Abstract
To improve drug product quality, the size and shape of active pharmaceutical ingredient (API) crystals need to meet tight specifications, in part determined by downstream manufacturing requirements. Improved critical quality attributes may also lead to better solubilisation and bioavailability during drug product delivery. Milling-aided crystallisation is a practical means to reduce the mean particle size and aspect ratio to meet these requirements and to improve downstream manufacturability. Other methods to control crystal shape employ temperature cycling during solution state crystallisation, e.g. Direct Nucleation Control (DNC) may be used to alter the particle morphology and size distribution through successive heating-cooling cycles for dissolution and recrystallisation. In this work, the process objective is to target uniformly sized, equant shaped crystals with enhanced bioavailability using DNC crystallisation, integrated with either external loop and in-situ wet-milling. Experiments were conducted using mefenamic acid in 2-butanol, starting with a benchmark case of batch crystallisation with a linear cooling profile. This allowed identification of suitable DNC set-points, which were then implemented using closed-loop feedback control, based on sensing the FBRM counts. DNC is shown to be capable of improving crystal shape, but additional control is added by applying wet-milling to reduce crystal size. Application of wet-milling, combined with DNC was effective in reducing the crystal size D90 < 50 mm and reducing the aspect ratio. The wet-milling approaches were compared in terms of cycle time and final crystal size and shape, by varying the wet-milling speed, with targeted counts specified for the DNC set-point. The external wet-mill aided DNC crystallisations reached a steady-state with reduced cycle time and improved crystal morphology, in comparison with in-situ wet-mill aided DNC processes.
Highlights
The aspect ratio of needle-shaped crystals is modified by polypropylene glycol (PPG), which acts as growth blocking agent on selected crystal faces
FBRM counts #/s, Temperature and concentration profile and in situ PVM images showing the crystals at the end for: (a) and (b) Linear cooling crystallization of lovastatin/ethyl acetate (c) and (d) Lovastatin/ethyl acetate/PPG-4000 with mill-aided, DNC + T-cycling crystallization (e) and (f) Lovastatin/ethyl acetate/PPG-4000 with seeded, DNC + T-cycling crystallization
▪ Shape modification is achieved by using additives + temperature cycling resulting in decorrelating growth and dissolution, which overall inhibit growth along the a-axis at [100]
Summary
The aspect ratio of needle-shaped crystals is modified by polypropylene glycol (PPG), which acts as growth blocking agent on selected crystal faces. The fastest growth path along the [100] direction is suppressed while the [010] direction indicating distinctively growth gives spindle body shape. The images show that growth from solution is disrupted on some surfaces resulting in an uneven microstructure, whilst growth on other planes remain relatively flat
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