LITERATURE REVIEW OF AMINO ACID AS A POTENTIAL COFORMER AND EXPERIMENT OF PILOT SCALE UP OF SALT COCRYSTAL DICLOFENAC SODIUM PROLINE
The physicochemical properties of active pharmaceutical ingredients (API), especially solubility and permeability, are the important factors that affect the bioavailability of a pharmaceutical preparation. However, most of the API that has been founded has low solubility and/or permeability. Cocr...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/56615 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The physicochemical properties of active pharmaceutical ingredients (API),
especially solubility and permeability, are the important factors that affect the
bioavailability of a pharmaceutical preparation. However, most of the API that has
been founded has low solubility and/or permeability. Cocrystal preparation is one
of the most popular ways to modify the physicochemical properties through noncovalent interactions between API and coformer, without changing its
pharmacological properties. This study summarizes the literature review on amino
acids as coformers and experiments regarding the scale up of manufacture of
diclofenac sodium-L-proline cocrystal (NDP) which previously reported its
structure and ability to increase the solubility of diclofenac sodium by more than
three times. The literature review aims to observe the development of the use of
amino acids as a potential coformer that is safer than other chemical coformers
while still providing the desired physicochemical properties modification. Review
material is obtained from searches with search engines: Google Scholar, Pubmed,
Science Direct, and ACS (American Chemical Society) Publications using the
following keywords: amino acids, cocrystal, coformer, and L-proline. The collected
journals were selected according to inclusion criteria, which are: national and
international journals published in the last 10 years (2010-2020), discussed about
cocrystal development using amino acids as coformer and their influence on the
physicochemical properties of API. Amino acids are considered promising
coformers due to their functional groups that can form strong hydrogen bonds from
their zwitterionic groups. From the selected result, 103 journals were obtained for
analysis and it was concluded that amino acids, especially L-proline (LP), are a
safe coformer and support the concept of the ‘green method’and can increase the
solubility, permeability, and stability of API. This is because LP is soluble in water
and has a hydrotropic effect, which is the ability to dissolve hydrophobic molecules.
In addition, the presence of a pyrrolidine ring causes the LP structure to be stiff
which contributes to its superior stabilization ability compared to other coformers.
The research was continued with laboratory experiment that aim to develope a pilot
scale up method for manufacture of NDP salt cocrystal to obtain products on a
bigger scale, which were then observed for their flowability and compressibility
properties. Previous studies have shown that NDP can be produced by both the
solvent evaporation (SE). However, scaling up using the SE method requires a lot
of solvent, so it is less desirable. The solvent-drop grinding (SDG) method is
preferred due to less solvent used and can produce cocrystal in a shorter time than
neat grinding (NG) or SE. In this experiment, a study of NDP formation was carried
out using the SDG method and the scale up was carried out with SDG method using
a bender which represents a mixing device used in the medicinal raw material
industry. Optimization of the amount of solvent and mixing time of the diclofenac
sodium and LP components in a blender was carried out until the NDP salt
cocrystal was obtained according to what had been reported. The resulting
cocrystal was characterized using Fourier Transformed Infrared (FTIR),
Differential Scanning Calorimetry (DSC), Powder X-Ray Diffraction (PXRD), and
Scanning Electron Microscope (SEM). The result of the experiment found that the
SDG with conventional mortar method can be used to produce NDP salt cocrystal
and the SDG-blender method produces NDP salt cocrystal with the optimal amount
of ethanol (96%) of 0,5 mL/g in 2 minutes, at a rotating speed of 20000 rpm. The
scale up was carried out in stages, starting from 5 g, 10 g, 15 g, and 25 g each
production batch. From the various optimizations, 100 g of NDP salt cocrystal had
been collected. After the cocrystal is characterized, the cocrystal formed by the
SDG with conventional mortar method in small amounts and the SDG-blender
method that produce up to 25 g had a melting point, DSC, and PXRD corresponding
to the tetrahydrate form, similar to those previously reported. SEM observation
showed that those method has the same morphology. Thus, it can be concluded that
the SDG-blender method was successfully used for scaling up the formation of NDP
cocrystal. The formation of cocrystal shows better flowability and compressibility
properties than diclofenac sodium.
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