Competitive Binding of Tolmetin to β-Cyclodextrin and Human Serum Albumin: <Superscript>1</Superscript>H NMR and Fluorescence Spectroscopy Studies

The host–guest interaction of tolmetin (TOL) with β-cyclodextrin (β-CD) and the influence of human serum albumin (HSA) on the formation of the inclusion complex were studied by 1D and 2D NMR spectroscopy. The TOL/β-CD inclusion complex formed at a molar ratio of 1:1 with a binding constant value of 2164.5 L·mol^?1. Data analysis showed that the addition of 10 μmol·L^?1 of HSA weakened the strength of TOL binding to β-CD (K _a = 1493 L·mol^?1). The interaction of TOL with HSA in the absence and presence of β-CD was studied by analyzing the fluorescence quenching data. The Stern–Volmer quenching constants and the binding constants are found to be smaller in the presence of β-CD, suggesting that β-CD hinders the strong interaction of TOL with HSA by complex formation. Additionally, the presence of β-CD does not induce conformational and microenvironmental changes on HSA.     

Influence of the glucosylated β-cyclodextrin inclusion on sulfur trioxide spin-adduct stabilizations and spin-trapping rate processes for DMPO-type spin traps

The effect of CD-inclusion on spin-trapping rates and spin-adduct decay rates for sulfur trioxide radical anion (SO₃ ^??) was investigated. SO₃ ^?? radical was produced with UV photolysis of sodium sulfite in basic aqueous solution, and spin-trapped with various spin traps, i.e., PBN (α-phenyl-N-t-butylnitrone), DMPO (5,5-dimethyl pyrroline-1-oxide), and three other phosphoryl DMPO-type spin traps. A modified β-CD, 6-O-α-d-glucosyl-β-cyclodextrin (G-β-CD) having better inclusion properties than β-CD, was employed. Upon adding excess G-β-CD, decay rates of SO₃ ^?? radical adducts significantly decreased in most spin traps. Half-lives of SO₃ ^?? radical adducts of phosphoryl spin traps were one to two orders of magnitude longer than that of PBN or DMPO, and the G-β-CD addition further extended the half-life time. The spin traps containing phosphoryl-group all showed higher SO₃ ^?? trapping rates than those of PBN and DMPO, but two phosphoryl spin traps achieved slower trapping rates by G-β-CD addition. In addition, the structures of CD-inclusion complexes of spin traps were established by means of 1D and 2D NMR measurements. Based on the results, the influences of inclusion on the spin-trapping rate processes and spin-adduct stabilizations were discussed. We conclude that substituents in DMPO-type spin traps may be modified to provide best spin-trapping capabilities in the presence or absence of CD.     

On the formation of arseno aminoxyls (nitroxides) by spin trapping of arseno radicals

The ·AsO₂ radical is detected by spin trapping using 2-methyl-2-nitrosopropane producing a new aminoxyl spin adduct. As0₄·^2? is trapped as an oxygen-centered radical by phenyl $\text{tert}$-butyl nitrone.     

Kinetic studies on the thermal dissociation of β-cyclodextrin-cinnamyl alcohol inclusion complex

The stability of β-cyclodextrin-cinnamyl alcohol inclusion complex (β-CD·C₉H₁₀·8H₂O) was investigated using TG and DSC. The mass loss took place in three stages: the dehydration occurred between 50–120°C; the dissociation of β-CD·C₉H₁₀O occurred in the range of 210–260°C; and the decomposition of β-CD began at 280°C. The dissociation of β-CD·C₉H₁₀O was studied by means of thermogravimetry, and the results showed: the dissociation of β-CD·C₉H₁₀O was dominated by a two-dimensional diffusion process (D₂). The activation energyE was 161.2 kJ mol^?1, the pre-exponential factorA was 4.5×10¹³ min^?1. Cyclodextrin is able to form inclusion complexes with a great variety of guest molecules, and the interesting of studies focussed on the energy binding cyclodextrin and the guest molecule. In this paper, β-cyclodextrin-cinnamyl alcohol inclusion complex was studied by fluorescence spectrophotometry and infrared absorption spectroscopy, and the results show: the stable energy of inclusion complexes of β-CD with weakly polar guest molecules consists mainly of Van der Waals interaction.     

