Characterization of nanomedicines' surface coverage using molecular probes and capillary electrophoresis.

A faithful characterization of nanomedicine (NM) is needed for a better understanding of their in vivo outcomes. Size and surface charge are studied with well-established methods. However, other relevant parameters for the understanding of NM behavior in vivo remain largely inaccessible. For instance, the reactive surface of nanomedicines, which are often grafted with macromolecules to decrease their recognition by the immune system, is excluded from a systematic characterization. Yet, it is known that a subtle modification of NMs' surface characteristics (grafting density, molecular architecture and conformation of macromolecules) is at the root of major changes in the presence of biological components. In this work, a method that investigates the steric hindrance properties of the NMs' surface coverage based on its capacity to exclude or allow adsorption of well-defined proteins was developed based on capillary electrophoresis. A series of proteins with different molecular weights (MW) were used as molecular probes to screen their adsorption behavior on nanoparticles bearing different molecular architectures at their surface. This novel strategy evaluating to some degree a functionality of NMs can bring additional information about their shell property and might allow for a better perception of their behavior in the presence of biological components. The developed method could discriminate nanoparticles with a high surface coverage excluding high MW proteins from nanoparticles with a low surface coverage that allowed high MW proteins to adsorb on their surface. The method has the potential for further standardization and automation for a routine use. It can be applied in quality control of NMs and to investigate interactions between proteins and NM in different situations.

Analysis of anions in aqueous samples by ion chromatography and capillary electrophoresis. A comparative study of peak modeling and validation criteria.

The object of this study is the comparison of two methods for the quantitative analysis of anions in aqueous samples: ion chromatography with conductimetric detection, and capillary zone electrophoresis with indirect photometric detection. The comparison includes modeling of experimental peaks as well as statistical validation criteria according to the recommendations of the International Conference on Harmonisation. In ion chromatography, peak shapes are Gaussian or exponentially modified Gaussian, and the number of theoretical plates calculated using the appropriate mathematical relations correspond well to those obtained from statistical moments. Peaks in capillary electrophoresis, however, do not follow the same models. A different model, treating the peaks as right angle triangles, has been studied. Equations corresponding to this model permit a good estimation of plate numbers. The statistical validation of these methods includes detection limits, linearity, accuracy and precision. Overall, ion chromatography yields better validation results than capillary electrophoresis. In the latter method the injection mode plays an important role, with voltage injection giving lower detection limits than hydrodynamic injection.

Analysis of intact heparin by capillary electrophoresis using short end injection configuration.

A capillary electrophoresis method for the analysis of intact heparin was developed using a phosphate buffer and a fused silica capillary. Operational parameters such as pH and concentration of the running buffer were investigated. The short end injection configuration permitted a gain on peak efficiency, on the analysis time and on the repeatability of both migration times and peak areas, through a reduction of the migration distance. Moreover, the beneficial effect of the presence of sodium chloride in the heparin sample on the peak efficiency was demonstrated and the influence of the salts on the conformation of the heparin was discussed. The optimized method (short end injection configuration, 50mM phosphate buffer pH 3, heparin sample prepared in 10 g/L NaCl solution) was validated in terms of linearity, reproducibility and specificity according to ICH requirements.