Nanoemulsified orlistat-embedded multi-unit pellet system (MUPS) with improved dissolution and pancreatic lipase inhibition.

The present research work explores an innovative technological solution to constraints in efficient oral delivery of poorly water-soluble anti-obesity drug orlistat. Nanoemulsion of orlistat and its subsequent transformation into multi-unit pellet system (MUPS) for improved oral delivery was developed. Orlistat nanoemulsion was developed with capryol PGMC as an oil phase and cremophor RH40 as an emulsifier using high-pressure homogenization. Influence of critical processing parameters on globule size distribution, polydispersity index and physical stability of nanoemulsion was evaluated. The optimized nanoemulsion was transformed into MUPS using an extrusion spheronization technique. Optimized formulation was characterized at nanoemulsion as well as MUPS stage. DLS and nanoparticle tracking analysis studies of orlistat nanoemulsion exhibited unimodal size distribution with polydispersity value <0.1. Confocal laser scanning microscopy (CLSM) studies confirmed the presence of uniform spherical nanosized oil droplets of nanoemulsified orlistat. DSC and PXRD studies of MUPS confirmed amorphization of embedded nanoemulsified orlistat. In-vitro dissolution studies in surfactant-reduced media demonstrated remarkable improvement in dissolution compared to pure orlistat and marketed formulation (Xenical Capsules 120 mg, Hoffman-La Roche, Basle, Switzerland). Comparative in-vitro bovine porcine pancreatic lipase inhibition studies of pure orlistat, marketed product and developed MUPS showed 13.57- and 2.41-fold higher lipase inhibition with developed MUPS compared to pure orlistat and marketed products, respectively.

Soluble itraconazole in tablet form using disordered drug delivery approach: critical scale-up considerations and bio-equivalence studies.

The present research work explores formulation design, critical scale-up considerations and bio-equivalence studies of soluble itraconazole (ITZ) in a tablet form using disordered drug delivery approach. Disordered system of ITZ with a lower viscosity grade of hydroxypropyl methyl cellulose (Pharmacoat 603) was developed for the first time and extensively characterised at three different stages, namely development of glass system, pellet coating and tablet compression using advanced analytical techniques. Complete molecular embedment of ITZ resulting in amorphisation was observed and found to be sustained until end of the real-time and accelerated stability studies. Developed formulation exhibited comparative in vitro dissolution profile (similarity factor>70) with reference product (Sporanox, Janssen Pharmaceutica) in simulated gastric fluid without enzymes. Formulation was scaled up in three batches (50,000 tablets/batch) with detailed validation of critical process parameters using process capability index method. Critical scale-up considerations like control of residual solvent content, effect of pellet size on dissolution, process variables in pellet coating, compressibility of coated pellets and cushioning effect required for desired compressibility were thoroughly discussed. Bioequivalence study of single dose of test and reference product in seven healthy human volunteers under fed condition exhibited significant bioequivalence with results (AUClast and AUC∞) lying between 90% confidence interval. With increase in number of subjects to 24, a significant effect on pharmacokinetic parameters of both reference as well as developed ITZ tablets was observed.

Effect of decisive formulation variables on bioencapsulation efficiency and integrity of yeast biocapsules for oral itraconazole delivery.

Reproducible delivery of drugs through bioencapsulation in cellular carriers is severely limited by biovariability in cellular carriers and effects of decisive formulation variables. Surmounting the constraints in reproducible results, our work explores optimization methodology for precise and reproducible cellular bioencapsulation technology for poorly water soluble drug. Active-dried baker's yeast cells were selected as cellular carriers for poorly soluble antimycotic agent itraconazole (ITZ). Pre-treatment of yeast cells with various techniques exhibited substantial augmentation in bioencapsulation efficiency (%BE). Sequentially optimized values of formulation variables like bioencapsulation temperature (40-50°C), stirring rate (350 rpm) and time (5 h) exhibited highest %BE with desired reproducibility. In comparison with marketed product, bioencapsulated itraconazole demonstrated marked increase in solubility with more than 70% release in 10 min. Compression pressure equivalent to tablet hardness of 2.0-3.5 kg/cm(2) was optimum to maintain integrity of biocapsules. Resulting biocapsules exhibited safe residual solvent content, inertness for fermentation ability and excellent stability at accelerated conditions.

Amorphous ternary cyclodextrin nanocomposites of telmisartan for oral drug delivery: improved solubility and reduced pharmacokinetic variability.

Despite of advancements in dosage form design and use of multifunctional excipients, improvement in dissolution characteristics of molecules like Telmisartan (TEL) having exceedingly pH dependent and poor solubility profile is still challenging. The present research work explores an innovative particle engineering approach which synergistically coalesce two principally different solubility enhancement strategies namely ternary ß-cyclodextrin complexation and top-down nanonization in a unit process. The research was aimed to improve solubility and reduce in vivo variability in pharmacokinetic parameters of TEL irrespective to physiological pH conditions. Ternary ß-cyclodextrin nanocomposites of TEL were prepared with high pressure homogenization using meglumine as ternary component. TEL nanocomposites were thoroughly characterized for particle size, surface topology, surface charge, inclusion complexation, crystalinity, dissolution and in vivo pharmacokinetic performance in male wistar rats at fed and fasted state. TEL nanocomposites exhibited average particle size of 698 ± 23 nm. Remarkable improvement in in vitro dissolution characteristics in multimedia and biorelevant media was observed in comparison with plain drug and marketed formulation. Results of in vivo pharmacokinetic studies revealed that, nanocomposites effectively bypass variation in pharmacokinetic parameters at fed and fasted states with 346%, 315%, 301% and 321% increase in relative bioavailability compared to marketed formulation and pure TEL in fed and fasted conditions respectively.