Electrochemical study of indapamide and its complexation with ��-cyclodextrin

Electrochemical oxidation of indapamide has been investigated at glassy carbon electrode using cyclic and differential pulse voltammetry (DPV). Indapamide exhibited two well resolved signals which attributed to the oxidation of indoline ring and benzamide moiety in phosphate buffers in the pH range of 2.7?C10.1. The oxidation processes have been shown to be irreversible and diffusion controlled. The formation of an inclusion complex of indapamide with ??-cyclodextrin (??-CD) has been investigated by cyclic, differential pulse voltammetry as well as UV?CVis spectrophotometry. The stability constant of the complex was determined to be 6199 and 2717 M^?1 using differential pulse voltammetry and UV?CVis spectrophotometry, respectively.     

Study of complexation of gliclazide with β-cyclodextrin in solution by nmr techniques

The study of complexation between GL and -CD in liquid medium has been carried out by phase-solubility,¹H and¹³C NMR studies. A formation complex is observed from the phase solubility diagram, being the average association constant of 1094 M^–1, The NMR studies revealed the preferent complexation of the aliphatic moiety of GL. The aromatic moiety is also entrapped, but in minor extent, by the CD molecules.     

Interaction of metal ions with biomolecular ligands: how accurate are calculated free energies associated with metal ion complexation?

To address fundamental questions in bioinorganic chemistry, such as metal ion selectivity, accurate computational protocols for both the gas-phase association of metal-ligand complexes and solvation/desolvation energies of the species involved are needed. In this work, we attempt to critically evaluate the performance of the ab initio and DFT electronic structure methods available and recent solvation models in calculations of the energetics associated with metal ion complexation. On the example of five model complexes ([M(II)(CH(3)S)(H(2)O)](+), [M(II)(H(2)O)(2)(H(2)S)(NH(3))](2+), [M(II)(CH(3)S)(NH(3))(H(2)O)(CH(3)COO)], [M(II)(H(2)O)(3)(SH)(CH(3)COO)(Im)], [M(II)(H(2)S)(H(2)O)(CH(3)COO)(PhOH)(Im)](+) in typical coordination geometries) and four metal ions (Fe(2+), Cu(2+), Zn(2+), and Cd(2+); representing open- and closed-shell and the first- and second-row transition metal elements), we provide reference values for the gas-phase complexation energies, as presumably obtained using the CCSD(T)/aug-cc-pVTZ method, and compare them with cheaper methods, such as DFT and RI-MP2, that can be used for large-scale calculations. We also discuss two possible definitions of interaction energies underlying the theoretically predicted metal-ion selectivity and the effect of geometry optimization on these values. Finally, popular solvation models, such as COSMO-RS and SMD, are used to demonstrate whether quantum chemical calculations can provide the overall free enthalpy (ΔG) changes in the range of the expected experimental values for the model complexes or match the experimental stability constants in the case of three complexes for which the experimental data exist. The data presented highlight several intricacies in the theoretical predictions of the experimental stability constants: the covalent character of some metal-ligand bonds (e.g., Cu(II)-thiolate) causing larger errors in the gas-phase complexation energies, inaccuracies in the treatment of solvation of the charged species, and difficulties in the definition of the reference state for Jahn-Teller unstable systems (e.g., [Cu(H(2)O)(6)](2+)). Although the agreement between the experimental (as derived from the stability constants) and calculated values is often within 5 kcal·mol(-1), in more complicated cases, it may exceed 15 kcal·mol(-1). Therefore, extreme caution must be exercised in assessing the subtle issues of metal ion selectivity quantitatively.     

The structure of 6,6′-biquinolyl and its dication in solution

Conformational analysis of 6,6-biquinolyl and its dication was performed using dipole moments and data from electric and magnetic birefringence. The rotation angles between the quinoline rings for thecis- andtrans-conformers in solution are 50°. The emergence of positive charges on both heteroaromatic rings does not result in noticeable changes in the spatial structure.Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 2, pp. 330–332, February, 1994.     

Electrochemical sensing in solution��origins, applications and future perspectives

The origins of electrochemical sensing in solution are briefly surveyed together with the potential advantages of potentiometric and voltammetric sensors and biosensors. Selected applications and current trends are illustrated, and future perspectives are discussed.     

