Quality assessment of niosomal suspensions.

Niosomes are vesicular carriers formed by a bilayer shell, which is composed of non-ionic surfactants with the addition of a structural supporting agent. Cholesterol is typically used as an additive to increase the stability or drug entrapment efficiency of niosomes. Although increasing the amount of cholesterol is reported to improve niosomal properties, an excessive amount of cholesterol may not be accommodated in the bilayer shell, and thus remain in the crystalline form in the niosomal solution. The presence of a crystalline phase is a potential risk for further medical application. Therefore, Tween 80-based niosomes were prepared using a well-established thin-film hydration method and organic phase injection method, followed by their thorough characterization in order to estimate the cholesterol incorporation into the niosomal shell. To detect the crystalline phase in the niosomal suspensions, a novel approach based on depolarized dynamic light scattering combined with cryo-transmission electron microscopy, X-ray diffraction and optical microscopy is used to confirm the presence of cholesterol crystals. This method is fast, quantitative, and allows the sample analysis in a natural liquid environment, thus eliminating biased results influenced by sample drying.

Monitoring of particle sizes distribution during Valsartan precipitation in the presence of nonionic surfactant.

Particle size is a key parameter when dealing with drug particle formation, delivery or dissolution. The correct measurement of particle size depends on various factors, such as sample preparation or dilution, but also on the choice of method for its characterization. In this work, we study the process of precipitation of poorly water-soluble drug Valsartan from supersaturated solution in the presence of nonionic surfactant Tween 20. Several techniques including dynamic light scattering (DLS) operated in several measuring modes, optical microscope (OM) and static light scattering (SLS) were used to analyze the kinetics of particle formation. As concluded by the results, the increase in turbidity of the solution seriously limits the application of classical DLS to properly measure the particle size and polydispersity. One way to get around this restriction is by dilution, which however results in a decrease in the size of Valsartan particles in the studied population. In contrast, here we present for a first time technique based on modulated 3D cross correlation DLS equipped with the sample goniometer to determine size of submicron particles of the drug in highly turbid solutions. Additionally, a modified OM was used to measure micron-sized particles for samples without any dilution in a continuous mode. Measured particle sizes combined with measured Valsartan concentration allowed us to identify mechanism responsible for the particle formation from supersaturated solutions. The main mechanism, as it is shown in this work, is covering surface of precipitate particles by the amount of used Tween 20.