Preparation, optimization and preliminary pharmacokinetic study of curcumin encapsulated turmeric oil microemulsion in zebra fish.

The present investigation aimed to develop curcumin loaded turmeric oil microemulsion for brain targeting. An effort has been made to investigate the role of functional components in developing brain targeted formulation which could enhance the bioavailability and uptake of drug in the brain upon oral administration. Preliminary studies like solubility study, emulsification study and construction of the pseudo ternary phase diagram were performed for screening components. The formulation was optimized by using extreme vertices mixture design. The optimized formulation was characterized for appearance, stability to centrifugation, dilution potential, globule size, zeta potential and drug content. Furthermore, ex-vivo permeation in chicken gut sac non everted technique and pharmacokinetic study in adult zebra fishes were carried out. The optimized formulation was found to clear, yellow-colored with the absence of phase separation and precipitation denoted the stability of formulation to centrifugation and dilution. The mean globule size, polydispersity index, zeta potential and drug content was observed as 29.13± 0.12 nm, 0.23 ± 0.01,-12.33 ± 1.37 mV and 99.10±3.91 %, respectively. Ex vivo permeation study revealed 2.41 fold enhancement in the steady-state flux when compared to curcumin solution. Furthermore, optimized formulation showed shorter Tmax (5 min) and higher AUC(0-∞) (7.93 µg/brain*min) compared to the curcumin solution which showed similar Tmax and AUC(0-∞) of 2.78 µg/brain*min after oral administration to zebra fishes revealing 3.97 fold enhancement. The results revealed enhanced ex vivo oral absorption and enhanced in vivo brain pharmacokinetics of curcumin via functional microemulsion in the zebra fish model.

In Vitro and In Vivo Performance of Novel Spray Dried Andrographolide Loaded Scleroglucan Based Formulation for Dry Powder Inhaler.

BACKGROUND: Current therapy for pulmonary arterial hypertension (PAH) is unable to prevent progression of disease due to continuous infusions and multiple oral administrations. This resulted in the need of novel treatment which would target directly structural vascular changes that weaken blood flow through pulmonary circulation. OBJECTIVE: The objective of present study was to develop spray dried (SD) formulation for dry powder inhaler (DPI) with enhanced aerosol performance and lung deposition by using novel bioactive, andrographolide (AGP) and carrier, scleroglucan (SCLG) with improved antihypertensive activity. The SDAGP formulation was evaluated for physicochemical properties and in vitro/in vivo lung deposition. Further, antihypertensive activity was studied by monocrotaline (MCT) induced rat model. RESULTS: The SDAGP exhibited mean median aerodynamic diameter (MMAD) and fine particle fraction (FPF) of 3.37 ± 0.47 µm and 60.24 ± 0.98%. The in vivo absorption profile of final formulation reflected increased lung deposition of AGP at the end of 24 h with no signs of inflammation and toxicity. Moreover, SDAGP formulation confirmed enhanced antihypertensive activity. CONCLUSION: The results proved use of AGP and SCLG as a novel bioactive and carrier with enhanced lung deposition and pulmonary antihypertensive activity.

Improved bioavailability of orally administered andrographolide from pH-sensitive nanoparticles.

Andrographolide, a major bioactive phytoconstituent derived from Androgaphis paniculata that is safe and beneficial in several ailments, was formulated into pH-sensitive nanoparticle suspension with a view of improving its oral bioavailability. The andrographolide-loaded pH-sensitive nanoparticles were prepared by nanoprecipitation technique using Eudragit® EPO (cationic poly methacrylate copolymer). The 3(2) factorial design was used to optimize the amount of polymer and stabilizer (Pluronic® F-68). The optimized batch obtained using 0.45% w/v of Eudragit® EPO and 0.6% w/v of Pluronic® F-68 showed high-encapsulation efficiency of 93.8±0.67% with particle size of 255±9 nm and zeta potential of 29.3±3.4 mV. The bioavailability of andrographolide from optimized nanoparticles and pure andrographolide was assessed in male Wistar albino rats at a dose of 10 mg/kg. As compared to the pure andrographolide, almost 2.2 and 3.2-fold increase in AUC0-∞, Cmax and 121.53% increase in relative bioavailability were observed for andrographolide from pH-sensitive nanoparticles (P<0.05). Shorter Tmax by about fourfold difference were observed with 2.2-fold decrease in Cl/F. The improved dissolution rate owing to its reduced particle size, increased surface area and reduced diffusion layer thickness may have contributed to oral bioavailability. The results clearly indicate the potential of pH-sensitive nanoparticles for oral delivery of low-bioavailability phytoconstituents such as andrographolide.

Studies on nonionic surfactant bilayer vesicles of ciclopirox olamine.

CONTEXT: Niosomal delivery can prove an alternative to improve the poor skin penetration and residence of the topical antifungal drugs that account for the long treatment regimes in cutaneous mycosis. OBJECTIVE: To investigate niosomes as carriers for dermal delivery of ciclopirox olamine (CPO), a broad spectrum antifungal drug. MATERIALS AND METHODS: Niosomes were prepared by ethanol injection method using Span 60, cholesterol, diacetyl phosphate according to 3(2) factorial design and evaluated for physicochemical parameters, in vitro and ex vivo deposition in skin and stability study. RESULTS: Unilamellar CPO niosomes of size 170-280 nm, entrapment efficiency 38-68%, and sufficient electrokinetic stability were obtained. Percent drug deposition in artificial membrane varied from 12.75 to 92.74. Deposition of CPO into rat skin from niosomal dispersion and its gel was significantly higher than that of plain CPO solution and its marketed product. Obtained niosomes possessed sufficient stability on storage. DISCUSSION: Increasing amounts of Span 60 and cholesterol increase the vesicle size probably because of entrapment of CPO-ionized molecules in the aqueous compartment and interaction of its unionized counterpart with the bilayer constituents leading to increase in bilayer thickness. Consequently, the percent entrapment efficiency also increased. However, increasing Span 60 levels decreased the in vitro percent drug deposition. This might be attributed to the larger size of vesicles produced by high amounts of surfactant that showed poor deposition. The optimized batch possessed sufficient stability. CONCLUSIONS: The results of this investigation suggest that niosomes are promising tools for cutaneous retention of CPO.