Enthalpy-Entropy Compensation in the Structure-Dependent Effect of Nonsteroidal Anti-inflammatory Drugs on the Aqueous Solubility of Diltiazem.

Certain combinations of acidic and basic drugs can cause significant changes in physicochemical properties through the formation of ionic liquids, eutectic mixtures, or deep eutectic solvents. In particular, combining indomethacin and lidocaine is known to result in apparent increases in both the partition coefficients (hydrophobicity) and aqueous solubilities (hydrophilicity). The physicochemical interactions between drugs change the water solubility of the drugs and affect the bio-availability of active pharmaceutical ingredients. Therefore, we need to clarify the mechanism of changes of water solubility of drugs through the physicochemical interactions. In the present study, we identified a thermodynamic factor that regulates the dissolution of a basic drug, in the presence of various acidic nonsteroidal anti-inflammatory drugs. The results demonstrated that enthalpy-entropy compensation plays a key role in the dissolution of drug mixtures and that relevant thermodynamic conditions should be considered.

Comparative study of the hydrophobic interaction effect of pH and ionic strength on aggregation/emulsification of Congo red and amyloid fibrillation of insulin.

Amyloid fibrillation is provoked by the conformational rearrangement of its source. In our previous study, we claimed that the conformational rearrangement of hen egg white lysozyme requires intermolecular aggregation/packing induced. Our proposed causality of the aggregation and amyloid formation was demonstrated by the quantitative dependence of amyloid fibrillation on pH difference from its isoelectric point (pI) and on the square root of ionic strength in order to reduce the intermolecular repulsion due to the shielding effect of electrolytes (DLVO effect). When Congo red has dianionic form at the pH higher than its pKa, it forms ribbon-like micelle colloids under lower ionic strength, while it loses electrostatic repulsion and aggregates to be emulsified in the octanolic phase under the higher ionic strength. These behaviors of Congo red were resembling to molecular assembly of surfactants. In contrast, the amyloid formation of insulin was proportional to the square root of ionic strength at the pH lower than its isoelectric point. Therefore, the trigger for conformational rearrangement of amyloid fibrillation is predominantly gripped by hydrophobic hydration and an electrostatic shielding effect. We concluded that the both behaviors of Congo red and insulin were derived from a driving force related to the hydrophobic hydration.

Stabilization of the Metastable α-Form of Indomethacin Induced by the Addition of 2-Hydroxypropyl-ß-Cyclodextrin, Causing Supersaturation (Spring) and Its Sustaining Deployment (Parachute).

The purpose of this study is to find that a small amount of 2-Hydroxypropyl-ß-cyclodextrin (HP-ß-CD) can produce a parachute effect on indomethacin (INM). From the examination of dissolution curves and concentration after several days, the supersaturation of INM was observed for the mixtures containing HP-ß-CD at a molar ratio ≤ 0.5, and the sustained deployment of supersaturation was found not only in equimolar mixtures but also in mixtures with a shortage of HP-ß-CD. In the solid state, it was compared the physical properties of INM/HP-ß-CD mixtures using two different mixing methods and determined the stoichiometry of INM and HP-ß-CD. Differential scanning calorimetry (DSC) revealed that the polymorphs of INM were converted by HP-ß-CD into an amorphous state. Furthermore, X-ray powder diffraction (XRPD) and DSC-XRPD demonstrated that INM crystals from the INM/HP-ß-CD mixture prepared from an EtOH solution were metastable. In conclusion, these phenomena may be considered the "spring" and "parachute" effects of mixtures with a shortage of HP-ß-CD, as they depended on the presence of the metastable α-form of INM. The addition of 1/3 to 1/20 equivalents of HP-ß-CD to INM enhanced INM solubility.

Leading individual features of antioxidant systematically classified by the ORAC assay and its single electron transfer and hydrogen atom transfer reactivities; analyzing ALS therapeutic drug Edaravone.

