Demonstrating accuracy of the already proposed protocol for structure elucidation of cyclodextrin inclusion complexes by validation using quantitative ROESY analysis

In this study, we attempt to ascertain the accuracy of the structures determined using our previously developed method and hence the accuracy of our method. In the present report, we have taken the guest molecule cetirizine (CTZ) and the host molecules are α-cyclodextrin (α-CD) and β-cyclodextrin (β-CD). Structures with good accuracy were elucidated using a productive fusion of experimental and computational methods. We performed molecular mechanics studies (MM) in light of experimental ROESY studies, followed by molecular dynamics studies (MD). The results from these studies were analyzed using quantitative ROESY analysis to determine the final accurate structures of the complexes. The accuracy of these structures was tested using density functional theory (DFT) that is an accurate method for structure determination. DFT studies were carried out using the functionals B3LYP and M06L with def-TZVP basis set and similarly quantitative ROESY analysis was performed for the obtained structures. The ROESY intensities of the structures obtained from MM and MD studies, were compared with ROESY intensities of the structures obtained from DFT studies. Calculated ROESY intensities of the structures obtained from B3LYP functional are comparable, with intensities of structures obtained from MM and MD studies, but M06L functional showed poor results. In addition to the accuracy of MM and MD studies, low computational cost and less time input make it good method for structural studies for CD inclusion complexes.

     

Complexation of triptolide and its succinate derivative with cyclodextrins: affinity capillary electrophoresis, isothermal titration calorimetry and 1H NMR studies

The complexation of the triptolide PG490 and its succinate derivative PG490-88Na with various cyclodextrins was studied using three complementary techniques: affinity capillary electrophoresis (ACE), isothermal titration calorimetry (ITC) and nuclear magnetic resonance (NMR). The apparent binding constants of the complexes formed between the drugs and 8 CDs (α-CD, β-CD, γ-CD, HP-α-CD, HP-β-CD, HP-γ-CD, CM-β-CD and amino-β-CD) were determined by ACE through linear Scott's plots. The apparent and averaged binding constants of the complexes formed between PG490-88 and β-CD, γ-CD, HP-α-CD, HP-β-CD or HP-γ-CD are contained in the narrow range 135-167 M(-1). For the anionic CM-β-CD and cationic amino-β-CD, these constants are 38 and 278 M(-1), respectively, which is in accordance with electrostatic repulsions or attractions with the succinate moiety. ITC and NMR investigations for the binding constants determinations were performed for 2 CDs allowing high complexation: HP-β-CD and amino-β-CD. The three techniques provided similar results. ITC and NMR, in contrast to ACE, allowed to study the complexes formed between the neutral compound PG490 and neutral cyclodextrins. A more advanced characterization of the PG 490-88Na/amino-β-CD complex, which displays the highest apparent binding constant, was undertaken using NMR spectroscopy. The 1:1 stoichiometry of the complex was established by (1)H NMR 1D and selective 1D TOCSY experiments using the continuous variation method. Moreover, the 1D and 2D ROESY experiments revealed the inclusion of the isopropyl moiety of the triptolide derivative in the hydrophobic CD cavity. Altogether, the data provide strong evidences that the two triptolide compounds can be efficiently complexed with CD.     

A comparative study of inclusion complexes of flunarizine with alpha (α-CD) and beta-cyclodextrin (β-CD)

A detailed NMR (¹H, COSY, and ROESY) spectroscopic study of complexation of Flunarazine (FL) with α- and β-CD was carried out. ¹H NMR titration studies confirmed the formation of FL/α-CD and FL/β-CD complexes as evidenced by chemical shift variations of the proton resonances of both the CDs and FL. The stoichiometry of the complexes was determined to be 1:2 (FL/α-CD) and 1:1 (FL/β-CD) and overall binding constants were also calculated. It was confirmed with the help of ROESY spectral data that only one of the F-substituted aromatic ring and phenyl ring penetrate the α-CD cavity while both F-substituted aromatic rings as well as phenyl ring penetrates the β-CD cavity during complexation. The binding modes of FL/CD cavity interactions derived from ROESY experimental data show that the resulting complex of FL with β-CD possesses better induced fit interaction as compared to α-CD, which is responsible for the enhanced molecular stability with β-CD in comparison to α-CD. The mode of penetration of guest into the CD cavity and structures of the complexes has been established.     

