Ricardo A. E. Castro

Thermal behavior of some antihistamines

Thermogravimetry (TG), differential scanning calorimetry (DSC), polarized light thermal microscopy (PLTM), as well as X-ray powder diffraction (XRD) and Fourier transformed infrared spectroscopy (FTIR) were used to study the thermal behavior and the chemical structure of cimetidine, famotidine, ranitidine-HCl, and nizatidine. The TG–DSC curves show that the famotidine and ranitidine-HCl suffer decomposition during melting and they are thermally less stable in comparison with cimetidine and nizatidine, the latter being the most stable of all the drugs studied in this study. The DSC curves of famotidine and ranitidine-HCl show exothermic peaks immediately after the melting, confirming the occurrence of thermal decomposition. The DSC curves also show that the cimetidine and nizatidine have some thermal stability after melting. The thermal events shown in the PLTM images are consistent with the results shown in the TG–DSC and DSC curves. The XRD patterns show that the cimetidine and famotidine are less crystalline compared with ranitidine-HCl and nizatidine. The theoretical FTIR bands are in agreement with those obtained experimentally, and in some cases, no difference is observed between the theoretical and experimental values, even being identical in one of the cases.

A thermodynamic based approach on the investigation of a diflunisal pharmaceutical co-crystal with improved intrinsic dissolution rate

A thermodynamic based approach is used to investigate diflunisal+nicotinamide binary and solution mixtures. A 2:1 co-crystal could be prepared by liquid assisted ball mill grinding and by solution crystallization from ethanol. The diflunisal+nicotinamide+ethanol ternary phase diagram points out conditions for co-crystal scaling-up. From the diflunisal+nicotinamide binary phase diagram, besides identification of the co-crystal stoichiometry, two additional useful binary compositions, eutectic mixtures, were characterized. From a solution enthalpy based approach, the enthalpic stabilization of the co-crystal relative to the pure solid components is quantified. Intrinsic dissolution rate, IDR, in test conditions consistent with USP requirements, including those referred in the diflunisal tablet monograph, were carried out, indicating that the co-crystal improves diflunisal IDR by about 20%. The systematic study of diflunisal+nicotinamide mixtures presented in this work is of particular interest due to the relevance of diflunisal, both as a non-steroidal anti-inflammatory drug and also due to the potentiality of orally administrated diflunisal in familial amyloid polyneuropathy.

A study of the structure of the pindolol based on infrared spectroscopy and natural bond orbital theory.

Beta-adrenoceptor-blocking agents (beta-blockers) are on the list of the top selling drugs. Pindolol is a representative of this type of compound, either from the structural point of view, or as reference for comparison of the pharmacokinetic properties of the beta-blockers. A study of the pindolol structure based on infrared spectroscopy and natural bond orbital (NBO) theory is the main aim of the present research. FTIR spectra of the solid pindolol were recorded from 4000 to 400cm(-1), at temperatures between 25 and -170 degrees C. For spectral interpretation, the theoretical vibrational spectra of the conformer present in the solid was obtained at the B3LYP/6-31G* level of theory. NBO analysis of the reference conformer, before and after optimization, was carried out at the same level of theory referred above. Characteristic absorption vibrational bands of the spectra of solid pindolol and of the isolated conformer were identified. Intra- and intermolecular interactions in pindolol were confirmed by the frequency shift of the vibrational modes and by the NBO theory. A detailed molecular picture of pindolol and of its intermolecular interactions was obtained from spectroscopy and NBO theory. The combination of both methods gives a deeper insight into the structure.

β-Phase Formation of Poly(9,9-dioctylfluorene) Induced by Liposome Phospholipid Bilayers

The well-structured β-phase emission of the neutral poly(9,9-dioctylfluorene) (PFO) is observed in 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) bilayers, either as polydisperse aqueous liposomes or as the lamellar phase in thin films, and has been characterized by absorption, fluorescence (steady-state and time-resolved), and fluorescence anisotropy spectroscopy. Inclusion of PFO in DMPC liposomes provides a way of obtaining the ordered structure of this neutral polymer in aqueous suspensions. Quantification of the increase of the PFO β-phase in DMPC liposomes with the increase in polymer concentration is followed by deconvolution of the absorption spectra. In solid films, the presence of the phospholipids enhances the β-phase formation. In addition, the effect of the PFO concentration on the phospholipid phase transitions has been studied by differential scanning calorimetry (in liposome) and polarized light thermal microscopy (in solid film), confirming PFO/DMPC interactions in both liposome and films. The liposome size and structure in the presence and absence of polymer were characterized by dynamic light scattering and transmission electron microscopy, which showed relatively modest changes in liposome shape but a decrease in size upon incorporation of PFO.

