Preparation, structural analysis, and properties of tenoxicam cocrystals.

Cocrystals of tenoxicam, a non-steroidal anti-inflammatory drug, are screened, prepared, and characterized in this study. Nine tenoxicam cocrystals were identified using solvent-drop grinding (SDG) techniques. Structural characterization was performed using powder X-ray diffraction (PXRD), differential scanning calorimetry, and multinuclear solid-state NMR (SSNMR). Thermal analysis, PXRD, and 1D SSNMR are used to detect solvates and phase mixtures encountered in SDG cocrystal screening. 2D SSNMR methods are then used to confirm cocrystal formation and determine structural aspects for selected cocrystals formed with saccharin, salicylic acid, succinic acid, and glycolic acid in comparison to Forms I and III of tenoxicam. Molecular association is demonstrated using cross-polarization heteronuclear dipolar correlation (CP-HETCOR) methods involving (1)H and (13)C nuclei. Short-range (1)H-(13)C CP-HETCOR and (1)H-(1)H double-quantum interactions between atoms of interest, including those engaged in hydrogen bonding, are used to reveal local aspects of the cocrystal structure. (15)N SSNMR is used to assess ionization state and the potential for zwitterionization in the selected cocrystals. The tenoxicam saccharin cocrystal was found to be similar in structure to a previously-reported cocrystal of piroxicam and saccharin. The four selected cocrystals yielded intrinsic dissolution rates that were similar or reduced relative to tenoxicam Form III.

Preparation and structural characterization of amorphous spray-dried dispersions of tenoxicam with enhanced dissolution.

Tenoxicam is a poorly soluble nonsteroidal anti-inflammatory drug. In this work, the solubility of tenoxicam is enhanced using amorphous spray-dried dispersions (SDDs) prepared using two molar equivalents of l-arginine and optionally with 10%-50% (w/w) polyvinylpyrrolidone (PVP). When added to the dispersions, PVP is shown to improve physical properties and also assists in maintaining supersaturation in solution. The dispersions provide a twofold increase over equilibrium solubility at the same pH. The dispersions are characterized using electron microscopy, vibrational spectroscopy, diffuse-reflectance visible spectroscopy, and X-ray powder diffraction. The structures of the dispersions are probed using solid-state nuclear magnetic resonance (SSNMR) experiments applied to the (1) H, (13) C, and (15) N nuclei, including two-dimensional dipolar correlation experiments that detect molecular association and the formation of a glass solution between tenoxicam, l-arginine, and PVP. Other aspects of the amorphous structure, including hydrogen-bonding interactions and the ionization state of tenoxicam and l-arginine, are also explored using SSNMR methods. These methods are used to show that the SDDs contain an amorphous l-arginine salt of tenoxicam in a glass solution that also includes PVP when present. Finally, the dispersions show only a minor decrease in chemical stability during accelerated stability studies relative to a crystalline form of tenoxicam.

Characterization, selection, and development of an orally dosed drug polymorph from an enantiotropically related system.

Solid-state characterization methods are used to study a dimorphic pharmaceutical compound and select a form for development. Polymorph screening found that [4-(4-chloro-3-fluorophenyl)-2-[4-(methyloxy)phenyl]-1,3-thiazol-5-yl] acetic acid can crystallize into two non-solvated polymorphs designated Forms 1 and 2. Physical methods including vibrational spectroscopy, X-ray powder diffraction, solid-state NMR (SSNMR), thermal analysis, and gravimetric water vapor sorption are used to fully characterize the two polymorphs. Temperature-dependent competitive ripening experiments and solubility measurements indicated that the polymorphs in this system exhibit enantiotropy with a thermodynamic transition temperature of 35+/-3 degrees C. This complicates the selection of a polymorph to progress in drug development. Both forms had undesirable qualities; however, a particular drawback of Form 1 was found in its tendency to convert to Form 2 upon milling. Combining this effect and the desired formulation approach with physical property results led to a rationale for the choice of Form 2 for further development. Because this form is thermodynamically metastable at room temperature, analytical approaches were developed to ensure its exclusive presence, including a quantitative infrared spectroscopic method for drug substance and (13)C and (19)F solid-state NMR limit tests for the undesired form in drug product at drug loads of 8.3% (w/w).

Enantiotropically-related polymorphs of {4-(4-chloro-3-fluorophenyl)-2-[4-(methyloxy)phenyl]-1,3-thiazol-5-yl} acetic acid: crystal structures and multinuclear solid-state NMR.