Many natural compounds mop up radicals and limit radical reactions and may prove useful in reducing or preventing oxidative stress-related diseases in vivo. Several assays have been developed to measure antioxidant or anti-radical activity. Here, we measured the anti-radical activities of representative antioxidants using different assays. The oxygen radical absorption capacity (ORAC) assay has two mechanistic stages. We classified antioxidant behavior using two characteristic values thought to be related to the two stages - peroxyl radical formation time (lag time) and fluorescein annihilation rate (k obs) - by applying Voronoi polyhedral division. We focused on four class-representative antioxidants, Trolox ®, vitamin C, l-cysteine, and 2,6-di­tert­butyl­p-cresol, and compared their characteristic activities with those of edaravone. Our analysis indicates that edaravone is in the same group as cysteine and may function via a similar mechanism. Our results suggest that analyzing lag time and k obs is a useful method to characterize antioxidants.

Effects of Heat Treatment on Indomethacin-Cimetidine Mixture; Investigation of Drug-Drug Interaction Using Singular Value Decomposition in FTIR Spectroscopy.

This study investigated the effect of phase transformation on indomethacin (IMC), cimetidine (CIM), and their 1:1 eutectic mixture, using FTIR spectra and multivariate analysis. The IMC form γ, CIM form A, and IMC-CIM 1:1 mixture molar ratio samples were heated on a hot plate at 303-453 K for 5 min and cooled till room temperature. The prepared samples were investigated by powder X-ray diffraction analysis and infrared spectroscopy with KBr powder. The PXRD patterns suggested the bulk IMC form γ, bulk CIM form A, and 1:1 physical mixture samples phase transformed into low-crystallinity IMC form γ, amorphous CIM, and eutectic mixture, respectively. FTIR spectra combined with singular value decomposition (SVD) suggested by absorbance peak shifts of several vibration modes that the polymorphic transformations of the samples affect their molecular interactions. The estimated melting points of heated samples were evaluated by sigmoid fitting based on the SVD results. The principal components of SVD show that the process of phase transformation of IMC-CIM 1:1 mixture samples affect the IR vibration of the CO stretch of IMC and the C-C stretch and C-H bending of CIM. These results suggest that molecular interaction is an important factor in the eutectic condition of IMC-CIM 1:1 mixture. This observation enables to evaluate for in co-amorphous formulations or stability of drug combinations in a poly pill.

Molecular recognizable ion-paired complex formation between diclofenac/indomethacin and famotidine/cimetidine regulates their aqueous solubility.

This study focused on the physicochemical interactions between acidic and basic drugs in aqueous solutions. Their ion pair interactions were evaluated in an in vitro study. The model non-steroid anti-inflammatory drugs (NSAIDs), indomethacin (INM) and diclofenac (DIC), were used as acidic and hydrophobic drugs, whereas cimetidine (CIM), famotidine (FAM), and imidazole (IMD) were used as basic additives with heterocyclic moieties. The drug mixtures were evaluated by thermal analysis, dissolution test, nuclear magnetic resonance (NMR) spectroscopy, and mass spectroscopy. The fusion enthalpy of DIC-CIM, INM-CIM, and INM-arginine (ARG) sample was calculated based on melting temperature transformation. The DIC mixture with CIM, IMD, antipyrine (ANT), and ARG showed enhanced solubility, whereas the DIC-FAM mixture sample showed a decreased solubility. Electrospray ionization mass spectroscopy was carried out to detect binary mixtures. The interactions in DIC-FAM mixture sample were found between the carboxyl group of DIC and the amine groups of FAM by NMR. These findings were suggested that DIC-FAM mixture samples construct ion pair complexes based on the theory of Bjerrum. Moreover, the acid model drug and basic model drug also can be constructed 1:1 complexes that affects their solubility in the solvent of water type.

Relationship Between Phase Solubility Diagrams and Crystalline Structures During Dissolution of Cimetidine/Cyclodextrin Complex Crystals.

