Physicochemical properties of salts of p-aminosalicylic acid. I. Correlation of crystal structure and hydrate stability

First Steps towards Understanding the Non-Linear Impact of Mg on Calcite Solubility: A Molecular Dynamics Study

Magnesium (Mg2+) is one of the most common impurities in calcite and is known to have a non-linear impact on the solubility of magnesian calcites. Using molecular dynamics (MD), we observed that Mg2+ impacts overall surface energies, local free energy profiles, interfacial water density, structure and dynamics and, at higher concentrations, it also causes crystal surface deformation. Low Mg concentrations did not alter the overall crystal structure, but stabilised Ca2+ locally and tended to increase the etch pit nucleation energy. As a result, Ca-extraction energies over a wide range of 39 kJ/mol were observed. Calcite surfaces with an island were less stable compared to flat surfaces, and the incorporation of Mg2+ destabilised the island surface further, increasing the surface energy and the calcium extraction energies. In general, Ca2+ is less stable in islands of high Mg2+ concentrations. The local variation in free energies depends on the amount and distance to nearest Mg in addition to local disruption of interfacial water and the flexibility of surface carbonate ions to rotate. The result is a complex interplay of these characteristics that cause variability in local dissolution energies. Taken together, these results illustrate molecular scale processes behind the non-linear impact of Mg2+ concentration on the solubility of magnesium-bearing calcites.

Solid state transformations of different stoichiometric forms of an organic salt formed from 5-sulfosalicylic acid and hexamethylenetetramine upon dehydration and rehydration

The reversible solid state transformations between the diverse forms (e.g. hydrous/anhydrous and different stoichiometries) of a salt formed from 5-sulfosalicylic acid (A) and hexamethylenetetramine (B) have been investigated.

Factors affecting crystallization of hydrates

Objectives

To provide a comprehensive understanding of the competing thermodynamic and kinetic factors governing the crystallization of various hydrate systems. The ultimate goal is to utilize this understanding to improve the control over the unit operations involving hydrate formation, as well as to optimize the bioavailability of a given drug product.

Key findings

The thermodynamic and kinetic factors that govern hydrate crystallization are introduced and the current status of the endeavour to gain a mechanistic understanding of the phenomena that occur during the crystallization of different hydrate systems is discussed. The importance of hydrate investigation in the pharmaceutical field is exemplified by examining two specific hydrate systems: the polymorphic hydrate system and hydrates of pharmaceutical salts.

Summary

This review identifies the factors that are of critical importance in the investigation of anhydrate/hydrate systems. This knowledge can be used to control the phase transformation during pharmaceutical processing and storage, as well as in building a desired functionality for the final formulation.

Structural characterisation and dehydration behaviour of siramesine hydrochloride

In this study the crystal structures of siramesine hydrochloride anhydrate alpha-form and siramesine hydrochloride monohydrate were determined, and this structural information was used to explain the physicochemical properties of the two solid forms. In the crystal structure of the monohydrate, each water molecule is hydrogen bonded to two chloride ions, and thus the water is relatively strongly bound in the crystal. No apparent channels for dehydration were observed in the monohydrate structure, which could allow transmission of structural information during dehydration. Instead destructive dehydration occurred, where the elimination of water from the monohydrate resulted in the formation of an oily phase, which subsequently recrystallised into one or more crystalline forms. Solubility and intrinsic dissolution rate of the anhydrate alpha-form and the monohydrate in aqueous media were investigated and both were found to be lower for the monohydrate compared to the anhydrate alpha-form. Finally, the interactions between water molecules and chloride ions in the monohydrate as well as changes in packing induced by water incorporation could be detected by spectroscopic techniques.

