Preparation and investigation of P28GST-loaded PLGA microparticles for immunomodulation of experimental colitis.

The aim of this work was to prepare and characterize (in vitro and in vivo) PLGA-based microparticles loaded with an enzymatic protein derived from the helminth parasite Schistosoma haematobium: glutathione S-transferase P28GST (P28GST). This protein is not only a promising candidate vaccine against schistosomiasis, it also exhibits interesting immunomodulating effects, which can be helpful for the regulation of inflammatory diseases. Helminths express a regulatory role on intestinal inflammation, and immunization by P28GST has recently been shown to be as efficient as infection to reduce inflammation in a murine colitis model. As an alternative to the combination with a classical adjuvant, long acting P28GST microparticles were prepared in order to induce colitis prevention. PLGA was used as biodegradable and biocompatible matrix former, and a W/O/W emulsion/solvent extraction technique applied to prepare different types of microparticles. The effects of key formulation and processing parameters (e.g., the polymer molecular weight, drug loading, W/O/W phase volumes and stirring rates of the primary/secondary emulsions) on the systems' performance were studied. Microparticles providing about constant P28GST release during several weeks were selected and their effects in an experimental model of colitis evaluated. Mice received P28GST-loaded or P28GST-free PLGA microparticles (s.c.) on Day 0, and optionally also on Days 14 and 28. Colitis was induced on Day 35, the animals were sacrificed on Day 37. Interestingly, the Wallace score (being a measure of the severity of the inflammation) was significantly lower in mice treated with P28GST microparticles compared to placebo after 1 or 3 injections. As immunogenicity markers, increased anti-P28GST IgG levels were detected after three P28GST PLGA microparticle injections, but not in the control groups. Thus, the proposed microparticles offer an interesting potential for the preventive treatment of experimental colitis, while the underlying mechanism of action is still to be investigated.

Unintended and in situ amorphisation of pharmaceuticals.

Amorphisation of poorly water-soluble drugs is one approach that can be applied to improve their solubility and thus their bioavailability. Amorphisation is a process that usually requires deliberate external energy input. However, amorphisation can happen both unintentionally, as in process-induced amorphisation during manufacturing, or in situ during dissolution, vaporisation, or lipolysis. The systems in which unintended and in situ amorphisation has been observed normally contain a drug and a carrier. Common carriers include polymers and mesoporous silica particles. However, the precise mechanisms by which in situ amorphisation occurs are often not fully understood. In situ amorphisation can be exploited and performed before administration of the drug or possibly even within the gastrointestinal tract, as can be inferred from in situ amorphisation observed during in vitro lipolysis. The use of in situ amorphisation can thus confer the advantages of the amorphous form, such as higher apparent solubility and faster dissolution rate, without the disadvantage of its physical instability.

The impact of surface- and nano-crystallisation on the detected amorphous content and the dissolution behaviour of amorphous indomethacin.

The crystallinity and physical stability of amorphous drugs has previously been studied using different analytical techniques. However, the effect of the measurement method on observed crystallinity and its importance for critical quality attributes, such as dissolution, has not yet been widely investigated. The aim of this study was to (i) qualitatively analyse and understand the recrystallisation behaviour of amorphous indomethacin during storage, (ii) quantify the amorphous content during storage with complementary analytical techniques and (iii) investigate the relationship between observed recrystallisation behaviour and dissolution behaviour. Quench cooled indomethacin was stored and the samples were visualised by scanning electron microscopy to gain spatially resolved information about the recrystallisation behaviour. Crystallisation was quantified by Fourier transform attenuated total reflectance infrared (FT-ATR-IR) spectroscopy, differential scanning calorimetry and X-ray powder diffraction. These techniques resulted in different observed recrystallisation profiles. The physicochemical phenomena detected and sampling geometry for each technique together with the sample recrystallising from the surface and appearance of nano-crystals were used to explain the differences. The dissolution behaviour at the observed recrystallisation endpoints for the different analytical techniques revealed that FT-ATR-IR spectroscopy predicted the changes in dissolution behaviour due to crystallisation best.