Effect of Drug Loading in Mesoporous Silica on Amorphous Stability and Performance

Christoffer G. Bavnhøj, Matthias M. Knopp, Korbinian Löbmann*

*Corresponding author for this work

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2 Citations (Scopus)
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Abstract

The encapsulation of drugs within mesoporous silica (MS) has for several years been a subject of research. Previous studies proposed that drug loadings up to the monomolecular loading capacity (MLC) are the optimal choice for maintaining the drug in an amorphous form, whereas filling the pores above the monolayer and up to the pore filling capacity (PFC) may introduce some physical instabilities. The aim of this study was to assess the effect of drug loading in MS-based amorphous formulations on the stability of the amorphous form of the drug as well as the dissolution. In particular, the following drug loadings were investigated: below MLC, at MLC, between MLC and PFC and at PFC. The drug-loaded MS formulations were analyzed directly after preparation and after 18 months of storage under accelerated conditions (40 °C in both dry and humid conditions). The MLC and PFC for the drug celecoxib (CEL) on the MS ParteckSLC500 (SLC) were determined at 33.5 wt.% and 48.4 wt.%, respectively. This study found that SLC can effectively preserve the amorphous form of the drug for 18 months, provided that the loading is below the PFC (<48.4 wt.%) and no humidity is present. On the other hand, drug loading at the PFC showed recrystallization even when stored under dry conditions. Under humid conditions, however, all samples, regardless of drug loading, showed recrystallization upon storage. In terms of dissolution, all freshly prepared formulations showed supersaturation. For drug loadings below PFC, a degree of supersaturation (DS) around 15 was measured before precipitation was observed. For drug loadings at PFC, the DS was found to be lower and only 6-times compared to the crystalline solubility. Lastly, for those samples that remained amorphous during storage for 18 months, the release profiles were found to be the same as the freshly loaded samples, with similar Cmax, Tmax and dissolution rate.

Original languageEnglish
Article number163
JournalPharmaceutics
Volume16
Issue number2
Number of pages11
ISSN1999-4923
DOIs
Publication statusPublished - 2024

Bibliographical note

Publisher Copyright:
© 2024 by the authors.

Keywords

  • amorphous stability
  • differential scanning calorimetry (DSC)
  • dissolution
  • loading capacity
  • long-term stability
  • mesoporous silica
  • poorly soluble drugs
  • pore volume
  • surface area

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