Parenteral formulation of zopiclone

The present study was undertaken with an intention to develop a stable and effective parenteral formulation, containing the drug zopiclone. Since zopiclone is a water insoluble drug, various methods such as co-solvency, pH control and hydrotrophy have been tried in order to enhance its solubility. When all these methods could not give adequate solubility enhancement of the drug, a hydrochloride salt was prepared, and it was found to be thermostable. Various batches of zopiclone hydrochloride injection formulation were prepared in order to assess the influence of light, atmospheric oxygen and antioxidant on the stability of the drug and the formulations were also subjected to accelerated stability testing in order to predict approximate shelf-life of the product.

Dehydration behavior and structural characterization of the GW275919X monohydrate

GW275919X, a central muscle relaxant for the treatment of lower back pain, exists in a monohydrate. Knowledge of the solid state dehydration behavior and the crystal structure is essential for determining its relative physical stability. Thermal analysis and hot-stage powder X-ray diffraction were used to study the solid state phase transformation during the dehydration process. Crystal structure was determined by single crystal X-ray analysis. Molecular modeling with Cerius(2) software was used to visualize the hydrate crystal structure and to construct the molecular packing and hydrogen bond diagram. Morphology prediction was performed using the BFDH calculation. Crystallographic data: monoclinic, space group, P21/c, a (Angstrom)=14.3734, b (Angstrom)=5.0336, c (Angstrom)=15.4633 and beta=105.11 degrees. Water molecules in the hydrate crystal of GW275919X are involved in the hydrogen bonds and these hydrogen bonds contribute to the coherence of the crystal structure. The longest dimension of the predicted morphology is in the b-direction, which would correspond to the needle axis of the experimental crystals.

Structure and Physical Stability of Hydrates and Thermotropic Mesophase of Calcium Benzoate

The aim of this study is to investigate the hydration and the dehydration processes of calcium benzoate hydrates (trihydrate and monohydrate), thermotropic mesophases (dehydrated mesophase and lyophilized mesophase) and amorphous state, and the influence of their molecular order on those processes. X-ray analysis revealed that trihydrate has a planar structure composed of two types of planes-one from benzoic acid, water, and calcium ion and another from benzoic acid and water-and that both planes are linked by three water molecules. It was found that calcium benzoate was able to exist as thermotropic mesophases by dehydration of trihydrate and lyophilization. These mesophases were characterized by polarizing-light microscopy (PLM), X-ray powder diffraction (XRPD), differential thermal analysis (DTA), thermogravimetric analysis (TGA), and scanning electron microscopy (SEM). Both mesophases prepared by two procedures showed some similar physical properties, but lyophilized mesophase seemed to have molecular structure with higher order than dehydrated mesophase. The mesophases exhibited different hydration behavior. The dehydrated mesophase showed a stepwise rehydration process where it became monohydrate first and then trihydrate. The lyophilized mesophase became trihydrate without appearance of monohydrate. An amorphous form could also be prepared and it rehydrated first to the monohydrate and then trihydrate. The results suggest that the more disordered dehydrated mesophase and amorphous state change to monohydrate whereas the more ordered lyophilized mesophase cannot change to monohydrate but only to trihydrate.

Characterization of dehydration and hydration behavior of calcium lactate pentahydrate and its anhydrate

The use of calcium lactate pentahydrate (CLP) as an additional filler-binder for direct compaction of tablets has been reported to result in a short disintegration time and rapid drug release. The aim of this study was to understand the dehydration and hydration behavior of CLP and calcium lactate anhydrate (CLA) under various conditions of storage temperature and relative humidity. The removal and acquisition of crystal water were investigated by using differential scanning calorimetry (DSC), thermogravimetry-differential thermal analysis (TG-DTA), powder X-ray diffraction (PXRD) and scanning electron microscopy (SEM). The PXRD results indicated that CLP exists as a crystalline solid and CLA as an amorphous solid. Dehydration of CLP resulted in aggregated particles of CLA with an increase in average particle size. The dehydration and hydration kinetics of CLP were analyzed with the Hancock-Sharp equation on the basis of the isothermal DSC data. The dehydration of CLP followed a zero-order mechanism (Polany-Winger equation). In contrast, the surface roughness of CLA was significantly decreased by hydration. The hydration of CLA followed a three-dimensional diffusion model (Ginstling-Brounshtein equation).

