AI Article Synopsis
- Celecoxib nanocrystalline solid dispersion (CEL_NCSD) was created using spray drying techniques with mannitol and sodium lauryl sulfate.
- The study aimed to determine the size of CEL nanocrystals and investigate their agglomeration and dissolution.
- Results showed that CEL nanocrystals were embedded within mannitol, revealing an average size of 882 nm and highlighting that their dissolution profile was significantly better than that of larger microsuspensions.
Article Abstract
Celecoxib (CEL) Nanocrystalline Solid Dispersion (CEL_NCSD) was generated by spray drying CEL, mannitol (MAN) and sodium lauryl sulfate (SLS) from a solvent mixture of methanol, acetone and water. The purpose of the work was to determine the size of CEL nanocrystals, investigate agglomeration and inspect dissolution of CEL_NCSD. Size determination was challenging as CEL nanocrystals are embedded in the matrix of MAN. Firstly, neat CEL_NCSD was analyzed using Scherrer equation. Secondly, MAN was dissolved in an aqueous stabilizer medium to selectively measure the size of CEL nanocrystals. Raman Spectra captured in Morphologi G3-ID confirmed the presence of CEL-only particles in the media. This dispersion gave D values of 882 ± 170.34 nm in Zetasizer. Discriminatory dissolution studies confirmed total release of 34.61 ± 1.59%, 47.42 ± 0.24%, and 44.61 ± 1.11% at 120 min from a microsuspension (size 3 µm), a nanosuspension (media milled; size 660 nm) and CEL_NCSD, respectively. The dissolution profile of CEL_NCSD was similar to that of a nanosuspension (f2 72.24) instead of a coarse microsuspension. Thus, the present study revealed that optimized sample preparation is critical for the size determination of embedded drug nanocrystals in NCSD. Further, a discriminatory dissolution study substantiated that the size of CEL nanocrystals in CEL_NCSD is well below 1000 nm, thus showing a size-dependent improved dissolution profile.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6835401 | PMC |
| http://dx.doi.org/10.3390/pharmaceutics11100516 | DOI Listing |
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