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.     

Characterization of titanium dioxide photoactivity following the formation of radicals by EPR spectroscopy

In order to find ways to characterize oxygen-saturated aqueous TiO₂ suspensions, the formation of photo-induced free radicals was followed by EPR spectroscopy, using as indicators N-oxide and nitrone spin trapping agents, 5,5-dimethyl-1-pyrroline N-oxide (DMPO), 3,3,5,5-tetramethyl-1-pyrroline N-oxide (TMPO), α-(4-pyridyl-1-oxide)-N-tert-butylnitrone (POB N), 4-(N-methylpyridyl)-N-tert-butylnitrone (MePyBN), as well as semi-stable free radicals, 4-hydroxy-2,2,6,6-tetramethylpiperidine N-oxyl (TEMPOL), cation radical of 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid), diammonium salt (ABTS) and 1,1-diphenyl-2-picrylhydrazyl (DPPH). DMPO and TMPO are efficiently oxidized to the EPR-silent products via radical in termediates. Conversely, the nitrone spin traps (POBN and MePyBN) showed selective formation of hydroxyl radical spin adducts upon continuous irradiation of oxygenated TiO₂ suspensions. Their concentrations increased proportionally with the amount of photocatalyst and irradiation time. The EPR spectrum of the semi-stable free radicals TEMPOL, ABTS^·+ or DPPH is gradually eliminated during irradiation, and this system represents a simple technique for the evaluation of TiO₂ activity.     

Water-insoluble β-cyclodextrin polymer crosslinked by citric acid: synthesis and adsorption properties toward phenol and methylene blue

Water-insoluble β-cyclodextrin polymer (β-CDP) crosslinked by citric acid was obtained with a yield of 65% through an environment friendly synthesis procedure. FT-IR spectra disclosed that the hydroxyl groups of β-CD had reacted and condensated with the carboxyl groups of citric acid, and at the same time the structural characteristics of β-CD were essentially maintained in β-CDP. The β-CDP exhibited notable adsorption capability toward phenol (q _max = 13.8 mg g^?1) and especially large adsorption capability toward methylene blue (q _max = 105 mg g^?1). The concentration of methylene blue in water could be reduced to 0.11 mg L^?1 by the β-CDP, indicating the excellent adsorption sensitivity of β-CDP toward methylene blue. The adsorption results disclosed that the interior cavity and inclusion property of β-CD were maintained in the synthesized β-CDP.     

β-Cyclodextrin Inclusion Complexes of 2-Hydroxyfluorene and 2-Hydroxy-9-fluorenone: Differences in Stoichiometry and Excited State Prototropic Equilibrium

We report that 1:1 and 1:2 complexes are formed for 2-hydroxy-9-fluorenone with β-cyclodextrin (β-CD) and that there is an unusual red shift in emission at higher concentrations of β-CD. Between different stoichiometries of the complexes the titrimetric curves for the neutral–anionic equilibria for the guests differ drastically and so do the excited state pK values. The formation of an 1:1 inclusion complex with 2-hydroxy-9-fluorenone (2HFN) as the guest in β-CD with the binding constant (K) of 606.65 L·mol^?1 was determined. The ground and excited state pK _a values for the neutral–mono-anion equilibrium are not affected by β-CD. Hence the hydroxyl group is considered exposed in the aqueous environment. Two different types of inclusion complexes of 2HFN were observed in β-CD. The 1:2 complex of 2HFN shows a red shift from the 1:1 complex and is less fluorescent that the 1:1 complex. The red shift reveals that the 1:2 complex is more stabilized than the 1:1 complex. The excited state pK _a values in both complexes with β-CD are higher that those in aqueous solution. This shows that the complexation makes the molecule less acidic in the S1 state. The β-CD molecule is perceived as not able to encapsulate the 2HFN molecule fully, but the larger rim of the β-CD comes closer to the C=O group. The other half of the 2HFN molecule is encapsulated by the second β-CD molecule and thus there is formation of the 1:2 inclusion complex at higher concentrations of β-CD.     