Crystal structure and thermal behavior of nedocromil nickel octahydrate

The hydration behavior of a salt depends on the nature of the cation and the anion and on the molecular packing. A transition metal salt (nickel) of nedocromil was prepared and its crystal structure was elucidated in an attempt to study the influence of the nature of the bivalent cation on the structure, water interactions and molecular packing. Crystal data: nedocromil nickel octahydrate (NNi), orthorhombic, Pca2(1), a=29.5446(1) A, b=25.0444(1) A, c=13.3767(2) A, Z=16. The Ni2+, has octahedral coordination, but the coordination environments of the cations and the bonding environments of the water molecules differ. NNi contains four Ni2+ ions in the asymmetric unit, two of which are each octahedrally coordinated to five water molecules and to a carboxyl oxygen. The two remaining Ni2+ ions are linked in a Ni2(H2O)10(+4) species. Thermal analytical data for NNi show that the water molecules in this hydrate are lost in a single step dehydration, which may be attributed to the fairly continuous water layer in the ac plane of the crystal lattice.

Dehydration, hydration behavior, and structural analysis of fenoprofen calcium

Fenoprofen calcium (FC) is a nonsteroidal, anti-inflammatory, analgesic, and antipyretic agent. The dehydration behavior of FC dihydrate and the rehydration of the dried FC were investigated using differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), and powder X-ray diffractometry (PXRD). The stoichiometry, the crystal packing arrangement, and water environments in FC dihydrate were determined using single-crystal X-ray diffraction (XRD) analysis. The Arrhenius plot (natural logarithm of the dehydration rate constant versus the reciprocal of absolute temperature) for FC dihydrate from isothermal TGA is not linear. The activation energy of dehydration was 309 kJ/mol in the 50-60 degrees C range and 123 kJ/mol in the 60-80 degrees C range. The difference in activation energy can be explained from the crystal structure data where one water molecule is sandwiched between repeating polar carboxylate groups and the other water is in a slightly less polar region of the crystal. Single-crystal XRD analysis also indicated each calcium ion is coordinated to six oxygens. Two coordinating oxygens are provided by two water molecules and the other four oxygens are provided by the carboxylate group of four separate fenoprofen anions. Each fenoprofen anion, which can provide two oxygens for coordination, is associated with two different calcium ions. Hot-stage PXRD suggested that only a loss of 1 mole of water per mole of FC dihydrate (forming a monohydrate) was required to convert the material to a partially crystalline state. The monohydrate is not completely disordered as evidenced by a strong diffraction peak as well as some weaker peaks in the PXRD pattern. The rehydration of the anhydrous form of FC follows a solution-mediated transformation, prior to crystallizing as the dihydrate.

Dehydration behavior of nedocromil magnesium pentahydrate

The dehydration of nedocromil magnesium (NM) pentahydrate proceeds in two steps, corresponding to the loss of four water molecules in the first step and one water molecule in the second step. The effects of temperature, particle size, sample weight, water vapor pressure and dehydration-rehydration cycle on both the kinetics and activation energy of the dehydration of NM pentahydrate were studied using isothermal TGA and temperature-ramp DSC analyzed by Kissinger's method. The dehydration kinetics for both steps are best described by the Avrami-Erofeev equations, suggesting a nucleation-controlled mechanism. The high activation energy for the second dehydration step indicates that the last water molecule, which is bonded both to a magnesium ion and to a carboxylate oxygen atom, is more 'tightly bound'. The activation energy decreased with increasing sample weight and decreasing particle size. The dehydration rate increased with decreasing water vapor pressure and with repetition of the dehydration-hydration cycle. Dynamic and isothermal PXRD, and 13C solid-state NMR were employed to provide an insight into the dehydration mechanism and the nature of solid-state phase transformation during the dehydration. Molecular modeling with Cerius(2) was used to visualize the crystal structure and to construct the molecular packing diagram. A correlation was noted between the dehydration behavior and the bonding environment of the water molecules in the crystal structure.