Spectroscopic study and antioxidant activity of the inclusion complexes of cyclodextrins and amlodipine besylate drug

The aim of the study was to synthesize and characterization the inclusion complexes of amlodipine besylate (AML) drug with β-cyclodextrin (β-CD) and γ-cyclodextrin (γ-CD) which has antioxidating activity property. The guest/host interaction of AML with β-CD and γ-CD in order to complexation drug in β-CD and γ-CD were investigated. The interaction inclusion complexes was characterized by fourier transform infrared and ultraviolet–visible spectroscopies. The formation constant was calculated by using a modified Benesi–Hildebrand equation at 25 °C. The stoichiometry of inclusion complexes was found to be 1:1 for β-CD and γ-CD with AML drug. The antioxidant activity of AML drug and its inclusion complexes were determined by the scavenging of stable radical 2,2′-diphenyl-1-picrylhydrazyl (DPPH^·). Kinetic studies of DPPH^· with AML and CDs complexes were done. The experimental results confirmed the forming of AML complexes with CDs also these indicated that the AML/β-CD and AML/γ-CD inclusion complexes was the most reactive than its free form into antioxidant activity.     

Gamma-cyclodextrin on enhancement of water solubility and store stability of nystatin

The water solubility of nystatin was found enhanced by forming inclusion complex with gamma-cyclodextrin (γ-CD). Further discovery of a pleased surprise showed that the phase solubility curves of nystatin in β- and γ-CD aqueous solution were A_L type, while B_S type for α-CD, indicating 1:1 inclusion complexes were formed between β-CD, γ-CD and nystatin, but no inclusion complexes for α-CD, in addition, CDs with much larger ring would be more suitable for forming inclusion complexes with macrolide antibiotics. The aqueous solubility of nystatin in γ-CD solution was investigated increased with γ-CD concentration increasing. At the concentration of 24 g/100 ml for γ-CD aqueous solution, which is near to the saturated solution, water solubility of nystatin was found to be 104 μg/ml, which was 103 folds over original nystatin. Inclusion constants for γ-CD–nystatin complexes were 0.539 l/mmol, which is larger than that of β-CD–nystatin complex (0.375 l/mmol). The inclusion complex of γ-CD with nystatin was prepared and detected by infrared spectrum, results showing that the ester linkage and diene were included in the cavity of CDs, while conjugate arachidonic, carboxyl and amino group were left outside of CDs. Storing experiment showed that forming of the inclusion complexes greatly enhanced the stability of nystatin against light and oxygen.     

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).     

Mass spectrometry and molecular modeling studies on the inclusion complexes between alendronate and β-cyclodextrin

Complexation of alendronate sodium (AlnNa) with β-cyclodextrin (β-CD) was studied by means of ESI-mass spectrometry. The experimental results show that stable 1:1 inclusion complexes between selected bisphosphonates and β-CD were formed. In addition, complexes with different stoichiometry were observed. DFT/B3LYP calculations were performed to elucidate the different inclusion behavior between alendronate and β-CD. Molecular modeling showed that the inclusion complex of Aln-β-CD where the two phosphonate groups bound to the central carbon atom of bisphosphonate were inserted into the cavity of β-CD from its “top” side was thermodynamically more favorable than when they were inserted from its “bottom” side; the complexation energy was ?74.05 versus ?60.85 kcal/mol. The calculations indicated that the formation of conventional hydrogen bonds was the main factor for non-covalent β-CD:Aln complex formation and stabilization in the gas phase.     

Spectroscopic characterisation of the inclusion complexes between the antifungal drugs naftifine and terbinafine and cyclodextrins

The complexation of naftifine (NF) and terbinafine (TB) with cyclodextrins (CDs) has been investigated by UV/visible and ¹H NMR spectroscopy, ROESY techniques and also ESI-MS. Both drugs form 1:1 inclusion complexes with all the CDs tested except with α-CD, as deduced from the Benesi–Hildebrand plots and confirmed by ESI-MS and NMR spectroscopy (Job plot method). The K ₁₁ values for NF decrease in the order β-CD > methylated β-CD > 2-hydroxypropyl-β-CD >γ-CD. The determination of the enthalpy and entropy provides information about the main driving forces in the process. The stability constants of the complexes NF–β-CD, TB–β-CD and TB–γ-CD determined by ¹H NMR spectroscopy are in agreement with the values obtained by UV. For TB–β-CD, the value is higher, due to the fact that the length of the TB aliphatic chain allows a deeper inclusion of the naphthalene group inside the corresponding β-CD molecule, according to the 2D ROESY experiments.     

