Die EyeFlowCell: Entwicklung eines 3D-gedruckten In vitro-Freisetzungsmodells für intravitreale Darreichungsformen auf Basis einer Durchflusszelle

Die Therapie von Erkrankungen des hinteren Auges erfolgt heute hauptsächlich durch die intravitreale Injektion von Lösungen, Suspensionen oder Implantaten. Um neue intravitreale Arzneiformen zu entwickeln werden in der präklinischen Phase neben In vitro-Untersuchungen zur Wirkstofffreisetzung auch In vivo-Studien an Tieren verwendet. Die Physiologie des Auges der verwendeten Tiere weicht jedoch von denen des humanen Glaskörpers ab, weshalb die Übertragbarkeit der Ergebnisse teilweise kontrovers diskutiert wird. Durch eine Kombination dieser in vivo-Studien mit biorelevanteren In vitro-Freisetzungsmodellen könnte ein besseres Verständnis für das Verhalten von intravitrealen Arzneiformen erhalten werden. In dieser Arbeit wurde die EyeFlowCell entwickelt, bei der zentral der humane Glaskörper durch ein künstliches Gel simuliert wird. In dieses Glaskörpersubstitut injizierte Arzneiformen können hinsichtlich ihrer Wirkstofffreisetzung unter verschiedenen Aspekten charakterisiert werden

Ex Vivo Visualization of Distribution of Intravitreal Injections in the Porcine Vitreous and Hydrogels Simulating the Vitreous

The characterization of intravitreal dosage forms with regard to their behavior in vivo is usually explored in preclinical development through animal studies. In vitro vitreous substitutes (VS) to simulate the vitreous body for preclinical investigations have so far been insufficiently studied. To determine a distribution or concentration in the mostly gel-like VS, extraction of the gels is required in many cases. This destroys the gels, which makes a continuous investigation of the distribution impossible. In this work, the distribution of a contrast agent in hyaluronic acid agar gels and polyacrylamide gels was studied by magnetic resonance imaging and compared with the distribution in ex vivo porcine vitreous. The porcine vitreous served as a surrogate for human vitreous since both are similar in their physicochemical properties. It was shown that both gels do not completely represent the porcine vitreous body, but the distribution in the polyacrylamide gel is similar to that in the porcine vitreous body. In contrast, the distribution throughout the hyaluronic acid agar gel is much faster. It was also shown that anatomical features such as the lens and the interfacial tension to the anterior eye chamber could have an influence on the distribution that is difficult to reproduce using in vitro VS. However, with the presented method, new in vitro VS can be investigated continuously without destruction in the future, and thus their suitability as a substitute for the human vitreous can be verified

The EyeFlowCell: Development of a 3D-Printed Dissolution Test Setup for Intravitreal Dosage Forms

An in vitro dissolution model, the so-called EyeFlowCell (EFC), was developed to test intravitreal dosage forms, simulating parameters such as the gel-like consistency of the vitreous body. The developed model consists of a stereolithography 3D-printed flow-through cell with a polyacrylamide (PAA) gel as its core. This gel needed to be coated with an agarose sheath because of its low viscosity. Drug release from hydroxypropyl methylcellulose-based implants containing either triamcinolone acetonide or fluorescein sodium was studied in the EFC using a schematic eye movement by the EyeMovementSystem (EyeMoS). For comparison, studies were performed in USP apparatus 4 and USP apparatus 7. Significantly slower drug release was observed in the PAA gel for both model drugs compared with the compendial methods. Drug release from fluorescein sodium-containing model implants was completed after 40 min in USP apparatus 4, whereas drug release in the gel-based EFC lasted 72 h. Drug release from triamcinolone acetonide-containing model implants was completed after 35 min in USP apparatus 4 and after 150 min in USP apparatus 7, whereas this was delayed until 96 h in the EFC. These results suggest that compendial release methods may overestimate the drug release rate in the human vitreous body. Using a gel-based in vitro release system such as the EFC may better predict drug release

After Lisbon: National Parliaments in the European Union

The role of national parliaments in EU matters has become an important subject in the debate over the democratic legitimacy of European Union decision-making. Strengthening parliamentary scrutiny and participation rights at both the domestic and the European level is often seen as an effective measure to address the perceived 'democratic deficit' of the EU - the reason for affording them a prominent place in the newly introduced 'Provisions on Democratic Principles' of the Union (in particular Article 12 TEU). Whether this aim can be met, however, depends crucially on the degree and the manner in which national parliaments actually make use of their institutional rights. This volume therefore aims at providing a comprehensive overview of the activities of national parliaments in the post-Lisbon era. This includes the 'classic' scrutiny of EU legislation, but also parliamentary involvement in EU foreign policy, the use of new parliamentary participation rights of the Lisbon Treaty (Early Warning System), their role regarding the EU's response to the eurozone crisis and the, so far under-researched, role of parliamentary administrators in scrutiny processes. This introduction provides the guiding theoretical framework for the contributions. Based on neo-institutionalist approaches, it discusses institutional capacities and political motivation as the two key explanatory factors in the analysis of parliamentary involvement in EU affairs