Effect of pH and α-, β- and γ-cyclodextrin on the spectral properties of etoricoxib: spectroscopic and molecular dynamics study

The spectral properties of etoricoxib (ETR) at pH 2.0, 6.0 and 10.0 in the presence of cyclodextrins (CDs) were investigated. The absorption spectrum of ETR in acidic medium exhibited two bands centered at 236 and 273 nm, while in basic medium it exhibited two bands centered at 236 and 285 nm. No change in the spectrum was observed in the presence of CDs. The fluorescence emission spectra of ETR in acidic and basic media exhibited one band at 380 nm and another one at 484 nm. The emission band at 484 nm was enhanced when ETR was complexed with β-CD and γ-CD at pH 2.0, 6.0 and 10.0, while the band at 380 nm was enhanced selectively when ETR was complexed with α-CD at pH 2.0. Molecular dynamics simulations computations revealed that at pH 2.0, the sulfonyl moiety of H₂ETR²⁺ is preferentially included within the α-CD cavity, which is believed to cause the enhancement of the band at 380 nm. Moreover, at pH 6.0 and 10.0, the enhancement of the band at 484 nm was related to the inclusion of the chloropyridinyl and methylpyridinyl groups of the bipyridine moiety of HETR⁺ and ETR within β-CD and γ-CD cavities. Benesi–Hildebrand analysis showed that the ETR/β-CD complex adopts a 1:1 stoichiometry with association constant of K ₁₁?=?64.8 at pH 2.0, K ₁₁?=?105.4 at pH 6.0 and K ₁₁?=?520.5 at pH 10.0.     

Cationic cyclodextrins chemically-bonded chiral stationary phases for high-performance liquid chromatography

Two covalently bonded cationic β-CD chiral stationary phases (CSPs) prepared by graft polymerization of 6^A-(3-vinylimidazolium)-6-deoxyperphenylcarbamate-β-cyclodextrin chloride or 6^A-(N,N-allylmethylammonium)-6-deoxyperphenylcarbamoyl-β-cyclodextrin chloride onto silica gel were successfully applied in high-performance liquid chromatography (HPLC). Their enantioseparation capability was examined with 12 racemic pharmaceuticals and 6 carboxylic acids. The results indicated that imidazolium-containing β-CD CSP afforded more favorable enantioseparations than that containing ammonium moiety under normal-phase HPLC. The cationic moiety on β-CD CSPs could form strong hydrogen bonding with analytes in normal-phase liquid chromatography (NPLC) to enhance the analytes’ retention and enantioseparations. In reversed-phase liquid chromatography (RPLC), the analytes exhibited their maximum retention when the pH of mobile phase was close to their pK_a value. Inclusion complexation with CD cavity and columbic/ionic interactions with cationic substituent on the CD rim would afford accentuated retention and enantioseparations of the analytes.     

Characterization of inclusion complex of vitamin E compound with 2,6-di-O-methylated β-cyclodextrin as the solubility enhancer and its kinetic determination for radical scavenging ability

The structure of the inclusion complex of α-tocopherol (vitamin E compound) with 2,6-di-O-methylated β-cyclodextrin (DM-β-CD) was characterized by 2D ROESY NMR measurements, suggesting that DM-β-CD includes the side-chain moiety of α-tocopherol. The inclusion complexation of DM-β-CD showed the usefulness of water solubilizer for the radical scavenging assay of vitamin E compounds in aqueous solution. Using the electron paramagnetic resonance (EPR) competitive spin trapping method, we determined the oxygen radical (RO^?) scavenging abilities of seven vitamin E compounds (tocopherols and tocotrienols), which were solubilized by DM-β-CD in water. The order of the RO^? radical scavenging abilities for vitamin E compounds solubilized by DM-β-CD are α- > β- ≈ γ- > δ-, which is in agreement with the oxidation potential values of antioxidants. It is noted that the RO^? radical scavenging abilities of tocotrienols are comparable to those of tocopherols. Based on the results, the mechanism of the antioxidant reaction of vitamin E compounds with the RO^? radical is discussed.     