Separation of enantiomers of norephedrine by capillary electrophoresis using cyclodextrins as chiral selectors: comparative CE and NMR studies

In this study, the enantiomer migration order (EMO) of norephedrine (NEP) in the presence of various CDs was investigated by CE. NMR and CE techniques were used to analyze the mechanism of the chiral recognition between NEP enantiomers and four CDs, i.e., native α-CD, β-CD, heptakis(2,3-di-O-acetyl-6-O-sulfo)-β-CD (HDAS-β-CD), and heptakis(2,3-di-O-methyl-6-O-sulfo)-β-CD (HDMS-β-CD). EMO was reversed in the presence of α-CD and β-CD, although only minor differences in the structures of the complexes formed between NEP and these CDs could be derived from rotating frame nuclear Overhauser experiments (ROESY). The complexes between the enantiomers of NEP and the sulfated CDs, HDMS-β-CD, and HDAS-β-CD, were substantially different. However, EMO of NEP was identical in the presence of these CDs. HDAS-β-CD proved to be the most suitable chiral selector for the CE enantioseparation of NEP.     

Comparison and correlation of in vitro, in vivo and in silico evaluations of alpha, beta and gamma cyclodextrin complexes of curcumin

In the present study investigated the effect of curcumin (CUR) alpha (α), beta (β) and gamma (γ) cyclodextrin (CD) complexes on its solubility and bioavailability. CUR the active principle of turmeric is a natural antioxidant agent with potent anti-inflammatory activity along with chemotherapeutic and chemopreventive properties. Poor solubility and poor oral bioavailability are the main reasons which preclude CUR use in therapy. Extent of complexation was β-CD complex (82 %) > γ-CD (71 %) > α-CD (65 %). Pulverization method resulted in significant enhancement of CUR (0.002 mg/ml) solubility with CUR α-CD complex (0.364 mg/ml) > CUR β-CD complex (0.186 mg/ml) > CUR γ-CD complex (0.068 mg/ml). Gibbs-free energy and in silico molecular docking studies favour formation of α-CD complex > β-CD complex > γ-CD complex. With reference to CUR, relative bioavailability of CUR α-CD, CUR β-CD and CUR γ-CD complexes were 460, 365 and 99 % respectively. CUR–CD complexes exhibited increased bioavailability with an increase in t_½, tmax, Cmax, AUC, Ka, and MRT; and a decrease in Ke, clearance and Vd values. AUC increase was CUR α-CD complex > CUR β-CD complex > CUR γ-CD complex. Significant difference (p < 0.05) was observed between CUR α-CD complex and CUR γ-CD complex by one-way ANOVA and Dunnett’s post hoc test for multiple comparison analysis. Correlation observed between in vitro, in vivo and in silico methods indicates potential of in silico and in vitro methods in CD selection.     

Encapsulation of vortioxetine with cyclodextrins via host–guest inclusion complex: Synthesis,characterization, solubility,and in vitro dissolution studies

Drug solubility plays a significant role in the development of drug formulation. The objectives of this work are to improve the solubility and dissolution rate of vortioxetine (VT) by preparing its inclusion complexes (ICs) with β-Cyclodextrin (β-CD) and γ-Cyclodextrin (γ-CD). The ICs were prepared in 1:1 M ratio via recrystallization method and characterized by P-XRD, FT-IR, ¹H NMR, 2D NOESY, and DSC. Further, the crystal structure of VT-β-CD was analyzed by SC-XRD. P-XRD data obtained for ICs describe the crystalline pattern. The DSC analysis shows change in the thermal behavior of VT, CDs and ICs. FT-IR analysis shows shifting of frequencies in ICs when compared with the pristine VT drug and CDs. The 2D NOESY in DMSO-d⁶ indicates weak interaction between the VT and CD molecules. The crystal structure of VT-β-CD consists of one guest VT, one host CD, and nine water molecules in the crystal lattice. The solubility of ICs was significantly improved in distilled water, pH 1.2 acidic, and phosphate buffer pH 6.8 medium, as compared with the solubility of the pristine VT drug. The in vitro dissolution rate of ICs in different dissolution media was investigated, which was higher than that of the commercial product of VT.     