Physical characterization of picotamide monohydrate and anhydrous picotamide

Picotamide is an antiplatelet agent given by mouth as monohydrate (PICOW) (Plactidil) in thrombo-embolic disorders. This study deals with physical characterization of PICOW recrystallized from various solvents and the respective dehydration products using X-ray powder diffractometry (XRD), infrared spectroscopy (IR), and thermal analytical techniques (differential scanning calorimetry, DSC; thermogravimetric analysis, TGA; simultaneous TGA/DSC; hot stage microscopy, HSM). Monophasic and biphasic DSC and TGA profiles of water loss were recorded under open conditions for PICOW samples which showed the same monoclinic crystal structure. Biphasic profiles became monophasic for gently ground samples which were, however, structurally identical to the intact samples. Morphological factors, the various degree of "perfection" of the PICOW crystal lattice, and/or cluster aggregation of PICOW crystals were assumed to be responsible for the differing dehydration patterns. Polymorphism in anhydrous picotamide, i.e., nucleation of crystal forms A, mp 135.5 +/- 0.4 degrees C, and B, mp 152.9 +/- 0.3 degrees C after dehydration of PICOW, was detected by DSC and HSM. The dehydration product of PICOW under isothermal conditions (115 degrees C, 20 mmHg), PICOA, was mainly composed of the lower melting polymorph A (fusion enthalpy 74.4 +/- 2.2 J g(-1)), which gradually reverted to the starting hydrate by storing in an ambient atmosphere. Dissolution tests of PICOW and PICOA in water at 37 degrees C as both powders and compressed disks reflected to some extent the higher solubility of the metastable form (by 24% at 37 degrees C) in terms of both higher dissolution efficiency and percent of active ingredient dissolved (by 28%) and intrinsic dissolution rate (by 32%).

Physicochemical characterization of nedocromil bivalent metal salt hydrates. 3. Nedocromil calcium

A crystalline pentahydrate and a crystalline 8/3 hydrate of nedocromil calcium (NC) were prepared. The relationships between these solid phases and the nature of the water interactions in their structures were studied through characterization by differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), Karl Fischer titrimetry (KFT), hot-stage microscopy (HSM), ambient- or variable-temperature powder X-ray diffraction (PXRD), Fourier-transform infrared (FTIR) spectroscopy, solid-state nuclear magnetic resonance (SSNMR) spectroscopy, water uptake at various relative humidities (RH), intrinsic dissolution rate (IDR) and solubility measurements. The solubility and intrinsic dissolution rate of the pentahydrate in water at 25 degrees C are approximately 17% greater than the corresponding values for the 8/3 hydrate, corresponding to a greater Gibbs free energy of only 380 J.mol-1 (91 cal.mol-1) for the pentahydrate. The results of DSC, TGA, and FTIR and SSNMR spectroscopy indicate that the water of hydration is more loosely bound in the pentahydrate than in the 8/3 hydrate. On increasing the temperature in open-pan DSC and TGA, the water in the pentahydrate is released in four steps (three steps in crimped pans), whereas the water in the 8/3 hydrate is released in three steps (three steps also in crimped pans). These three stepwise dehydrations are fundamentally explained by their different water environments in the crystal structure of the 8/3 hydrate, which was determined by single-crystal XRD [crystal data: triclinic, space group P1, a = 13.2381(3) A, b = 13.3650(2) A, c = 17.8224(2) A, alpha = 68.202(1) degrees, beta = 86.894(1) degrees, gamma = 82.969(1) degrees, Z = 6]. The asymmetric unit contains three nedocromil anions and three calcium cations associated with eight water molecules. The nedocromil anions act as polyfunctional ligands to the Ca2+ ions, coordinating through both the carbonyl oxygen and the carboxylate oxygen atoms. The molecular conformations of the three nedocromil anions in the asymmetric unit are almost identical. However, the crystal structure contains two different calcium environments, one of which has the Ca2+ ion hydrated by four water molecules in the equatorial plane and by two carbonyl oxygens in its axial coordination sites. In the second environment, the Ca2+ ion has four carboxylate oxygen atoms in its equatorial plane and two water molecules in its axial coordination sites. Two of the carboxylate ligands are twisted out of the tricyclic ring, and the other two carboxylate ligands are nearly coplanar with the tricyclic ring. All of the eight water molecules in the 8/3 hydrate are linked to calcium and carboxylate ions and none are linked to other water molecules.