Single crystal X-ray diffraction (SCXRD), powder X-ray diffraction (PXRD), and solid-state NMR (SSNMR) techniques are used to analyze the structures of two nonsolvated polymorphs of {4-(4-chloro-3-fluorophenyl)-2-[4-(methyloxy)phenyl]-1,3-thiazol-5-yl} acetic acid. These polymorphs are enantiotropically-related with a thermodynamic transition temperature of 35 +/- 3 degrees C. The crystal structure of Form 1, which is thermodynamically more stable at lower temperatures, was determined by SCXRD. The crystal structure of Form 2 was determined using PXRD structure solution methods that were assisted using two types of SSNMR experiments, dipolar connectivity experiments and chemical shift measurements. These experiments determined certain aspects of local conformation and intermolecular packing in Form 2 in comparison to Form 1, and provided qualitative knowledge that assisted in obtaining the best possible powder structure solution from the X-ray data. NMR chemical shifts for 1H, 13C, 15N, and 19F nuclei in Forms 1 and 2 are sensitive to hydrogen-bonding behavior, molecular conformation, and aromatic pi-stacking interactions. Density functional theory (DFT) geometry optimizations were used in tandem with Rietveld refinement and NMR chemical shielding calculations to improve and verify the Form 2 structure. The energy balance of the system and other properties relevant to drug development are predicted and discussed.

Accuracy and precision of quantitative energy-dispersive x-ray spectrometry in the environmental scanning electron microscope.

The accuracy and precision of quantitative energy-dispersive x-ray spectrometry in the environmental scanning electron microscope have been estimated using a series of copper / gold alloys of known composition. The mean values (five to six replicate experiments) had relative errors within +/- 5%, and most were within +/- 3.5%. All relative standard deviations were < 5% and most were < 3%. Since the standard specimens were large (approximately 500 microm) in diameter, electron scattering in the 2 torr of water vapor above the specimen did not affect the results. This level of accuracy and precision was possible only by using a novel specimen surface charge neutralization scheme.

Charge neutralization in the ESEM for quantitative X-ray microanalysis.

Quantitative chemical analysis by energy-dispersive X-ray spectrometry (EDS) in the environmental scanning electron microscope (ESEM) is difficult. This analysis is complicated by the spread of the electron beam by chamber gas molecules and the necessity for surface charge neutralization. Without charge neutralization, errors in quantitative analysis can range up to 15-20% relative. It is possible to achieve the error expected of traditional EDS, +/- 5% relative error, using a newly developed surface charge neutralization scheme for the ESEM. Estimates of accuracy and precision are based on studies of the National Bureau of Standards (now National Institutes for Science and Technology) Standard Reference Material 482, a series of certified copper-gold alloys. The scheme for charge neutralization requires an independent path to ground at or near the surface of the specimen. The current through the ground path must be maintained at zero by adjusting the voltage on the Gaseous Secondary Electron Detector when the sample chamber is at a gas pressure of 1-2 torr. This procedure forms the exact number of chamber gas positive ions to neutralize negative electrical charge on the specimen surface from electron bombardment.

Copper Oxide Precipitates in NBS Standard Reference Material 482.

Copper oxide has been detected in the copper containing alloys of NBS Standard Reference Material (SRM) 482. This occurrence is significant because it represents heterogeneity within a standard reference material that was certified to be homogeneous on a micrometer scale. Oxide occurs as elliptically to spherically shaped precipitates whose size differs with alloy composition. The largest precipitates occur in the Au20-Cu80 alloy and range in size from submicrometer up to 2 µm in diameter. Precipitates are observed using light microscopy, electron microscopy, and secondary ion mass spectrometry (SIMS). SIMS has demonstrated that the precipitates are present within all the SRM 482 wires that contain copper. Only the pure gold wire is precipitate free. Initial results from the analysis of the Au20-Cu80 alloy indicate that the percentage of precipitates is less than 1 % by area. Electron probe microanalysis (EPMA) of large (2 µm) precipitates in this same alloy indicates that precipitates are detectable by EPMA and that their composition differs significantly from the certified alloy composition. The small size and low percentage of these oxide precipitates minimizes the impact that they have upon the intended use of this standard for electron probe microanalysis. Heterogeneity caused by these oxide precipitates may however preclude the use of this standard for automated EPMA analyses and other microanalysis techniques.