Separation of terbutaline enantiomers in capillary electrophoresis with neutral cyclodextrin-type chiral selectors and investigation of the structure of selector-selectand complexes using nuclear magnetic resonance spectroscopy

The major goal of this study was to determine the affinity pattern of the terbutaline (TB) enantiomers toward α-, β-, γ-, and heptakis(2,3-di-O-acetyl)-β-cyclodextrins and using NMR spectroscopy for the understanding of the fine mechanisms of interaction between the cyclodextrins (CD) and TB enantiomers. It was shown once again that CE in combination with NMR spectroscopy represents a sensitive tool to study the affinity patterns and structure of CD complexes with chiral guests. Opposite affinity patterns of TB enantiomers toward native α- and β-CDs were associated with significant differences between the structure of the related complexes in solution. In particular, the complex between TB enantiomers and α-CD was of the external type, whereas an inclusion complex was formed between TB enantiomers and β-CD. One of the possible structures of the complex between TB and heptakis(2,3-di-O-acetyl)-β-CD (HDA-β-CD) was quite similar to that of TB and β-CD, although the chiral recognition pattern and enantioselectivity of TB complexation with these two CDs were very different.     

Formation of 3Pseudorotaxanes from β-cyclodextrin and a Series of Dicarboxylic Acids with Their Corresponding α,ω-alkanedicarboxylate Anions

Inclusion complexes between β-cyclodextrin (β-CD) and a series of dicarboxylic acids (DAn, n=11-15) were prepared by co-grinding and co-precipitation methods and the 3pseudorotaxane structure of them was eluci-dated by FTIR, DTA and XRD characterizations. Inclusion complexes of β-CD and α,w-alkanedicarboxylate anions (DAn2-) were acquired by neutralizing β-CD/DAn different inclusion complexes with sodium hydrox-ide and the structure was also proved to be a pseudorotaxane structure by 1H-NMR spectra and NOESY spectrum. Both the inclusion complexes of β-CD/DAn and β-CD/DAn2- adopt the 3pseudorotaxane structure with β-CD arranged in dimers threaded onto one aliphatic chain and the binding mode of 1:1 inclusion complex was excluded based on the consideration of chain conformations     

Photophysics of a cyanine dye within cyclodextrin cavity

The modulated photophysical and dynamical behavior of a potent anti-tumor photosensitizer 3,3^/-diethyloxadicarbocyanine iodide (DODCI) following host-guest inclusion complex formation with α-, β- and γ-Cyclodextrins (CDs) has been studied using steady-state and time-resolved spectroscopic methods. The cavity size of the CDs (α-CD <β-CD <γ-CD) is argued to play an instrumental role underlying the formation of the host-guest inclusion complex. While negligible interaction with α-CD is found to be succeeded by prominent quenching of monomeric fluorescence of the dye within β-CD and γ-CD with the degree of quenching being greater within γ-CD. The most appealing fact attained from the experimental results is the anticipation of dimer formation of DODCI within the large cavity of γ-CD which can entrap more than one molecule of DODCI. The steady-state results are found to be adequately corroborated by time-resolved fluorescence decay studies. Such encapsulation of the cyanine dye within the carrier cargo can be designed for targeted delivery inside biological systems.     

Enrofloxacin inclusion complexes with cyclodextrins

Inclusion complexes using α-, β-, γ-, and hydroxypropyl-β-CD (HP-β-CD) were produced with the antibiotic enrofloxacin, with the aim of increasing its solubility by complexation. Phase solubility diagrams were obtained, to confirm the formation of inclusion complexes, and to determine the solubility enhancement and stability constant of each complex. Enrofloxacin inclusion in β-CD showed the highest value of the complex stability constant (35.56?mmol?L^?1), but the greatest increase in solubility was obtained using HP-β-CD reaching a 1258% increase over enrofloxacin solubility in the absence of CD. The order of highest enrofloxacin solubility achieved was: HP-β-CD?>?α-CD?>?γ-CD?>?β-CD. In addition, formation of complexes was confirmed by differential scanning calorimetry and thermogravimetry, applied to the complexes obtained by the kneading technique. The influence of citric acid, alone or as an adjunct of β-CD, on the solubility of enrofloxacin was also determined. A solution of 15?mmol?L^?1 citric acid dissolved 10?g?L^?1 of enrofloxacin, but a gradual increase in β-CD concentration in the presence of citric acid did not increase the degree of solubilization of enrofloxacin.     