Inclusion complexes of melatonin with modified cyclodextrins

The solubility of melatonin (MT) was improved with the addition of modified cyclodextrins (CDs). The solubilities of MT in the presence of β-cyclodextrin (β-CD), hydroxypropyl-β-cyclodextrin (HP-β-CD), mono-6-O-maltosyl-β-cyclodextrin (mono-G₂-β-CD), methyl-β-cyclodextrin (Me-β-CD), and sulfobutylether-β-cyclodextrin (SBE-β-CD) were higher than that of MT itself. In particular, the solubility of MT in the presence of SBE-β-CD was 11 times higher than that of MT itself. The stability constant (K) obtained based on the fluorescence intensity was 490 L/mol for the MT/SBE-β-CD inclusion complex. The structure of the MT/SBE-β-CD complex in aqueous solution was examined by ¹H–¹H rotating frame nuclear overhauser effect spectroscopy NMR. A 5-methoxy moiety of MT was included from the secondary hydroxyl face of SBE-β-CD. The MT/SBE-β-CD inclusion complex was prepared by the freeze-drying method. The results of X-ray diffraction and differential scanning calorimetry confirmed the formation of the complex in solid.     

Crystal Structures of β-Cyclodextrin Complexes with Formic Acid and Acetic Acid

β-Cyclodextrin (β–CD)-formic acid (1) andβ-CD–acetic acid (2) inclusion complexes crystallizeas β-CD...0.3HCOOH...7.7H₂O andβ-CD...0.4CH₃COOH...7.7H₂O in themonoclinic space group P2₁ with comparable unit cell constants.Anisotropic refinement of atomic parameters against X-ray diffractiondata with F_o ² > 2σ (F_o ²) (986/8563 and 991/8358)converged at R-factors of 0.051 and 0.054 for 1 and 2,respectively. In both complexes, the β-CD molecularconformation, hydration pattern and crystal packing are similar,but the inclusion geometries of the guest molecules are different.The β-CD macrocycles adopt a ``round'' conformationstabilized by intramolecular, interglucose O3(n)...O2(n + 1)hydrogen bonds and their O6–H groups are systematically hydratedby water molecules. In the asymmetric unit, each complex contains oneβ-CD, 0.3 formic acid (or 0.4 acetic acid), and 7.7 water moleculesthat are distributed over 9 positions. Water sites located in theβ-CD cavity hydrogen bond to the guest molecule. In thecrystal lattice, β-CD molecules are packed in a typical ``herringbone'' fashion. In 1, the formic acid (occupancy 0.3) is entirely included in the β-CD cavity such that its C atom is shifted from the O4-plane center to the β-CD O6-side by 2.90 Å and C=O, C–-O bonds point to this side. In 2, the acetic acid (occupancy 0.4) is completely embedded in the β-CD cavity, in which the carboxylic C atom is displaced from the O4-plane centerto the β-CD O6-side by 0.87 Å; the C=O bond directsto the β-CD O6-side and makes an angle of 15°to the β-CD molecular axis. Furthermore, bothdimethyl-β-CD-acetic acid and β-CD-acetic acidcomplexes form a cage structure, showing that the small guestsenclosed entirely in the cavity either in β-CD or indimethyl-β-CD do not affect the packing of the host macrocycles.     

Study on the inclusion interaction of ethyl violet with cyclodextrins by MWNTs/Nafion modified glassy carbon electrode

The interactions of ethyl violet (EV) with cyclodextrins (CDs) were investigated by Multi-wall carbon nanotubes/Nafion composite film modified glassy carbon electrode (MWNTs/Nafion/GCE). It was found that the MWNTs/Nafion composite film can effectively catalyze the electrode reaction of EV. The variation of the electrochemical behavior of EV upon the addition of CDs indicated the formation of the inclusion complexes of EV with β-CD, heptakis (2,3,6-tri-O-methyl)-β-CD (TM-β-CD), heptakis (2,6-di-O-methyl)-β-CD (DM-β-CD), hydroxypropyl-β-CD (HP-β-CD), and carboxymethyl-β-CD (CM-β-CD). The stoichiometry ratios of EV and the above five CDs were found to be 1:1. The inclusion ability obeyed the order: CM-β-CD > HP-β-CD > TM-β-CD > DM-β-CD > β-CD. The results showed that the modified β-CDs exhibited stronger binding ability than native β-CD, especially the charged CM-β-CD, which implied that the inclusion capacity depends on not only size matching and hydrophobicity but also electrostatic interaction. ¹HNMR spectra and molecule mechanics calculations suggested that EV was included into the cavity of β-CD from the wider side.     

