dc.description.abstract |
This report provides chemistry of salbutamol sulphate, tramadol hydrochloride,
diclofenac sodium and ethylcellulose, physics of drug release through particle wall
and use of microparticles in life sciences. Microparticles of salbutamol sulphate were
prepared by using three different microencapsulation techniques i.e. coacervation
thermal change, solvent evaporation and coacervation non-solvent addition by
adjusting the ratio of drug to ethylcellulose. Salbutamol sulphate microparticles were
compared with the microparticles of diclofenac sodium and tramadol hydrochloride
and characterized by micromeritics, SEM, FTIR, X-RD, dissolution and thermal
studies. The microcapsules were then compressed into tablets to study the variation of
drug release between microcapsules and tabletted microcapsules. In vitro release
profiles of prepared microcapsules and tabletted microcapsules were studied using
USP XXIV dissolution apparatus I and II, respectively, in 450 ml double distilled
water at 50 rpm maintained at 37°C. Microparticles were whitish, irregular in
morphology and aggregated with good stability, fine rheological properties and
excellent encapsulation efficiency. Percentage yield was almost greater than 90% in
each batch. Initial burst effect was observed in the release pattern of tramadol
hydrochloride and salbutamol sulphate formulations. No strong chemical interaction
was observed between the drugs and polymer in microparticles. The release of drug
from their respective formulations was sustained in the following rank: diclofenac
sodium > salbutamol sulphate > tramadol hydrochloride. Polymer concentration and
sustained release behavior were found to be directly proportional to each other. A
slight increase in actual drug loading but profound increase in mean diameter of
microcapsules was observed with an increase in the viscosity of ethylcellulose. The
rate of drug release from microparticles decreased as the concentration of
2Abstract
polyisobutylene was increased from 6% to 12% during microencapsulation. UV and
FTIR spectroscopy, x-ray diffractometry and thermal analysis showed that
ethylcellulose did not interact with these drugs. The release pattern of tabletted
microparticles was affected significantly (p <0.05) by the addition of HPMC as
excepient and insignificantly (p >0.05) by the type of dissolution media and stirring
speed. All the batches of tablets showed good stability and reproducibility. Release
profiles were evaluated by model-dependent and model independent approaches. The
drug release from all the formulations was best explained by Higuchi’s equation, as
the plots showed highest linearity, followed by zero order and first order. The
mechanism of drug release was anomalous diffusion from all formulations. Non-
solvent addition phase separation was found to be a suitable method to develop
ethylcellulose based multi-unit controlled release drug delivery system.
A sensitive reverse phase-high performance liquid chromatography (RP-HPLC)
method with fluorescent detector (FLD) was developed and optimized for salbutamol
sulfate determination in human plasma. In this regard, mobile phase specifications,
extraction procedures, excitation and emission wavelengths were optimized. The
HPLC system consisted of a Lichrosorb RP-C18 analytical column (4.6 × 200 mm, 5
μm) with FLD operated at excitation 228 nm and emission 310 nm. Mobile phase
{CH 3 OH / (NH 4 )H 2 PO 4 (67 mM)(pH 3.0) / Triethylamine (TEA), 50 / 50 / 0.02
(v/v/v%)} was run at a flow rate of 0.7 mL/min. To clean up samples, a liquid-liquid
extraction (LLE) procedure was selected and optimized. Salbutamol sulphate and
tramadol hydrochloride eluted at 4.1 and 5.2 minutes respectively. Adequate
extraction efficiency was achieved by DEHP (75.88-85.52%). The standard curve was
linear for the range tested (0.5–80 ng/mL) and the coefficient of determination was
0.9989. A detection limit of 0.17 ng/mL was achieved. The intra- and inter-day
3Abstract
precision was less than 4%. The present assay combines adequate accuracy and
precision with sensitivity for salbutamol sulphate determination in human plasma and
can be applied to study pharmacokinetics of salbutamol sulphate sustained release
tablets after oral administration in human.
A good linear correlation (R 2 = 0.9224, 0.945, 0.9363 and 0.9694 for T 1 , T 2 , T 3 and
reference formulations, respectively) was obtained between the percent cumulative
drug released (in vitro) and the percent cumulative drug absorbed (in vivo) data of
these formulations at specific time points to develop level A in vitro-in vivo
correlation that shows a reliable prediction of the plasma concentrations obtained
following a single dose.
Keywords:
Coacervation, Solvent evaporation, Viscosity grade, Salbutamol sulphate, Tramadol
hydrochloride, Dissolution, Diclofenac sodium, Ethylcellulose, Characterization,
Method optimization, RP-HPLC method, Fluorescent detection, Ion-pair extraction,
Calibration curve, Internal standard, In-vitro and in-vivo correlation. |
en_US |