Quantitative bioimaging of platinum group elements in tumor spheroids.

Limited drug penetration into tumor tissue is a significant factor to the effectiveness of cancer therapy. Tumor spheroids, a 3D cell culture model system, can be used to study drug penetration for pharmaceutical development. In this study, a method for quantitative bioimaging of platinum group elements by laser ablation (LA) coupled to inductively coupled plasma mass spectrometry (ICP-MS) is presented. Different matrix-matched standards were used to develop a quantitative LA-ICP-MS method with high spatial resolution. To investigate drug penetration, tumor spheroids were incubated with platinum complexes (Pt(II)acetylacetonate, cisplatin) and the palladium tagged photosensitizer 5,10,15,20-tetrakis(3-hydroxyphenyl)porphyrin (mTHPP). Distribution and accumulation of the pharmaceuticals were determined with the developed method.

Drug Release and Targeting: the Versatility of Polymethacrylate Nanoparticles for Peroral Administration Revealed by Using an Optimized In Vitro-Toolbox.

PURPOSE: The contribution of permeability and drug release to drug targeting were investigated in the course of development of a nanosized formulation of the anti-inflammatory compound TMP-001, for the local treatment in the gastrointestinal tract. METHODS: TMP-001 was encapsulated by nanoprecipitation into Eudragit® RS 100. The permeability of these carriers was investigated in an Ussing chamber model and the release rate was determined under biorelevant conditions. Formulation toxicity and particle-cell-interaction were investigated by flow cytometry, fluorescence and electron microscopy. Furthermore, spray drying was performed. RESULTS: Effective internalization of Eudragit®-nanoparticles into cancer cells was demonstrated. A burst release of the nanoparticles implied poor interaction of TMP-001 with Eudragit®. A sustained release (70.5% release after 30 min compared to 98.0% for the API) was accomplished after spray drying yielded an increased particle size. Recovery rate of TMP-001 after spray drying was 94.2 ± 5.9%. CONCLUSION: The release of API from polymeric nanoparticles contributes profoundly to the in vivo-performance of drug delivery devices in the gastrointestinal tract. The impact of drug-polymer interaction and particle size was analyzed. Sustained release of TMP-001 could only be achieved by increasing particle size. Therefore, biorelevant release testing has been demonstrated to be a valid tool for nanoformulation design.

A palladium label to monitor nanoparticle-assisted drug delivery of a photosensitizer into tumor spheroids by elemental bioimaging.

In this study, the cellular uptake of the second generation photosensitizer 5,10,15,20-tetrakis(3-hydroxyphenyl)porphyrin (mTHPP) was investigated using laser ablation coupled to inductively coupled plasma mass spectrometry (LA-ICP-MS) at a spatial resolution of 10 µm. To achieve high sensitivity, the photosensitizer was tagged with palladium. As a tumor model system, a 3D cell culture of the TKF-1 cell line was used. These tumor spheroids were incubated with the Pd-tagged photosensitizer embedded in poly(lactic-co-glycolic acid) (PLGA) nanoparticles to investigate the efficiency of nanoparticle based drug delivery. An accumulation of the drug in the first cell layers of the tumor spheroid was observed. In the case of nanoparticle based drug delivery, a significantly more homogeneous distribution of the photosensitizer was achieved, compared to tumor spheroids incubated with the dissolved photosensitizer without the nanoparticular drug delivery system. The infiltration depth of the Pd-tagged photosensitizer could not be increased with rising incubation time, which can be attributed to the adsorption of the photosensitizer onto cellular components.