Examination of intermolecular interaction as a result of cogrinding actarit and β-cyclodextrin

In this study, investigations were performed in regard to the possibility of complexation of actarit (ACT) with β-cyclodextrin (β-CD) for improving the solubility and dissolution rate. Complexes of β-CD and ACT (ACT/β-CD molar ratio = 1/1) were prepared using the cogrinding method. Formation of an ACT/β-CD inclusion complex by cogrinding was confirmed using powder X-ray diffraction measurement. The powder X-ray diffraction of the ground mixture (ACT/β-CD = 1/1) showed a halo pattern. The diffraction pattern of the ground mixture after storage at RH 82 %, 40 °C exhibited new diffraction peaks at 2θ = 11.6º and 17.8º, and differed from those of ACT and β-CD crystals. In vitro studies showed that the solubility and dissolution rate of ACT were significantly improved by complexation with β-CD with respect to the drug alone. In ¹H-NMR measurement, changes in chemical shift (1H) suggested that the drug phenyl moiety was included in the cavities of β-CD mainly by hydrophobic interaction, and that the primary hydroxy side of β-CD was tightly associated with each drug. The results show clear evidence of intermolecular interaction between β-CD and ACT.     

Synthesis and structural characterization of 18-, 19-, 20- and 22-membered Schiff base macrocycles

The complexation parameters of dipyridamole (Dipy) with β-cyclodextrin (β-CD) were investigated by using several techniques including phase solubility diagrams (PSD), proton nuclear magnetic resonance (¹H-NMR), x-ray powder diffractometry (XRPD), differential scanning calorimetry (DSC), scanning electron microscopy (SEM) and molecular mechanical modeling (MM⁺). From the pH-solubility profiles, two basic pK _as at 6.4 and 2.7 were estimated. The linear correlation of the free energy of Dipy/β-CD complex formation (ΔG ₁₁) with the corresponding free energy of inherent Dipy aqueous solubility (ΔG _So), obtained from the linear variation of ln K ₁₁ with that of the inherent Dipy solubility (ln S _o) at different pHs and ionic strengths, was used to measure the contribution of the hydrophobic character of Dipy to include into the hydrophobic β-CD cavity. Complex formation of Dipy was driven by favorable enthalpy (ΔH° = ?14.8 kJ/mol) and entropy (ΔS° = 31.9 J/mol K) factors. ¹H-NMR and molecular mechanical modeling studies indicate the formation of different isomeric 1:1 and 1:2 complexes, where both the piperidine and diethanolamine moieties get separately included into the β-CD cavity. Molecular mechanical modeling computations indicate that the dominant driving force for complexation is Van der Waals with lower contribution from electrostatic interactions. ¹H-NMR and XRPD, DSC, SEM studies of isolated solid complexes indicate the formation of inclusion complexes in aqueous solution.     

Electroanalytical method of TCPP and its supramolecular system with cyclodextrins

In this paper, electroanalytical method of tetrakis (4-carboxylphenyl) porphyrin (TCPP) has been established. In a supporting electrolyte of KH₂PO₄-Na₂HPO₄ (pH 7.0), a sensitive second derivative reduction peak of TCPP was found by single-sweep oscillopolarography. The potential peak is −0.70 V (versus SCE).The relationship between peak height and the concentration of TCPP is linear from 1×10⁻⁷ to 2×10⁻⁵ mol l⁻¹, the relative standard deviation (R.S.D.) was 0.41% (n=8), and the recovery of TCPP varied from 95.8-105.4%.The interaction of cyclodextrins (CD) with TCPP in NH₃-NH₄Cl (pH 8.0) has been studied by polarography. The TCPP can form the 1:1 inclusion complex with β-CD, γ-CD, hydroxylpropyl-β-CD, sulfurbutylether-β-CD and trimethyl-β-CD. “Current method” has been used to determine the formation constants of TCPP with five CDs. The result shows that the inclusion ability of hydroxylpropyl-β-CD is very strong. Moreover, modified β-CD has stronger inclusion capacity than native β-CD. The formation constant of TCPP with γ-CD is much greater than that of TCPP with β-CD, because the γ-CD has a bigger cavity that can match with the size of the meso-phenyl of TCPP. The supramolecular data will provide useful information for further application of TCPP.     

