Enhanced Oral Bioavailability of Felodipine from Solid Lipid Nanoparticles Prepared Through Effervescent Dispersion Technique.

Felodipine (FLD), a dihydropyridine calcium channel blocker with excellent antihypertensive effect, is poorly soluble and undergoes extensive hepatic metabolism, which lead to poor oral bioavailability (about 15%) and limit its clinic application. The goal of this study was to develop solid lipid nanoparticles (SLNs) loading FLD to improve the oral bioavailability. The FLD loaded solid lipid nanoparticles (FLD-SLNs) were prepared by the effervescent dispersion technique developed by our laboratory, which might have some advantages over traditional methods. The FLD-SLNs showed desired particle characteristics with particle size (198.15 ± 1.82 nm), poly dispersity index (0.26 ± 0.02), zeta-potential (- 25.53 ± 0.60 mV), entrapment efficiency (95.65 ± 0.70%), drug loading (2.33 ± 0.10%), and a spherical appearance. Pharmacokinetic results showed that the FLD-SLNs presented 3.17-fold increase in area under the curve (AUC(0-t)) compared with free FLD after oral administration in beagle dogs, which indicated that SLNs prepared using the effervescent dispersion technique can improve the bioavailability of lipophilic drugs like felodipine by enhancement of absorption and reduction first-pass metabolism.

Melt extrusion process for adjusting drug release of poorly water soluble drug felodipine using different polymer matrices.

The purpose of the present study was to use commercial available polymers like PVP/PEG, soluplus® and kollidon® SR to prepare immediate and sustained release formulations of felodipine by hot melt mixing method. Solid dispersions containing 5, 10, 20 and 30wt% drug have been prepared in a Haake-Buchler Reomixer at melt temperature 130°C and mixing time 10min. As was found from DSC and XDR studies completely amorphous and miscible solid dispersions can be prepared. In all cases a single glass transition was recorded, which is depended from the used drug amount. Hydrogen bonds and the molecular interaction between felodipine and polymer matrices are responsible for the miscibility of prepared formulations. This has as result the substantial enhancement of felodipine release rate in PVP/PEG mixture and due to the high solubility of used polymers immediate release formulations have been prepared. On the contrary, sustained release formulations can be prepared in the case of kollidon SR solid dispersions. The release mechanism of all preparations was studied using different kinetic models. Finally, binding affinity values calculated by molecular docking simulations were used as estimators for predicting long-term drug's physical stability in solid dispersions.

Synthesis, biological evaluation, calcium channel antagonist activity, and anticonvulsant activity of felodipine coupled to a dihydropyridine-pyridinium salt redox chemical delivery system.

3-(2-Hydroxyethyl) 5-methyl 1,4-dihydro-2,6-dimethyl-4-(2,3-dichlorophenyl)-3,5-pyridinedi-carboxyla te (7) was prepared using a modified Hantzsch reaction, which was then elaborated to 3-[2-[[(1-methyl-1,4-dihydropyrid-3-yl)carbonyl]oxy]ethyl]5-methyl 1,4-dihydro-2,6-dimethyl-4-(2,3-dichlorophenyl)-3,5-pyridinedicarboxylat e [10, felodipine-chemical delivery system (CDS)]. The equipotent 3-(2-hydroxyethyl) 7 (IC50 = 3.04 x 10(-8) M) and felodipine-CDS (10, IC50 = 3.10 x 10(-8) M) were, respectively, 2- and 21-fold less potent calcium channel antagonists than the reference drugs nimodipine (IC50 = 1.49 x 10(-8) M) and felodipine (IC50 = 1.45 x 10(-9) M). Compounds 7, 10, nimodipine, and felodipine are highly lipophilic (Kp = 236, 366, 187, and 442, respectively). 3-(2-Hydroxyethyl) 7, felodipine-CDS (10), and felodipine provided protection against maximal electroshock-induced seizures in mice but were inactive in the subcutaneous metrazol anticonvulsant screen. In vitro incubation studies of felodipine with rat plasma and 20% brain homogenates showed felodipine was very stable in both biological media. Similar incubations of felodipine-CDS showed its rate of biotransformation followed psuedo-first-order kinetics with half-lives of 15.5 h in rat plasma and 1.3 h in 20% rat brain homgenates. In vivo biodistribution of felodipine and felodipine-CDS was studied. Uptake of felodipine in brain produced a peak brain concentration of 5 micrograms/g of brain tissue at 5 min, after which it rapidly egressed from brain resulting in undetectable levels at 60 min. Peak blood concentrations of 10 occurred at about 7 min followed by a rapid decline to a near undetectable concentration by 17 min. The pyridinium salt species 9, resulting from oxidation of 10, also reached peak concentrations at about 7 min but it slowly decreased to undetectable concentrations at 2 h. 3-(2-Hydroxyethyl) 7 remained at near undetectable concentrations throughout a 2 h time period. Localization of 10 in brain provided a peak concentration of 4.2 micrograms/g of brain tissue at 5 min and then decreased to negligible concentrations at 15 min. The concentration of oxidized pyridinium species 9 in brain remained high providing detectable concentrations up to 4 days. In contrast, the concentration of the 3-(2-hydroxyethyl) hydrolysis product 7 in brain remained at very low levels throughout the study. The slow hydrolysis rate of the pyridinium ester 9 to the 3-(2-hydroxyethyl) 7 and the rapid egression of felodipine-CDS from brain are believed to contribute to the moderate anticonvulsant activity exhibited hy the felodipine-CDS (10).