Nanotechnology has a great potential for improving many areas of research and its applications, like nanoscale phenomena and processes, nanomaterials, nanoscale devices and instrumentation research. Nanoparticles, that are currently used, demonstrate many desirable properties for cancer management, considering their ability to accumulate in the specific parts of pathological areas and provide controlled drug release. Pharmaceutical nanocarriers can be used as a part of drug delivery systems for the purposes of therapy, diagnosis and imaging. Methods for nanoparticle manufacturing are: spray drying, aerosol flow reactor, mechanical methods (milling, homogenization under high pressure), precipitation techniques, techniques using supercritical fluids, methods for emulsion preparation and freezing (lyophilization). Future trends in the development of nanotechnology are expected to go towards additional decrease in dimensions of active and auxiliary compounds. The only way to achieve this is to combine methods used in medicine, engineering, materials studying, information technologies and physics. Keywords: nanoparticles, cancer, drug delivery

Suspension stability can be theoretically estimated prior to the beginning of the formulating process based on the solid phase particle size, liquid phase density, and viscosity. Stokes equation can be used to predict suspension stability in order to save time and resources. The examples of these calculations for the assessment of suspension physical characteristics are given in this article. One parameter that cannot be theoretically estimated with precision is flocculation/deflocculation. Flocculation can be experimentally determined using the "jar test," and it is a critical parameter for the substances showing inclination toward caking. Suspensions will sediment in time; however, it is their key feature to be able to redisperse in order to preserve the efficacy and proper dosage. Bismuth subnitrate is practically insoluble in water, which makes it convenient for oral pharmaceutical suspensions, rather than the other pharmaceutical forms. Like the other bismuth compounds, it tends to cake in aqueous medium. In order to prevent formation of the solid sediment, controlled flocculation of the suspended bismuth subnitrate particles is recommended. The effect of the excipients (sodium citrate, Tween 20, propylene glycol, microcrystalline cellulose) on the transmittance of the prepared suspensions and the quantity and characteristics of the formed sediment were evaluated. Suspensions containing sodium citrate, as well as the formulations with sodium citrate and microcrystalline cellulose, based on their transmittance characteristics, were determined to be flocculating suspensions, regardless of the sodium citrate concentration used. The highest affinity towards formation of flocculating suspensions, with the highest transmittance value had microcrystalline cellulose with 15% (w/w) sodium citrate.

Since the assay method for pantoprazole in pantoprazole pellets is not described in current pharmacopoeias (USP, BP), the aim of this work was to develop and validate a simple, precise and accurate method for determination of pantoprazole in pantoprazole pellets. Separation was achieved on a reversed-phase C8 column (250 x 4.6 mm i.d.; 5 a mixture of phosphate buffer pH 3.0 and acetonitrile as mobile phase, at a flow rate 2 ml/min and UV detection at 290 nm. The method was validated according to ICH Guidelines. Validation showed that developed method was valid and reliable for determination of active substance in pantoprazole

The solubility enhancement of diazepam and nitrazepam in water was analyzed depending on temperature and amount of α-cyclodextrin ( α-CD), β-cyclodextrin (β-CD) and 2-hydroxypropyl-β-cyclodextrin (2-HP-β-CD). The interactions of drug-cyclodextrin in solution were investigated by the phase-solubility analysis. Diazepam (nitrazepam) content in aqueous complexation medium was analyzed UV spectrophotometrically. Classical solubility data were used to derive apparent stability constants (K1:1) which were used to derive thermodynamic parameters for the diazepam (nitrazepam)-cyclodextrin complexes. Since all phase solubility plots were of AL–types, and calculated Slopes after linear regression analysis were found to be less than 1, it could be assumed that stoichiometry of the formed binary systems was 1:1. According to the calculated K1:1 values, the stability of the complexes of diazepam and nitrazepam with a-CD, β-CD and 2-HP-β-CD varies as follows: 2-HP-β-CD > β-CD > β-CD. The a-CD has higher affinity for dissolving nitrazepam compared to diazepam. While all parameters lead to an improvement in solubility, the largest effect was obtained for guest-host complexation with 2-HP-β-CD. The solubility of diazepam and nitrazepam in water increased 93.02 times and 64.23 times, respectively, in the presence of 40% (w/w) 2-HP-β-CD, at 25°C. Solubility data for diazepam and nitrazepam in aqueous 2-HP-b-CD were used to derive thermodynamic parameters, ΔG° at 298 K = –14.43 kJ·mol–1, ΔH° = 0.79 kJ·mol–1, ΔS° at 298 K = 51.17 J·mol–1·K–1 and ΔG° at 298 K = –13.43 kJ·mol–1, ΔH° = 2.38 kJ·mol–1, ΔS° at 298 K = 53.01 J·mol–1·K–1, respectively. Formation of inclusion complexes substantially increases the water solubility of diazepam and nitrazepam. Diazepam and nitrazepam dissolution thermodynamics in aqueous 2-HP-β-CD were characterized by spontaneous and endothermic dissolution and hydrophobic interactions.