The complexation of flurbiprofen with β-cyclodextrin: a NMR study in aqueous solution

The complexation process between racemic flurbiprofen and β-cyclodextrin in solution was investigated by 1D and 2D proton NMR spectroscopy. In the presence of β-cyclodextrin, the aromatic protons of flurbiprofen were the most affected, suggesting a strong involvement of the phenyl groups in the inclusion mechanism. The stoichiometry of the complex was determined by the method of continuous variation, using the chemical induced shifts of both host and guest protons. The association constant, K_a of the obtained complex was calculated and found to be 2483.8 M^?1. On the other hand, signals belonging to the protons associated with the carboxyl group are split in the presence of β-cyclodextrin indicating enantiomeric differentiation. Rotating frame NOE spectroscopy, (ROESY), was used to ascertain the solution geometry of the host–guest complex. The result suggested that the flurbiprofen molecule fully penetrates the β-cyclodextrin cavity with the carboxyl group protruding from the primary hydroxyl side and the phenyl group close to the secondary rim.     

Study of complexation of alkyl-substituted 2,2′-dipyrrolylmethene with lanthanide salts by electronic spectroscopy

It has been found with the use of electronic spectroscopy that the reaction of alkyl-substituted 2,2′-dipyrrolylmethene with La(III), Pr(III), Sm(III), Dy(III), Ho(III), Er(IIII), and Yb(III) salts leads to the formation of tris(dipyrrolylmethene) complexes. Based on electronic absorption spectroscopy data and formation constants of lanthanide complexes, together with the earlier data, analysis of the nature of M-L bonds in 2,2′-dipyrrolylmethene chelates with p, d, and f elements has been performed. A correlation was found between the complex stability and the polarizing action of the complex-forming ion on the chromophore π system of dipyrrolylmethene, which allows one to classify these heterocyclic ligands with probes highly sensitive to the change in the ratio between the ionic and covalent contributions to coordination interactions.     

The shape of protein–polymer conjugates in dilute solution

Protein–polymer conjugation can significantly affect many different aspects of protein behavior, ranging from their solution properties to their ability to form solution and bulk nanostructured materials. An underlying fundamental question is how the molecular design affects the shape of the conjugate and, consequently, its properties. This work measures the molecular configuration of model protein–polymer conjugates in dilute solution using small-angle neutron scattering (SANS) and uses quantitative model fitting to understand the shape of the molecules. Form factor measurements of four model bioconjugates of the red fluorescent protein mCherry and the polymers poly(N-isopropylacrylamide), poly(hydroxypropyl acrylate), poly(oligoethylene glycol acrylate), and poly(ethylene glycol) show that these protein–polymer conjugates are well described by a recently developed scattering function for colloid–polymer conjugates that explicitly incorporates excluded volume interactions in the polymer configuration. In the regime where the protein does not exhibit strong interactions with the polymer, modeling the protein–polymer interactions using a purely repulsive Weeks–Chandler–Andersen potential also leads to a coarse-grained depiction of the conjugate that agrees well with its scattering behavior. The coarse-grained model can additionally be used for systems with varying protein–polymer interactions, ranging from purely repulsive to strongly attractive, which may be useful for conjugates with strong electrostatic or hydrophobic attractive interactions. © 2015 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2016, 54, 292–302     

Quantum-chemical modeling of possible reactions of Roussin’s red esters with aryl ligands in DMSO solution

Possible reactions of Roussin’s red esters [Fe₂(μ-SC₆H₄R)₂(NO)₄], where R = H, o-NH₂, m-NO₂, m-OH, or m-NH₂, in DMSO solution were investigated by quantum chemical modeling. It was shown that in these systems, numerous reactions can occur, including NO donation, ligand substitution, and decomposition into mononuclear iron nitrosyl complexes. The resulting compounds are also NO donors.     

Thermodynamics of complexation of tauro- and glyco-conjugated bile salts with two modified ��-cyclodextrins

The interaction between two modified ??-cyclodextrins and bile salts, common for rat, dog and man, was studied using isothermal titration calorimetry. The structural differences in the interaction were investigated by ¹³C NMR. The two modified ??-cyclodextrins were chosen because of their frequent use as oral excipients in drug formulation and in marketed products. All the investigated bile salts had an affinity for the ??-cyclodextrins, although there were large variations in the stability constants. The variations in the enthalpic and entropic contributions to the overall Gibbs free energy revealed differences in the binding mode to the investigated bile salts, i.e. the bile salts with a hydroxyl group at C12 interacted differently than bile salts without this hydroxyl group. These observations were supported by ¹³C NMR, which suggested binding to the D-ring of the steroid structure for bile salts with a hydroxyl group at C12 and to the C-ring for the bile salts without this hydroxyl group. The type of substitution of ??-cyclodextrin had significant effects on the thermodynamics of the interaction where especially the entropic changed were affected.     

