Development of oral site-specific pellets containing flavonoid extract with antioxidant activity

Abstract Herbal medicines are recognized as an effective treatment of common diseases, mainly associated with oxidative stress. Therefore developing drug delivery systems of these biological active ingredients are gaining interest. Parsley (Petroselinum crispum L.) is a well-known culinary herb and its leaf contains high amount of apigenin, therefore it is suitable as a natural source of this flavonoid. Apigenin possess many health effects such as antioxidant, anti-inflammatory and anticancer activities. Unfortunately, these benefits are limited due to the low water solubility and bioavailability, it was recently classified as BCS II group compound. Therefore the aim of this study was to develop a carrier system for Petroselinum crispum extract, containing high amount of apigenin. Microcrystalline cellulose inert pellet cores were chosen and enteric coatings were applied. The produced multiparticulates had spherical shape, narrow size distribution and low moisture content. 10% (w/w) Eudragit® L 30 D-55 and 15% (w/w) Eudragit® FS 30 D coating was adequate for the modified release in vitro. The layered pellets demonstrated antioxidant activity. It was concluded that development of oral site-specific pellets containing flavonoid extract successful and the therapeutic effectiveness could be hypothesized

Liposomes for topical use: physico-chemical comparison of vesicles prepared from egg or soy lecithin

Developments in nanotechnology and in the formulation of liposomal systems provide the opportunity for cosmetic dermatology to design novel delivery systems. Determination of their physico-chemical parameters has importance when developing a nano-delivery system. The present study highlights some technological aspects/characteristics of liposomes formulated from egg or soy lecithins for topical use. Alterations in the pH, viscosity, surface tension, and microscopic/macroscopic appearance of these vesicular systems were investigated. The chemical composition of the two types of lecithin was checked by mass spectrometry. Caffeine, as a model molecule, was encapsulated into multilamellar vesicles prepared from the two types of lecithin: then zeta potential, membrane fluidity, and encapsulation efficiency were compared. According to our observations, samples prepared from the two lecithins altered the pH in opposite directions: egg lecithin increased it while soy lecithin decreased it with increased lipid concentration. Our EPR spectroscopic results showed that the binding of caffeine did not change the membrane fluidity in the temperature range of possible topical use (measured between 2 and 50 °C). Combining our results on encapsulation efficiency for caffeine (about 30% for both lecithins) with those on membrane fluidity data, we concluded that the interaction of caffeine with the liposomal membrane does not change the rotational motion of the lipid molecules close to the head group region. In conclusion, topical use of egg lecithin for liposomal formulations can be preferred if there are no differences in the physico-chemical properties due to the encapsulated drugs, because the physiological effects of egg lecithin vesicles on skin are significantly better than that of soy lecithin liposomes

The similarity question for biologicals and non-biological complex drugs

AbstractFor small – low molecular weight – molecule medicines a robust regulatory system has evolved over the years. This system guarantees high and constant quality of our (generic) medicines. Pharmaceutical equivalence and bioequivalence assessment are the pillars under that system. But there are complex medicines where the question of equivalence is more challenging to answer. For biologicals the paradigm of similarity rather than equality (the emergence of ‘biosimilars’) was developed in the past decade. This has been a program where an evolutionary, science based approach has been chosen by the frontrunner regulatory body, the EMA, with a ‘learn and confirm’ character.In addition, there is another group of complex drugs, the non-biological complex drugs, NBCDs, where the generic paradigm can be challenged as well. The NBCDs are defined as: 1. consisting of a complex multitude of closely related structures; 2. the entire multitude is the active pharmaceutical ingredient; 3. the properties cannot be fully characterized by physicochemical analysis and 4. the consistent, tightly controlled manufacturing process is fundamental to reproduce the product. NBCDs encompass product families such as the glatiramoids, liposomes, iron–carbohydrate colloids and many candidates of the group of the upcoming nanoparticulate systems. Following the main principles of regulatory pathways for biologicals (with appropriate product-by-product adjustments), instead of that for small molecules, would be the more logical strategy for these NBCDs.The status and outstanding regulatory issues for biosimilars and NBCD-similars/follow on versions were discussed at a conference in Budapest, Hungary (October 2014) and this commentary touches upon the issues brought up in the presentations, deliberations and conclusions

Development and characterization of voriconazole loaded nanoparticles for parenteral delivery

Human serum albumin (HSA) has attracted the most attention in the last decades as a new nanocarrier system of active pharmaceutical ingredients (API) due to its biocompatibility and high binding capacity to hydrophobic drugs. Voriconazole (VCZ), an antifungal agent with low water solubility, was selected to produce albumin based nanoparticles using nanoparticle albumin-bound technology (nab-technology). Aim of our study was to study the development process of VCZ-loaded nanoparticles for parenteral drug delivery, such as homogenizing pressure, homogenizing cycle number and drug loading capacity. The main characters of nanoparticles such as particle size distribution and polydispersity index (PDI) were determined by dynamic light scattering. Six homogenization cycles at 1800bar were ensured the acceptable PDI value (lower than 0.3) of the VCZ content nanoparticles. Optimized formulation process produced 81.2+/-1nm average particle size which meets the requirements of intravenous administration. Furthermore, the encapsulated concentration of VCZ was 69.7+/-4.2% and the water solubility was over 2 times greater than the API itself which were determined by the developed HPLC method. The in vivo release behavior can be predicted from our applied in vitro dissolution study. Almost 50% of VCZ was liberated from the nanoparticles in the first 60min

Unexpected retention behavior of baicalin: Hydrophilic interaction like properties of a reversed-phase column

tThe original aim of this study was to develop a method for the determination of baicalin from membranevesicles. The unconventional chromatographic separation (“inverse gradient elution” on a reversed phasecolumn) was due to a lucky chance, which is detailed and discussed in this study. The validated liquidchromatography-tandem mass spectrometry (LC–MS/MS) method is proved to be sensitive, rapid andselective. Chromatographic separation was performed on a Zorbax SB-C8 column (250 mm × 4.6 mm,i.d.; 5 �m) with 0.1% formic acid in water and methanol by linear gradient elution. Quantification ofbaicalin was determined by multiple reaction monitoring (MRM) mode using electrospray ionization(ESI). The calibration curve was linear (r = 0.9987) over the concentration range from 1 to 1000 nM.The coefficient of variation and relative error of baicalin for intra- and inter-assay at three quality con-trol (QC) levels were 2.0–10.2% and −6.1 to 6.7%, respectively. The lower limit of quantification (LLOQ)for baicalin was 1 nM (0.446 ng/ml), without preconcentration of the sample. This method was subse-quently applied to vesicular transport assays of baicalin in membrane vesicles successfully. The developedmethod can open up new area of research in the chromatographic separation of flavonoids and theirglucuronides