Tailoring crystal size distributions for product performance, compaction of paracetamol

Paracetamol crystals often exhibit poor compressibility properties, which results in capping issues. The Particle Size Distribution (PSD) of paracetamol was engineered to improve the compressibility of paracetamol crystals. This was accomplished by growing paracetamol crystals in the presence of additives. The active pharmaceutical ingredient Phenacetin and impurity 4-chloroacetanalide were used to modify the crystal properties of paracetamol. In solution, the phenacetin or 4-chloroacetanalide molecules adsorb onto the paracetamol crystal faces selectively (110 or 011) and inhibit the further growth of the paracetamol crystal and consequently, the paracetamol crystal growth is reduced substantially. For controlling the PSD of crystal to improve the compressibility of paracetamol crystals, a set of cooling crystallization experiments in the presence of additive was designed. According to a statistical experimental design, the cooling rate was the most effective parameter. The PSD was reduced when paracetamol crystallized from the controlled crystallization in the presence of less than 3 mol% of both additives. These smaller particles increased almost fourfold the compressibility of paracetamol in comparison to the commercial material. Moreover, tablets were prepared for each formulation using a direct compaction method. The results illustrated that a higher tablet hardness of paracetamol was achieved by tailoring the paracetamol crystal size distribution. In addition, the tablet disintegration time was higher for the formulation with increased hardness. Overall, this work presents the potential use of structurally similar compounds as additives to alter the mechanical properties of an API. (C) 2021 The Author(s). Published by Elsevier B.V.

Automated summary

This study engineered the Particle Size Distribution (PSD) of paracetamol crystals using additives to improve compressibility properties. Cooling crystallization experiments revealed that the cooling rate was the most effective parameter in controlling PSD. By tailoring crystal properties through controlled crystallization, smaller particles were obtained which significantly enhanced the compressibility of paracetamol. Tablets with improved hardness and longer disintegration time were prepared using direct compaction method. Overall, this work demonstrates the potential use of structurally similar compounds as additives to modify the mechanical properties of active pharmaceutical ingredients.