-Acyl-1,2-thiazetidin-1,1-dioxiden

Title compounds3a–3i were synthesized by acylation of 1,2-thiazetidine 1,1-dioxide by various methods. Spectroscopic data elucidate the conformation and geometry of the fourmembered ring. An X-ray analysis of3i is presented.