Cyclodextrins (CDs) form complex crystals with drugs and improve physicochemical properties of drugs. However, only few reports have summarized relationships between crystal structures of drug/CD and dissolution behavior. In this study, we developed cimetidine (CIM)/CD complex crystals to achieve sustained drug release and investigated the relationship between the dissolution behavior of CIM/CD complexes and their crystal structures. CIM and 3 types of CDs (α-, ß-, and γ-CD) formed a complex crystal when subjected to solvent mixing. The CIM/CD complexes had a highly reduced dissolution rate compared to that of the physical mixture of CIM and CD. ß-CD improved the solubility of CIM, whereas γ-CD decreased its solubility. Based on the phase solubility diagram, CIM and α-, ß-, and γ-CD indicated A-type positive (AP) and AL deviation, and B-type limited solubility (BS) profiles, respectively. In γ-CD, the saturated concentration of CIM decreased owing to the formation of a low-solubility complex with CIM. CIM/α-CD formed cage-type crystals, and CIM/ß-CD and CIM/γ-CD formed channel-type crystals. The dissolution rate constant (k) of CIM/α-CD and CIM/ß-CD were 0.045 and 0.04 h-1, respectively. CIM/γ-CD and CIM/ß-CD displayed channel-type crystals; however, the channel-type crystals of CIM/γ-CD were stabilized by the presence of additional water molecules.

Effects of ionic and reductive atmosphere on the conformational rearrangement in hen egg white lysozyme prior to amyloid formation.

In this study, the combined effects of pH and salt concentration on the aggregation and amyloid formation of a charge-bearing protein (hen egg white lysozyme, HEWL) were investigated, as well as the inhibition of amyloid formation by using dithiothreitol (DTT) as a denaturing agent. Amyloid formation was found to depend on the ion strength and pH of the sample solution. Rather than the total charge, the partial charge of the amyloid related residues contributes to amyloid formation at pH < isoelectric point (pI). On the other hand, at pH> pI HEWL only undergoes alkaline denaturation regardless of the ionic strength. The effect of adding different amounts of DTT at different times on amyloid formation was also investigated. These results suggested that the positions of charges on a protein and the protein secondary structure are critical for protein aggregation and amyloid formation.

The function of oxybuprocaine: a parachute effect that sustains the supersaturated state of anhydrous piroxicam crystals.

Polymers have been recognized to have the function of sustaining the supersaturated state of drugs. This function has been widely studied because it will improve the absorption of poorly water-soluble drugs. However, clarifying the mechanism of this sustaining pharmaceutical effect (parachute effect) on the supersaturated state as a result of polymers is remains a task. We have found that oxybuprocaine, which is a small molecule, has a parachute effect on the supersaturated state (due to an anhydrate-to-hydrate transformation) of piroxicam-anhydrate in the aqueous phase. We consider that oxybuprocaine controls the environment of the solution and the network of polymers is unnecessary. Therefore, oxybuprocaine not only becomes a clue for elucidating the essential mechanism of the parachute effect of polymers but also enables us to rationally propose a new type of solubilizer.

Decarboxylation of indomethacin induced by heat treatment.

As crystalline indomethacin is heated and subsequently cooled, it transforms into glassy indomethacin. While the original crystals are off-white in color, the glass becomes blackish-brown via a yellow intermediate stage. TLC of the components of the glass revealed three bands. The yellow component, which is generated either under hypoxic conditions or in the dark, was elucidated by NMR spectroscopy to be a decarboxylated fragment produced by thermal degradation. The colorless component is proposed to be formed by the opening of the indole ring of indomethacin; the structure of this degradation product was identified by EI-MS to be the same as the oxidative-cleavage product formed upon UV-irradiation, as previously reported. Another band was a blackish-brown pigment whose mobility placed it close to the TLC baseline. This oxidative-cleavage product and the blackish-brown pigment are not generated under hypoxic conditions. However, the extent of indomethacin decarboxylation under hypoxic conditions was found to be dependent on the heating temperature and time. Consequently, we prepared amorphous indomethacin through control of the heating temperature and time; heating at 160 °C for 30 min or less under hypoxic conditions is optimum for obtaining pure amorphous indomethacin.

Melting Process of the Peritectic Mixture of Lidocaine and Ibuprofen Interpreted by Site Percolation Theory Model.

