PurposeDevelopment of a method to assess the drug/polymer miscibility and stability of solid dispersions using a melt-based mixing method.MethodsAmorphous fractured films are prepared and characterized with Raman Microscopy in combination with Atomic Force Microscopy to discriminate between homogenously and heterogeneously mixed drug/polymer combinations. The homogenous combinations are analyzed further for physical stability under stress conditions, such as increased humidity or temperature.ResultsCombinations that have the potential to form a molecular disperse mixture are identified. Their potential to phase separate is determined through imaging at molecular length scales, which results in short observation time. De-mixing is quantified by phase separation analysis, and the drug/polymer combinations are ranked to identify the most stable combinations.ConclusionsThe presented results demonstrate that drug/polymer miscibility and stability of solid dispersions, with many mechanistic details, can be analyzed with Atomic Force Microscopy. The assay allows to identify well-miscible and stable combinations within hours or a few days.Electronic Supplementary MaterialThe online version of this article (doi:10.1007/s11095-010-0306-4) contains supplementary material, which is available to authorized users.
PurposeTo verify the robustness and fundamental value of Atomic Force Microscopy (AFM) and AFM-based assays to rapidly examine the molecular homogeneity and physical stability of amorphous solid dispersions on Hot-Melt-Extrudates.MethodsAmorphous solid dispersions were prepared with a Hot-Melt Extruder (HME) and profiled by Raman Microscopy and AFM following a sequential analytical routine (Multi-Scale-Imaging-of-Miscibiliy (MIMix)). Extrudates were analyzed before and after incubation at elevated temperature and humidity. The data were compared with published results as collected on miniaturized melt models. The value of molecular phase separation rates for long term stability prediction was assessed.ResultsData recorded on the extrudates are consistent with those published, and they can be compared side by side. Such direct data comparisons allow the identification of possible sources of extrudate heterogeneities. The surface roughness analysis of fracture-exposed interfaces is a novel quantitative way to trace on the nanometer scale the efficiencies of differently conducted HME-processes. Molecular phase separation rates are shown to be relevant for long term stability predictions.ConclusionsThe AFM-based assessment of API:excipient combinations is a robust method to rapidly identify miscible and stable solid dispersions in a routine manner. It provides a novel analytical tool for the optimization of HME processes.Electronic supplementary materialThe online version of this article (doi:10.1007/s11095-013-1045-0) contains supplementary material, which is available to authorized users.
: Orlistat, a lipase inhibitor taken with meals at doses of 60 mg (available over-the-counter) or 120 mg (prescription only) for treatment of obesity, is known to impair the absorption of fat-soluble molecules. Dalcetrapib, a modulator of cholesteryl ester transfer protein activity, is a lipophilic thioester prodrug. Lipase-induced and pancreatin-induced hydrolysis of dalcetrapib in biorelevant media in vitro was very efficiently inhibited by orlistat. Thus, the potential for orlistat to affect the bioavailability of concomitantly administered dalcetrapib was studied in an open-label 2-cohort study in 24 healthy volunteers as follows: single 600-mg doses of dalcetrapib were administered with increasing doses of orlistat (cohort A: 10, 40, 120 mg; cohort B: 20, 60, 120 mg). Exposure to the active form of dalcetrapib was more than 50% lower when taken with orlistat 60 mg or 120 mg than when taken alone. Similar trends were observed with lower orlistat doses (20 mg and 40 mg). Concomitant administration of orlistat also reduced the pharmacodynamic effects of dalcetrapib treatment on cholesteryl ester transfer protein activity. The interaction exceeds that predicted on the basis of dalcetrapib lipophilicity. These findings demonstrate the potential for large interactions between orlistat and esters that undergo de-esterification in the gastrointestinal tract, independent of lipophilicity.
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