Amorphous drug nanoparticles usually
exhibit low storage stability.
A comprehensive understanding of the molecular states and physicochemical
properties of the product is indispensable for designing stable formulations.
In the present study, an amorphous cyclosporin A (CyA) nanosuspension
with a mean particle size of approximately 370 nm was prepared by
wet bead milling with poloxamer 407 (P407). Interestingly, the prepared
amorphous CyA nanoparticles were transformed into uniform CyA nanocrystals
with a reduced mean particle size of approximately 200 nm during storage
at 25 °C. The CyA nanocrystals were stably maintained for at
least 1 month. The particle morphologies and molecular structures
of the CyA nanosuspensions before and after storage were thoroughly
characterized by cryogenic transmission electron microscopy and magic-angle
spinning nuclear magnetic resonance spectroscopy, respectively. They
revealed that the freshly prepared amorphous CyA nanoparticles (∼370
nm) were secondary particles composed of aggregated primary particles
with an estimated size of 50 nm. A portion of P407 was found to be
entrapped at the gaps between the primary particles due to aggregation,
while most of P407 was dissolved in the solution either adsorbing
at the solid/liquid interface or forming polymeric micelles. The entrapped
P407 is considered to play an important role in the destabilization
of the amorphous CyA nanoparticles. The resultant CyA nanocrystals
(∼200 nm) were uniform single crystals of Form 2 hydrate and
showed corner-truncated bipyramidal features. Owing to the narrow
particle size distribution of the CyA nanocrystals, the rate of Ostwald
ripening was slow, giving long-term stability to the CyA nanocrystals.
This study provides new insights into the destabilization mechanism
of amorphous drug nanoparticles.