THE EFFECT OF CO-FORMER AND TABLET EXCIPIENT ON SOLUBILITY AND DISSOLUTION OF NIMODIPINE
Nimodipine (NMP) belongs to class II Biopharmaceutics Classification System (BCS) with the typical characteristics of high permeability and poor solubility. The poor dissolution behavior of nimodipine was considered as the substantial factor limiting its oral absorption and will affect the bioava...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/33146 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Nimodipine (NMP) belongs to class II Biopharmaceutics Classification System
(BCS) with the typical characteristics of high permeability and poor solubility.
The poor dissolution behavior of nimodipine was considered as the substantial
factor limiting its oral absorption and will affect the bioavailability. NMP exists
into two polymorphic forms known as modification I and II (mod I and II). Mod I,
available on the market, is a metastable form. Mod II is the stable form. Solid
state transformation can occur in formulations due to processing, such as solvent
recrystallization, milling, heating, and compression. Phase transformation could
affect the physical properties such as internal structure, melting point, solubility,
dissolution, and compressibility. For the active ingredients available in the form
of metastable polymorphs and belonging to BCS Class II it is necessary to
observe the occurrence of polymorphic transformation to ensure the quality of the
final product.
Efforts to increase solubility can be done by crystal engineering method. Crystal
engineering through the cocrystallization process between the active ingredients
with cocrystal former. Cocrystal compounds reported to improving its solubility,
dissolution rate, stability, bioavailability, and compressibility properties of the
active ingredients. The selection of coformer compounds and their method of
manufacture greatly influences the success of the formation of cocrystal
compounds.
The existence of excipients and mechanical energy caused by the manufacturing
process can affect the solubility and dissolution rate of the active ingredient. The
rate of NMP dissolution has been reported differently for each batch of
production. For problematic ingredients in the tablet dissolution is necessary to
study the effect of excipients on the dissolution rate.
The aim of this study was to reveal the physical phenomena that occur in an effort
to improve solubility and dissolution of NMP through crystal engineering
techniques using pharmaceutical coformer compounds and with the addition of
excipients as diluent.
This research was a multi-stage process that consisting of NMP characterization
and the effect of solvent crystallization, study of thermal and mechanical energy
on NMP, crystal engineering for solubility improvement starting with coformer
selection, screening, and characterization of interaction, and dissolution test, the
influence of excipients which function as diluent to increase solubility and
dissolution rate of NMP.
NMP was characterized by the matching of PXRD diffractogram, DSC
thermogram, and FTIR, compared with the reference. Then the solids were
subjected to the treatment of milling, heating, recrystallization at solvent, and
compression. The results were characterized by PXRD, DSC, FTIR, polarization
microscope, and SEM. The grinding process for 15, 30, 60, and 120 minutes does
not cause polymorphic transformation in NMP solids. Solubility and dissolution
rate were not significantly different. The one-hour heating process at 60, 125, and
150ºC did not result in polymorphic transformation. The process of recrystallizing
through 60-minute dissolution with the aid of magnetic stirrer in organic solvents
(ethanol, methanol, and acetone) leads to partial modification of polymorphic
modifications I to II.
The compression process of single NMP with various pressure from 4.9 to 29.4
kN did not result in polymorphic transformation, but sintering (loss of surface
boundary due to particle joining) occurs on the surface and tablet fracture. The
greater the compression strength, the larger the sintering occurance. As a result of
this sintering, the water molecules can not penetrate the surface of the tablet so
that the tablet does not disintegrate in the disintegration test.
Efforts to increase NMP solubility are made through crystalline engineering for
the formation of cocrystal compounds between NMP and coformers. Selection of
coformer based on sinton owned. Several selected coformers were followed by a
cold contact method and their PXRD measurements. From the results of screening
and characterization performed, the crystals can only form between NMP with
isonikotinamide (INA). The pattern of PXRD diffractogram of NMP and INA
differs from the original compound. The binary phase diagram between NMP and
INA shows the crystals formed at a 1: 1 molar ratio. The DSC thermogram shows
a 112ºC cocrystal melting point, lower than the second melting point of the
starting compound. However, the solubility test showed no significant solubility
change.
Based on the characterization due to compression treatment of NMP causing
sintering and dissolution rate difference, a study of the effect of the existence of
excipients as a filler to the rate of NMP dissolution. Preferred excipients are ?-
lactose monohydrate and microcrystalline cellulose (MCC) with ratio NMP:
excipients 10:90, 20:80, and 30:70 w/w. Tests for NMP:excipients were
performed on a physical mixture, the mixture was milled, the mixture compressed
into tablets, and the powder tablet. NMP and excipient mixtures were
characterized by PXRD and SEM as well as dissolution tests. Diffractogram
PXRD mixture showed no change or diffraction peak shift. Dissolution tests show
that the greater the number of excipients used the higher the number of NMPs it
isolates. Treatment in the form of milling, compression, or compression and
milling combined affects the number of deformed. In general, ?-lactose
monohydrate increases dissolution rate better than MCC in all treatments.
This study has revealed the phenomenon that occurs due to the various effects of
manufacturing processes on the physical properties of NMP solids. In an effort to
increase the NMP solubility through crystal engineering formed between NMP-
INA crystals but not yet able to improve solubility and NMP dissolution. The
addition of excipient and the effect of mechanical energy to the NMP-excipient
mixture can increase solubility and NMP dissolution even closer to the dissolution
of innovator tablets.
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