Inclusion complex formation of ��- and ��-cyclodextrins with riboflavin and alloxazine in aqueous solution: thermodynamic study

Possibility of encapsulation of riboflavin and alloxazine by ??- and ??-cyclodextrins in aqueous solution was studied by ¹H NMR and solubility methods. Thermodynamic parameters of 1:1 inclusion complex formation (K, ??_cG⁰, ??_cH⁰ and ??_cS⁰) were obtained and analyzed in terms of influence of reagent??s structure on complexation process. It was shown that ??-cyclodextrin displays low binding affinity to riboflavin and alloxazine. On the contrary, ??-cyclodextrin forms with riboflavin and alloxazine more stable inclusion complexes. Binding is accompanied by the negative enthalpy and entropy changes that are determined by predominance of van der Waals interactions and possible H-bonding. The presence of ribityl substituent in riboflavin molecule prevents the deep penetration of this compound into macrocyclic cavity. Proposed on the basis of ¹H NMR data the partial insertion of the hydrophobic part of riboflavin and alloxazine molecules into the ??-cyclodextrin cavity causes the enhancement of aqueous solubility of the encapsulated substances. In comparison with ??-cyclodextrin, the solubilizing effect of ??-cyclodextrin is more pronounced due to its higher binding affinity to alloxazine and riboflavin.     

Interaction of thorium(IV) with nitrate in aqueous solution: medium effect or weak complexation?

Microcalorimetric titrations were performed to study the Th(IV)/nitrate interaction in aqueous solution. The results show the formation of a weak mononuclear complex of Th(IV) with nitrate and allow the determination of the complexation thermodynamic parameters at 298 K and ionic strength 1.0 mol dm(-3). The reaction is endothermic and entropy driven. Data and comparison with similar actinide(IV) complexes allow to confirm the inner-sphere nature of the Th(NO(3))(3+) complex.     

Electrochemical characteristics of poly(ophenylendiamine) film electrodes in phosphatic solution

The electrochemical characteristics of poly(o-phenylendiamine) (POPD) film modified electrodes have been investigated using different electrochemical techniques.The main interest is focused on the effect of potential and film thickness on the electrode process.Good agreement has been found for the apparent diffusion coefficient estimated by chronocoulometry and impedance spec-troscopy.The charge transfer process within POPD films is diffusion processes at negative and positive overpotentials and electron hopping mechanism at formal potential.The POPD film conductivity of the oxidized state is better than that of the reduced state.For all electrode processes,the H+ may penetrate the film/electrolyte interface and take part in charge transfer or protonation-deprotonation of phenazine rings.     

Electrochemical corrosion of thin ferromagnetic Fe—N films in neutral solution

A model experiment was conducted in order to determine an interplay between inherent strains and electrochemical corrosion rate in nitrogen-doped iron thin films. 150 and 300 nm thick films, used in the experiment, were obtained by means of DC magnetron sputtering. In order to study the influence of substrate on inherent strains in metal, these films were deposited onto flexible polymer and rigid glass substrates. It was found, that the rigidity of the substrate increased the corrosion rate of thin iron films in a neutral electrolytic solution. It was proven using X-ray diffraction, that the greater rigidity was, the stronger were the internal strains within the films. That effect was especially pronounced in thinner films, where the increase in the rate of dissolution was accompanied by a localization of corrosion. Characteristics of electrochemical processes were measured using a three-electrode cell. The comparison of the films free surface energy was performed by measuring water contact angle.     

Welding dynamics in an atomistic model of an amorphous polymer blend with polymer–polymer interface

We consider an atomistic model of thermal welding at the polymer-polymer interface of a polyetherimide/polycarbonate blend, motivated by applications to 3D manufacturing in space. We follow diffusion of semiflexible chains at the interface and analyze strengthening of the samples as a function of the welding time t_w by simulating the strain–stress and shear viscosity curves. The time scales for initial wetting, and for fast and slow diffusion, are revealed. It is shown that each component of the polymer blend has its own characteristic time of slow diffusion at the interface. Analysis of strain–stress demonstrates saturation of the Young's modulus at t_w = 240 ns, while the tensile strength continues to increase. The shear viscosity is found to have a very weak dependence on the welding time for t_w > 60 ns. It is shown that both strain–stress and shear viscosity curves agree with experimental data.     

An investigation of the complexation of a TTF derivative with α-, β- and γ-cyclodextrins in aqueous media

This Letter, describes the complexation of α-, β- and γ-cyclodextrins (1-3) with TTF derivative 4 in water. In particular, we show using ¹H, ¹³C NMR, UV-vis spectroscopy and isothermal titration calorimetry that β-cyclodextrin 2 forms an effective complex with 4. Complex 2·4 can be conveniently disassembled upon the addition of 1-adamantanol.     

Monte Carlo simulation of phase separation kinetics in a concentrated polymer solution

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