Eutectic mixtures are often used in the design and delivery of drugs. In this study, we examined the peritectic mixture of lidocaine (LDC) and ibuprofen (IBP) using differential scanning calorimetry, Raman spectroscopy, and microscopy. The obtained phase diagram showed that as the mixture was heated, first LDC melted at 293 K, then IBP dissolved in the liquefied LDC at 310 K, and finally all remaining crystals melted. In the 1H NMR spectra, the signals of the carboxyl group in IBP and amide or amine group in LDC shifted to the low magnetic field in the IBP/LDC mixtures, because of the intermolecular interaction between these moieties. Using FTIR spectroscopy, the kinetic "reaction" order of the melting process in the mixtures with excess LDC, equimolar, and excess IBP was determined to be +1/2, -1/2, and 0, respectively. The 2 contacts between the liquidus line and the higher melting line at 310 K at IBP molar fractions of 1/3 and of 2/3 were explained on the basis of the site percolation theory.

Enhancement of the 1-Octanol/Water Partition Coefficient of the Anti-Inflammatory Indomethacin in the Presence of Lidocaine and Other Local Anesthetics.

Side effects and excessive potentiation of drug efficacy caused by polypharmacy are becoming important social issues. The apparent partition coefficient of indomethacin (log P'IND) increases in the presence of lidocaine, and this is used as a physicochemical model for investigating polypharmacy. We examined the changes in log P'IND caused by clinically used local anesthetics-lidocaine, tetracaine, mepivacaine, bupivacaine, and dibucaine-and by structurally similar basic drugs-procainamide, imipramine, and diltiazem. The quantitative structure-activity relationship study of log P'IND showed that the partition coefficient values (log PLA) and the structural entropic terms (ΔSobs, log f) of the additives affect log P'IND. These results indicate that the local anesthetics and structurally similar drugs function as phase-transfer catalysts, increasing the membrane permeability of indomethacin via heterogeneous intermolecular association. Therefore, we expect that the potency of indomethacin, an acidic nonsteroidal anti-inflammatory drug, will be increased by concurrent administration of the other drugs.

Characteristics of amorphous complex formed between indomethacin and lidocaine hydrochloride.

Indomethacin (IM) easily forms an amorphous complex with lidocaine (LC) by heat treatment. To know the mechanism involved in the formation of this complex, we studied temperature-dependent phase changes in mixtures of IM and lidocaine hydrochloride (LH), in which the cationic form of LC forms a salt with Cl(-), in various molar ratios by using DSC and NMR. Although heating of the mixture of IM and LC (IM+LC), formed a eutectic mixture, that of IM and LH (IM+LH) did not, and IM in the IM+LH mixture was dissolved into fused LH. Cooling of the fused IM+LH showed the glass transition in all of the samples containing various amounts of IM, suggesting that fused IM+LH took a homogenous amorphous state (IM/LH) below its glass transition temperature, in contrast to the fused IM+LC, which formed the rubber state and/or glass state depending on the molar content of IM. The results of the NMR study showed that IM in IM/LH caused the electronic structure of LH to change in such a way as to become similar to that of LC, but this effect was limited. Hence, mode of interaction of LH with IM is different from that of LC with IM.

Features of heat-induced amorphous complex between indomethacin and lidocaine.

We studied temperature-dependent phase changes in the mixture of indomethacin (IM) and lidocaine (LC) in various molar ratios by differential scanning calorimetry (DSC). DSC studies were carried out between -40°C and 180°C heating/cooling/heating cycle at a rate of 10°C/min under a nitrogen gas flow. Although LC in the liquid state was crystallized, fused IM showed a glass transition signal upon cooling. Hence, cooling of fused IM caused it to assume the amorphous state below its glass transition temperature. Heating of the mixture of IM and LC resulted in formation of a eutectic mixture between them, and cooling of the fused mixture caused formation of the amorphous state at any molar ratio examined. It is noteworthy that the amorphous solid of the fused complex of IM and LC was in the rubber state and glass state in the mixtures containing IM between 20% and 40%, whereas there was only the glass state in the samples containing 50% IM and higher. In addition, crystallization of LC took place by cooling the fused sample containing 10% IM.