ABSTRACT
In this study we aim to explore the potential links between the mechanical properties, micronisation behaviour and surface energy of carbamazepine polymorphs using atomic force microscopy (AFM) measurements of material properties at the nanoscale. Carbamazepine Forms I, II and III were prepared and confirmed using X-ray powder diffraction (XRPD). AFM measurements of indentation hardness, Young's modulus and surface energy were made on the starting material. In addition, the surface energy was measured immediately after micronisation and after storage for four weeks. Carbamazepine polymorphs could be ranked by Young's modulus and hardness. Surface energy measurements showed an increase after micronisation in all cases, and a varying relaxation after storage for four weeks. Form I showed a smaller particle size distribution, indicating more complete micronisation. A promising correlation was observed between the hardness/Young's modulus ratio and the micronisation behaviour, in terms of particle size reduction and surface energy change. The results show potential for the predictive capacity of such an approach, and help to provide a greater understanding of material behaviour and properties during micronisation.
Subject(s)
Carbamazepine/chemistry , Microscopy, Atomic Force , Particle Size , Chemical Phenomena , Chemistry, Pharmaceutical , Crystallization , Elastic Modulus , Hardness , Microscopy, Electron, Scanning , Surface Properties , X-Ray DiffractionABSTRACT
A high pressure differential scanning calorimeter (HP-DSC) has been used to investigate the pressure dependence of the melting of the monoclinic (Form I) and orthorhombic (Form II) polymorphs of paracetamol (acetaminophen). DSC scans obtained at ambient pressure show that the stable monoclinic form melts at 442 K while the metastable orthorhombic form melts at 430 K. HP-DSC scans obtained for pressures up to about 450 MPa show that the melting temperatures of both Forms I and II increase with increasing pressure, but the latter more rapidly than the former. This results in a cross-over at about 250 MPa, where the two forms have approximately the same melting temperature, while at higher pressures Form II becomes the more stable phase. Although no solid-solid transitions have been observed, the coordinates of the I-II-liquid triple point have been found experimentally (p = 258.7 MPa and T = 489.6 K) for the first time, and confirm those predicted by Espeau et al. from a topological p-T diagram based on theoretical arguments and experimental data at ambient pressure.