Inclusion complex of usnic acid with β-cyclodextrin: characterization and nanoencapsulation into liposomes

In this study β-cyclodextrin (β-CD) was used to improve usnic acid (UA) solubility and the inclusion complex (UA:β-CD) was incorporated into liposomes in order to produce a targeted drug delivery system for exploiting the antimycobacterial activity of UA. A phase-solubility assay of UA in β-CD at pH 7.4 was performed. An apparent stability constant of K_1:1 = 234.5 M^?1 and a complexation efficiency of 0.005 was calculated. In the presence of 16 mM of β-CD the solubility of UA (7.3 μg/mL) increased more than 5-fold. The UA:β-CD complex was prepared using the freeze-drying technique and characterized through infrared and ¹HNMR spectroscopy, X-ray diffraction and thermal analyses. The UA:β-CD inclusion complex presented IR spectral modifications when compared with UA and β-CD spectra. ¹HNMR spectrum of UA:β-CD inclusion complex showed significant chemical shifts in proton H5 located inside the cavity of β-CD (Δδ = 0.127 ppm), suggesting that phenyl ring moiety of UA would be expected to be included within the β-CD cavity, interacting with the H-5 proton. A change in UA from its crystalline to amorphous form was observed on X-ray, suggesting the formation of a drug inclusion complex. DSC analysis showed the disappearance of the UA fusion peak UA:βCD complex. No differences between the antimicrobial activity of free UA and UA:βCD were found, supporting the hypothesis that the complexation with cyclodextrin did not interfere with drug activity. Liposomes containing UA:βCD were prepared using hydration of a thin lipid film method with subsequent sonication. Formulations of liposomes containing UA:βCD exhibited a drug encapsulation efficiency of 99.5% and remained stable for four months in a suspension form. Interestingly, the encapsulation of UA:βCD into the liposomes resulted in a modulation of in vitro kinetics of release of UA. Indeed, liposomes containing UA:β-CD presented a more prolonged release profile of free usnic acid compared to usnic acid-loaded liposomes.     

Thermodynamic studies on water-β-cyclodextrin-surfactant ternary systems

Conductance measurements are reported for double chain surfactants like N,N,N-octylpentyldimethylammonium (OPAC) and N,N,N-octyloctyldimethylammonium chlorides (OOAC) in water-β-cyclodextrin solution. From the specific conductivity data, the apparent critical micelle concentration (cmc¹) and the degree of counterion dissociation (β) were obtained at a fixed β-CD concentration (m_βCD = 0.01190 mol kg⁻¹, besides from the cmc¹ value and that in water (cmc) the stoichiometry of the surfactant-β-CD complex was calculated. Densities, heat capacities, enthalpies of dilution at 298 K and osmotic coefficients at 310 K were measured for the same systems; the apparent molar volumes, V_λ, and heat capacities, C_λ, of two surfactants in β-CD solution, calculated as functions of surfactant concentrations m_s, have made possible to obtain the properties of transfer of the surfactant from water to β-CD-water solutions.     

Inclusion complexes of rosmarinic acid and cyclodextrins: stoichiometry,association constants,and antioxidant potential

The interaction between β-cyclodextrin (β-CD) and the polyphenol rosmarinic acid (RA) is here reported by ¹H NMR titration experiments. The formation of an aqueous soluble inclusion complex is confirmed and valuable information regarding mode of penetration of guest into β-CD, stoichiometry, and stability of the complex is obtained. The analysis by the continuous variation method shows the undoubted formation of 1:1 β-CD/RA complex. Additionally, the estimated apparent association constants reveal the importance of the asymmetry of the RA in the complexation; the incorporation of the catechol moiety closer to the carboxylic group is more favorable (K?=?2,028 M^?1) than from the other end of the RA molecule (K?=?1,184 M^?1). Finally, we have also investigated the antioxidant activity and storage stability of the β-CD/RA complexed system; the presence of β-CD was found to produce a remarkable enhancement on the antioxidant activity.