Physicochemical characterization of nedocromil bivalent metal salt hydrates. 2. Nedocromil zinc

Salts are usually considered as alternatives for drug delivery when the physicochemical characteristics of the acidic or basic parent drug are unsuitable or inadequate for a satisfactory formulation. The physical, chemical, and biological characteristics of nedocromil sodium, which is used in the treatment of reversible obstructive airways diseases such as asthma, can be altered by its conversion to other salt forms. Nedocromil zinc (NZ), a bivalent metal salt, was found to exist in several hydration states, an octahydrate, a heptahydrate, and a pentahydrate, which itself exists in two modifications, designated as A and B. The relationships between these, NZ hydrates and the nature of the water interactions in the solid phases were studied through characterization by differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), Karl Fischer titrimetry (KFT), hot-stage microscopy (HSM), ambient- or variable-temperature powder X-ray diffraction (PXRD), Fourier-transform infrared (FTIR) spectroscopy, solid-state nuclear magnetic resonance (SSNMR) spectroscopy, environmental scanning electron microscopy (ESEM), water uptake at various relative humidities (RH), intrinsic dissolution rate (IDR), and solubility measurements. The integral water stoichiometries of the NZ hydrates were deduced from KFT and TGA and were confirmed by elemental analysis. For the heptahydrate, the loss of 1 mol of water at a higher temperature than for the others is attribute to an identifiable water molecule that is linked directly to the zinc and to two carboxylate oxygen atoms but not to the other water molecules, as deduced from the crystal structure previously determined. Similarly, for both pentahydrate modifications, 1 mol of water was also lost at a higher temperature than the others. Results from studies using DSC, TGA, HSM, PXRD, SSNMR, and FTIR suggested that the octahydrate contains loosely bound water in its structure and is partially amorphous. The course of the dehydration processes depended on the water vapor pressure and temperature. The octahydrate and heptahydrate underwent an apparently irreversible phase transformation to the pentahydrate at an elevated temperature and water vapor pressure. Pentahydrate modifications A and B differ in their long-range order (deduced from differences in their PXRD pattern and their thermal analytical behavior), but their short-range order (i.e., molecular environments) are identical (deduced by identical SSNMR spectra). The rank order of both IDR and solubility in water at 25 degrees C was octahydrate > heptahydrate > pentahydrate modification A approximately pentahydrate modification B, corresponding to the rank order of free energy with respect to the aqueous solution and the order of preparation according to Ostwald's rule of stages.

Physicochemical characterization of nedocromil bivalent metal salt hydrates. 1. Nedocromil magnesium