Thermoanalytical study of nimesulide and their recrystallization products obtained from solutions of several alcohols

Thermogravimetry, differential scanning calorimetry, and vibrational infrared spectroscopy were used to study nimesulide and its recrystallization products that were obtained from solutions of several alcohols. The thermoanalytical measurements were performed in both air and nitrogen atmospheres and the results suggest that, under the experimental conditions used in this paper, it was possible to obtain neither polymorphic nor pseudopolymorphic forms of this drug. In this investigation, quantum chemical approach methods were used to determine the molecular structures using the Becke three-parameter hybrid method and the Lee–Yang–Parr correlation functional. The performed molecular calculations were done with the Gaussian 09 routine and the theoretical calculation results were correlated with the experimental IR vibrational spectrum.

Structural characterization of solid trivalent metal dodecyl sulfates: from aqueous solution to lamellar superstructures

Metal dodecyl sulfates of trivalent aluminium, chromium, lanthanum and gadolinium were prepared by addition of the corresponding salts to aqueous solutions of sodium dodecyl sulfate at the natural pH (ca. 6). Using X-ray diffraction, FT-IR and NMR spectroscopy, DSC, thermogravimetry and polarizing light thermomicroscopy it is shown that metal dodecyl sulfates are formed with lamellar structures. These have different degrees of hydration, which depend upon the metal ion. In some cases there is evidence for coexistence of different lamellar phases. The metal is strongly bound electrostatically to the sulfate group, and although the alkyl chain is in an extended conformation, there are suggestions of local disordering of the methylene groups adjacent to the anionic head group. SEM with an EDS probe on the trivalent metal complexes shows a 1 : 3 ratio at the surface identical to the bulk structure. Studies by SEM and AFM provide evidence of periodicity, which is likely to be induced by the lamellar, layered structures. Differences are observed in the thermal behavior, which appear to reflect both the coordination behavior of the metal ion and the degree of hydration.

Phase transitions of 1,2-cyclohexanediol isomers studied by polarised light microscopy and differential thermal analysis

Polarised light microscopy and DTA have been used to study the phase transitions observed in cis and trans-1,2-cyclohexanediol during heating/cooling cycles performed between ambient and melting temperatures to prove that the presence of impurities even in trace amounts can affect the thermal properties of the substances. Good quality commercial material before and after further purification were used in this study.

Resolved structures of two picolinamide polymorphs. Investigation of the dimorphic system behaviour under conditions relevant to co-crystal synthesis

The polymorphism of picolinamide, one of the three isomeric pyridinecarboxamides, a group of co-formers with relevance for co-crystal research, has been investigated. Particular attention has been focused on phase transitions brought about in DSC scanning experiments or during ball mill grinding, a common strategy in co-crystal synthesis. Two polymorphs, which the Burger and Ramberger empirical rules predict to be enantiotropically related, were identified. The crystal structure of the room temperature stable polymorph II, Tfus,II = 102.0 °C, was redetermined, while that of the ambient temperature metastable polymorph I, Tfus,I = 106.4 °C, was determined for the first time. This was produced as single crystals by sublimation in an oven at 90 °C. In the crystalline structure of this polymorphic form, hydrogen bonds link the molecules in tetramers, which are then packed in piles along the a axis in an arrangement that has not been found in any of the previously solved crystalline structures of isomeric pyridinecarboxamides. Hirshfeld surface analysis was performed in order to facilitate comparison of the intermolecular contacts in both polymorphs. Ball mill grinding of commercial polymorph II gives rise to different outcomes, depending on the experimental conditions: neat grinding for 120 minutes results in conversion to polymorph I, while the addition of 10 μL of toluene, ethyl acetate, dimethylsulfoxide, methanol, ethanol or isopropyl alcohol and liquid assisted grinding stabilizes polymorph II.

Synthesis, spectroscopy, photophysics and thermal behaviour of stilbene-based triarylamines with dehydroabietic acid methyl ester moieties

Novel stilbene-based triarylamines with dehydroabietic acid methyl ester moieties have been synthesised by palladium catalysed C–N coupling reactions. The presence of the bulky dehydroabietic acid group increases solubility, hinders crystallisation and permits their sublimation while preserving their electronic and optical characteristics. This makes them good candidates for various molecular electronic applications. We report a detailed characterisation of their electrochemical, spectroscopic and photophysical properties. In addition, the thermal stability and behaviour is discussed with reference to the potential for preparation of stable thin films.

Novel organic hole transport layers for molecular electronic systems

Five novel triarylamines based on the bulky dehydroabietic acid unit have been synthesised, and their potential as hole transport layers tested. This bulky group facilitates film preparation and stability without significantly affecting the chemical or materials properties. Three of these systems present excellent stability, and show considerable potential for device applications.