LITERATURE REVIEW OF NSAID COCRYSTALS AND PILOT SCALE EXPERIMENT OF SODIUM MEFENAMIC NICOTINAMIDE AS POTENTIAL SALT COCRYSTAL
ii The formation of cocrystal can modulate active pharmaceutical ingredients with poor physicochemical and solid physical properties. This study aims to conduct a literature review on the development of nonsteroid anti inflammation (NSAID) cocrystal in general and to conduct pilot scale-up exper...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/56616 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | ii
The formation of cocrystal can modulate active pharmaceutical ingredients with
poor physicochemical and solid physical properties. This study aims to conduct a
literature review on the development of nonsteroid anti inflammation (NSAID)
cocrystal in general and to conduct pilot scale-up experiments of sodium mefenamic
nicotinamide (SMN) cocrystal salt. This literature review describes the progress
and challenges that occur in the development of NSAID cocrystal. Sources of
information were obtained by using “NSAID co-crystalline”inclusion criteria
through search engines, namely ScienceDirect, Google Scholar, PubMed,
American Chemical Society (ACS) publication. Based on the literature review, it
was known that researches on NSAID cocrystal have been developed in various
methods to produce better cocrystal. In the development of NSAID cocrystal, there
are many challenges, such as coformer selection, improvement of solubility and
intrinsic dissolution rate, changes in pH, changes instability, and formation of
polymorphisms. In this experiment, scaling up was carried out with the solvent drop
grinding (SDG) method using a blender with a capacity of 5g, 10g, 25 g to produce
a solid sample of 100 g. The SDG method was chosen because it can produce
homogeneous cocrystal faster, easier, and less expensive; with maximum yield, and
reducing the use of organic solvents compared to the solvent evaporation (SE)
method. Ethanol was chosen because it is most safe compared to other organic
solvents. Optimization of the SDG method with the blender was carried out to
obtain the mixing technique, the amount of solvent, and the best time. The results
of the scaleup were then characterized by solid analysis using thermal analysis
(electrothermal and DSC), FTIR, and PXRD. Furthermore, the characterization of
powder was carried out by testing the flow rate and compressibility of the SMN 25
g. Based on the results of the research, the SMN scale-up method with a blender
can be done by directly mixing mefenamic acid, sodium hydroxide, and
nicotinamide equimolar ratio 1: 1: 1 with the amount of solvent (70% ethanol) 3
mL for 5g SMN in a blender time of 1 minute, 7 ml. for 10g SMN and 14.2 ml for
25g SMN in 4 minutes. Characterization and evaluation of solids concluded that
the scale-up of SMN could be formed by mechanical methods using SDG using a
blender with better flow properties and compressibility compared to sodium
mefenamic salt (SM).
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