Nedocromil sodium is used in the treatment of reversible obstructive airways diseases, such as asthma. The physicochemical, mechanical, and biological characteristics of nedocromil sodium can be altered by its conversion to other salt forms. In this study, three crystalline hydrates, the pentahydrate, heptahydrate, and decahydrate, of a bivalent metal salt, nedocromil magnesium (NM), were prepared. The relationships between these hydrates were studied through their characterization by differential scanning calorimetry (DSC), thermogravimetric analysis (TGA). Karl Fischer titrimetry (KFT), hot stage microscopy (HSM), ambient or variable temperature powder X-ray diffraction (PXRD), Fourier-transform infrared (FTIR) spectroscopy, solid-state nuclear magnetic resonance (SSNMR) spectroscopy, scanning electron microscopy (SEM), water uptake at various relative humidities (RH), intrinsic dissolution rate (IDR), and solubility measurements. The pentahydrate showed two dehydration steps, corresponding to two binding states of water, a more temperature-sensitive tetramer and a more stable monomer, deduced from the crystal structure previously determined. The heptahydrate and decahydrate each showed a dehydration step with a minor change in slope at about 50 degrees C, which was analyzed by derivative TGA and confirmed by DSC. HSM and variable temperature PXRD also confirmed the thermal dehydration behavior of the NM hydrates. The decahydrate underwent an apparently irreversible phase transformation to the pentahydrate at 75 degrees C at an elevated water vapor pressure. The PXRD, FTIR, and SSNMR of the decahydrate were similar to those of the heptahydrate, suggesting that the three extra water molecules in the decahydrate are loosely bound, but were significantly different from those of the pentahydrate. The rank order of both IDR and solubility in water at 25 degrees C was heptahydrate approximately decahydrate > pentahydrate, corresponding to the rank order of free energy with respect to the aqueous solution.

Physicochemical characterization of diclofenac N-(2-hydroxyethyl)pyrrolidine: anhydrate and dihydrate crystalline forms

This study on diclofenac N-(2-hydroxyethyl)pyrrolidine (DHEP) characterizes and compares the anhydrate (DHEPA) and dihydrate (DHEPH) solid state forms using powder X-ray diffraction, infrared spectroscopic, and thermal analyses. Heats of solution and intrinsic dissolution rates are determined. The thermodynamics of hydration are discussed and the entropic cost of dihydrate formation is calculated. Reported differences in the solution behavior of DHEP crystallized from different solvents are explained. The molecular structures of both solid forms were determined and are presented. Crystal data for DHEPA: triclinic, space group P-1 (No 2), a = 11.662(2) A, b = 11.874(2) A, c = 15.296(3) A, alpha = 76.183(14) degrees, beta = 84.575(12) degrees, gamma = 87.028(12) degrees V = 2046.8(6)A3, Z = 4. Crystal data for DHEPH: triclinic, space group P-1 (No 2), a = 9.356(3) A, b = 9.920(2) A, c = 13.5413(12) A, alpha = 69.915(12) degrees, beta = 82.05(2) degrees, gamma = 71.51(2) degrees, V = 1118.9(4) A3, Z = 2. The experimentally observed ease of dehydration under conditions of nitrogen purge is explained in terms of crystal packing within the dihydrate.

Relationships between crystal structures, thermal properties, and solvate stability of dialkylhydroxypyridones and their formic acid solvates

Four 1,2-dialkyl-3-hydroxy-4-pyridones (DAHPs), which are iron chelators potentially suitable for oral administration, and their formic acid solvates (DAHP-Fs) were examined in powder form by powder X-ray diffraction (PXD), differential scanning calorimetry (DSC), thermal gravimetric analysis (TGA), and hot-stage microscopy (HSM). The experimental PXD pattern of each DAHP-F is different from that of the corresponding DAHP, indicating different crystalline phases. The PXD patterns calculated from the published crystal structures closely resemble the corresponding PXD patterns determined experimentally, indicating that the powdered materials studied are structurally identical with the single crystals previously examined. The DAHPs have similar DSC profiles consisting of melting followed by vaporization. The DSC profiles of the DAHP-Fs share five common features: melting and desolvation of the solvate, crystallization of the nonsolvate, vaporization of the released formic acid, melting of the nonsolvate, and vaporization of the nonsolvate. The weight loss steps in TGA indicate that each DAHP-F contains 1 mol of formic acid/mol of DAHP. The threshold temperature for desolvation of each DAHP increases with decreasing length of the hydrogen bond between the pyridone carbonyl oxygen and the formic acid carboxyl proton, corresponding to an increase in solvate stability. Thus, the relative stabilities of the solvates are delineated and are related to the length of the hydrogen bond between the DAHP and the formic acid molecules.