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The aim of this study was to prepare and evaluate the impact of polymers on
fabricating stable dexibuprofen (Dexi) and domperidone nanocrystals with enhanced
therapeutic potential, using a low energy, anti-solvent precipitation method (APSP).
Combinations of Hydroxypropyl methyl cellulose-Polyvinyl pyrrolidone and
Hydroxypropyl methyl cellulose-Eudragit were shown to be very effective in
producing stable dexi-nanocrystals with particle sizes of 85.0±2.5 nm and 90±3.0 nm,
and polydispersity of 0.179± 0.01, 0.182± 0.02 respectively. Produced nanocrystals of
DOMP and Ethucel combination, the average particle size and polydespersity index
were found to be approximately 130.00 ± 3.0 nm, 0.15 ± 0.01, moreover, the
combination of hydroxyl propyl methyl cellulose and polyvinyl alcohol also found
very affective to produce DOMP nanocrystals with small particle size (200.0 ±3.5nm)
and PDI (0.2±0.02). The stability studies conducted for 90 days demonstrated that
nanocrystals stored at 2-8°C and 25°C were more stable than those at 40°C. The
maximum recovery of dexi-nanocrystals was observed from the formulations using
the combination of Hydroxypropyl methylcellulose- Polyvinyl pyrrolidone and
Hydroxy propyl methyl cellulose- Eudragit, which equated to 98% and 94% of the
nominal active drug content respectively. In case of DOMP nanosuspensions stored at
2-8 ºC and room temperature (25 ºC) exhibited higher stability compared to the
samples stored at 40 ºC. Crystallinity of the processed and unprocessed dexi and
DOMP particles was confirmed using Differential Scanning Calorimetry, Powdered
X-ray Diffraction and Transmission Electron Microscope. FTIR studies for both Dexi
and DOMP nanocrystals confirmed that the process did not affect chemical integrity
of DOMP. The DOMP nanoparticles exhibited significantly enhanced dissolution rate
(P<0.05) compared to the raw counterpart. The saturation solubility of the
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dexinanocrystals was substantially increased to 270.0±3.5 µg/mL compared to the
raw dexi in water (51.0± 2.0μg/mL) and stabilizer solution (92.0 ± 3.0 μg/mL).
Enhanced dissolution rate (P<0.05) was observed for the dexi-nanocrystals compared
to the unprocessed drug substance and marketed tablets. The saturation solubility of
the DOMP nanocrystals was significantly increased to 2700.0± 3.5 µg/mL compared
to the raw dexi in water (952.0± 2.0μg/mL) and stabiliser solutions which include
HPMC (1253.0± 3.5) and HPMC-PVA (1133.0 ± 3.5 µg/ml). DOMP nanocrystals
resulted in enhanced dissolution rate (P<0.05) compared to the unprocessed drug
substance. Molecular Modeling studies underpinned and substantiated the
experimental studies, including the impact of polymers on nanoparticle sizes,
nanocrystals recovery and stability studies of the produced dexinanocrystals. The
highest potential was shown by combination of HPMC-PVP- Dexi (-4.7) and HPMC
EUD- DEXi (-4.6) . In case of DOMP, Molecular Modelling studies underpinned the
molecular level understanding of the DOMP-Polymer nanocrystal interaction and
substantiated the experimental studies, including the impact of polymers on
nanocrystals sizes, and stability studies of the produced DOMP nanocrystals. Ethocel
as single polymer showed highest binding potential (-27.26±0.24 ) for DOMP
nanocrystals and HPMC-PVA was found the best dimer to effectively bind (-25.22 ±
0.79) with the nanocrystals with subsequent small particle size and high stability
profile. The findings of the nociceptive assay showed that the dexinanocrystals
exhibited significant analgesia, compared to the raw dexibuprofen and the control
standard diclofenac sodium. The analgesic effect was, however, produced at much
lower doses (5mg/kg) than that of control standard, diclofenac sodium (20mg/kg) and
dexibuprofen counterparts (40 mg/kg). While the activity results in anti-emetic assay
confirmed that the nano-formulation provided significant anti-emetic effect (P< 0.05)
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at a dose of 0.5 mg/kg, comparable to that of the unprocessed DOMP and the control
standard Metoclopramide administered at the doses of 1.0m/kg and 30mg/kg
respectively. However, DOMP nanoparticles showed the anti-emetic effect at lower
doses compared to that of control standard and unprocessed DOMP. Furthermore,
there was observed a substantial % increase of antiemetic potential for DOMP
nanoparticles compared to the unprocessed DOMP and the standard metoclopramide. |
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