An overview of the analytical characterization of nanostructured drug delivery systems: Towards green and sustainable pharmaceuticals: A review

The analytical characterization of drug delivery systems prepared by means of green manufacturing technologies using CO2 as a processing fluid is here reviewed. The assessment of the performance of nanopharmaceuticals designed for controlled drug release may result in a complex analytical issue and multidisciplinary studies focused on the evaluation of physicochemical, morphological and textural properties of the products may be required. The determination of the drug content as well as the detection of impurities and solvent residues are often carried out by chromatography. Assays on solid state samples relying on X-ray, vibrational and nuclear magnetic resonance spectroscopies are of great interests to study the composition and structure of pharmaceutical forms. The morphology and size of particles are commonly checked by microscopy and complementary chemical information can be extracted in combination with spectroscopic accessories. Regarding the thermal behavior, calorimetric and thermogravimetric techniques are applied to assess the thermal transitions and stability of the samples. The evaluation of drug release profiles from the nanopharmaceuticals can be based on various experimental set-ups depending on the administration route to be considered. Kinetic curves showing the evolution of the drug concentration as a function of time in various physiological conditions (e.g., gastric, plasmatic or topical) are recorded commonly by UV–vis spectroscopy and/or chromatography. Representative examples are commented in detail to illustrate the characterization strategies.

Graphical abstractFigure optionsDownload full-size imageDownload as PowerPoint slideHighlights► Analytical evaluation of nanostructured drug delivery systems prepared by scCO2. ► Physicochemical characterization by chromatography and spectroscopy. ► Particle characterization by microscopy and thermal analysis. ► Release assessment by batch, continuous and diffusion devices.