A comparative study of complexation of enalapril with α-, β- and γ-cyclodextrins in aqueous medium: structure elucidation of inclusion complexes using NMR spectroscopic and molecular mechanics methods

Structural studies of complexes of enalapril maleate with α-, β- and γ-cyclodextrins were carried by NMR spectroscopy and computational methods. The formation of complexes of enalapril with all the three cyclodextrins was established by chemical shift changes observed in the cavity protons of cyclodextrins in the presence of enalapril maleate. The stoichiometry of the complexes was determined to be 1:1 by ¹H NMR titrations studies using Scott’s method. Intermolecular cross peaks observed in the 2D ROESY spectra of mixtures of enalapril maleate with three cyclodextrins helped in establishing the probable structures of these inclusion complexes which were supported by molecular mechanics (MM2) studies. Enalapril forms 1:1 inclusion complex with all the studied cyclodextrins through aromatic ring. The mode of approach of aromatic ring to the α-cyclodextrin cavity was found to be different from those of β- and γ-cyclodextrins, which were identical.     

Effect of the ring size and asymmetry of cyclodextrins on their inclusion ability: a theoretical study

Effect of the ring size and asymmetry upon methylation of cyclodextrins (CDs) on their inclusion ability has been demonstrated for the inclusion complexes of native α-, β-, γ-CDs, dimethylated β-CD (DIMEB) and trimethylated β-CD (TRIMEB) with piperazine (PIZ) by PM3 and ONIOM calculations. In all complexes, PIZ prefers residing mostly in the central CD cavity. The complex stability in the order TRIMEB–PIZ > DIMEB–PIZ > α-CD–PIZ > γ-CD–PIZ > β-CD–PIZ indicates that the CD-ring asymmetry promotes the macrocycle deformation and inclusion ability. Our calculation results suggest that the inclusion complexes of both native and methylated CDs with PIZ in the gas phase are energetically stable, in addition to the β-CD–PIZ inclusion complex that has been evidenced thus far by X-ray crystallographic and spectroscopic analyses. Further calculations in the presence of water and adjacent CD molecules show that the increased intermolecular hydrogen bond interactions enhance the stability of β-CD–PIZ complex.     

Microenvironmental effects of cyclodextrins I: Enhancement of intramolecular excimer formation of polymethylene-bisβ-naphthoate via inclusion with cyclodextrins

The effects of α-, β- and γ-cyclodextrins (CDs) on the fluorescence spectra of a series of polymethylene-bis-β-naphthoates (Bn) have been studied. It is observed that β-CD and γ-CD enhance Bn intramolecular excimer fluorescence, indicating the formation of two-to-one guest host inclusion complexes. The possible conformation of these inclusion complexes is discussed.     

Theoretical investigation study based on PM3MM and ONIOM2 calculations of β-Cyclodextrin complexes with diphenylamine

The inclusion complex of β-cyclodextrin (β-CD) and diphenylamine (DPA) was investigated by using PM3MM, DFT, HF and ONIOM2 methods. The most stable structure was obtained at the optimum position and angle. The results indicate that the inclusion complex formed by DPA entering into the cavity of β-CD from its wide side (the secondary hydroxyl group side) is more stable than that formed by DPA entering into the cavity of β-CD from its narrow side (the primary hydroxyl group side). The structures show the presence of several intermolecular hydrogen bond interactions that were studied on the basis of natural bonding orbital (NBO) analysis, employed to quantify the donor–acceptor interactions between diphenylamine and β-CD. A study of these complexes in solution was carried out using the CPCM model to examine the influence of solvation on the stability of the diphenylamine β-CD complex.     

Novel pyrrolo-quinazolino-quinoline analogues of the natural alkaloids and their inclusion molecular complexes in the native cyclodextrins: experimental versus theoretical study

A series ten novel analogs based on a novel template pyrrolo-quinazolino-quinolines, containing Luotonin-A (Luot-A) and 14-aza-camptothecin (14-aza-CPT) molecular core as well as their inclusion complexes in the native α- (α-CD), β- (β-CD) and γ- (β-CD) cyclodextrins were obtained. The physical properties of the alkaloids and corresponding molecular complexes with cyclodextrins are elucidated experimentally by the electronic absorption and CD-spectroscopy, electrospray ionization and matrix-assisted laser desorption/ionization mass spectrometry and nuclear magnetic resonance method. The experimental data are supported by the theoretical quantum chemical calculations of the molecular and electronic structures as well as physical properties in condense phase.