Compaction properties of crystalline pharmaceutical ingredients according to the Walker model and nanomechanical attributes

• Published in: International journal of pharmaceutics Vol. 472; no. 1-2; pp. 347 - 355
• Main Authors: Egart, M., Ilić, I., Janković, B., Lah, N., Srčič, S.
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 10.09.2014
• Subjects: Benzodiazepines - chemistry; Compactibility; Compressibility; Compressive Strength; Crystallization; Elasticity; Famotidine - chemistry; Hardness; Indentation hardness; Models, Theoretical; Nanoindentation; Nifedipine - chemistry; Piroxicam - chemistry; Walker coefficient; Young’s modulus; Walker coefficient; Young’s modulus; Compressibility; Compactibility; Indentation hardness; Nanoindentation
• ISSN: 0378-5173; 1873-3476
• DOI: 10.1016/j.ijpharm.2014.06.047

[Display omitted] This study investigates the extent to which single-crystal mechanical properties of selected active ingredients (famotidine, nifedipine, olanzapine, piroxicam) influence their bulk compressibility and compactibility. Nanomechanical attributes of oriented single crystals were determined with instrumented nanoindentation, and bulk deformational properties were assessed with the Walker and Heckel models as well as the elastic relaxation index. Good correlations were established between bulk and single-crystal plasticity parameters: the Walker coefficient and indentation hardness. The Walker model showed more practical value for evaluating bulk deformational properties of the APIs investigated because their properties differed more distinctly compared to the Heckel model. In addition, it was possible to predict the elastic properties of the materials investigated at the bulk level because a correlation between the elastic relaxation index and compliance was established. The value of using indentation hardness for crystalline APIs was also confirmed because their compactibility at the bulk level was able to be predicted. Mechanically interlocked structures were characteristic of most polymorphic forms investigated, resulting in single crystals having isotropic mechanical properties. It was revealed that in such cases good correlations between single and bulk mechanical properties can be expected. The results imply that innate crystal deformational properties define their compressibility and compactibility properties to a great extent.