Stability evaluation of temoporfin-loaded liposomal gels for topical application.

Temoporfin (mTHPC) is a potent second-generation synthetic photosensitizer. Topical delivery of mTHPC is of great interest for the photodynamic therapy of psoriasis and superficial skin cancer lesions. The aim of this study was to evaluate the stability of hydrophilic gels containing mTHPC-loaded liposomes. Two different mTHPC-loaded liposome dispersions, composed of 15 % (w/w) nonhydrogenated soybean lecithin of different phosphatidylcholine content, were prepared and incorporated (2:1 w/w) into hydrogels of different carbomer concentrations (1.5, 2.25, and 3%; w/w). Obtained liposomal hydrogels, containing 0.15% (w/w) mTHPC, 10% (w/w) phospholipids, and 0, 0.5, or 1% (w/w) carbomer, were analyzed for flow properties, liposome particle size, and polydispersity index (PDI), pH value, and mTHPC content after their preparation and at predetermined time intervals during 6 months of storage at 4 and 23 degrees C. All hydrogels showed, during the whole period of investigation, adequate characteristics for topical application (i.e., they revealed shear-thinning plastic flow behavior). Rheological parameters, particle size, and PDI of liposomes in hydrogels, mTHPC content, and pH value did not show remarkable changes during the storage of gels, which could make them unacceptable for topical use. The obtained results indicated physical and chemical stability of liposomal gels containing mTHPC during 6 months of storage at both temperatures.

Chlorin Nanoparticles for Tissue Diagnostics and Photodynamic Therapy.

BACKGROUND: Organic crystalline nanoparticles (NPs) are not fluorescent due to the crystalline structure of the flat molecules organized in layers. In earlier experiments with Aluminum Phthalocyanine (AlPc)-derived NPs, the preferential uptake and dissolution by macrophages was demonstrated [3]. Therefore, inflamed tissue or cancer tissue with accumulated macrophages may exhibit specific fluorescence in contrast to healthy tissue which does not fluoresce. The present study addresses the photobiological effects of NP generated from Temoporfin (mTHPC), a clinically utilized photosensitizer belonging to the chlorin family. METHODS: In-vitro investigations addressing uptake, dissolution and phototoxicity of mTHPC NP vs. the liposomal mTHPC formulation Foslip were performed using J774A.1 macrophages and L929 fibroblasts. For total NP uptake analysis, the cells were lysed, the nanoparticles dissolved and the fluorescence quantified. The intracellular molecular dissolution was measured by flow cytometry. Fluorescence microscopy served for controlling intracellular localization of the dissolved fluorescing molecules. Reaction mechanisms after PDT (mitochondrial activity, apoptosis) were analyzed using fluorescent markers in cell-based assays and flow cytometry. RESULTS: Organic crystalline NP of different size were produced from mTHPC raw material. NP were internalized more efficiently in J774A.1 macrophages when compared to L929 fibroblasts, whereas uptake and fluorescence of Foslip was similar between the cell lines. NP dissolution correlated with internalization levels for larger particles in the range of 200-500 nm. Smaller particles (45 nm in diameter) were taken up at high levels in macrophages, but were not dissolved efficiently, resulting in comparatively low intracellular fluorescence. Whereas Foslip was predominantly localized in membranes, NP-mediated fluorescence also co-localized with acidic vesicles, suggesting endocytosis/phagocytosis as a major uptake mechanism. In macrophages, phototoxicity of NPs was stronger than in fibroblasts, even exceeding Foslip when administered in identical amounts. In both cell lines, phototoxicity correlated with mitochondrial depolarization and enhanced activation of caspase 3. CONCLUSIONS: Due to their preferential uptake/dissolution in macrophages, mTHPC NP may have potential for the diagnosis and photodynamic treatment of macrophage-associated disorders such as inflammation and cancer.

Lowering photosensitizer doses and increasing fluences induce apoptosis in tumor bearing mice.

The objective of this study was to determine an optimal dose of photodynamic therapy (PDT) for inducing apoptotic tumor cells in vivo. In this context, mice bearing human tongue-squamous epithelium carcinomas were treated with various photosensitizer concentrations and fluences. Tumor apoptosis was imaged after 2 days via a self-designed DY-734-annexin V probe using near-infrared fluorescence (NIRF) optical imaging. Apoptosis was verified ex vivo via TUNEL staining. Apoptotic tumor cells were detected in vivo at a dose of 40 µg photosensitizer and a fluency of 100 J/cm(2). This is the lowest photosensitizer dose reported so far.

Cellular and molecular effects of the liposomal mTHPC derivative Foslipos in prostate carcinoma cells in vitro.

BACKGROUND: Meso-tetra-hydroxyphenyl-chlorine (mTHPC) is among the most powerful photosensitizers available for photodynamic therapy (PDT). However, the mechanisms leading to cell death are poorly understood. We here focused on changes at DNA and RNA levels after treatment with the liposomal mTHPC derivative Foslipos in vitro. METHODS: After determination of darktoxicity, laser conditions and uptake kinetics, PC-3 prostate carcinoma cells were subjected to PDT with Foslipos, followed by assessment of cell numbers directly (TP0) or 1h (TP1), 2h (TP2), 5h (TP5) and 24h (TP24) after illumination. Nucleic acids had been extracted for evaluation of RNA amounts and integrity as well as for estimation of abasic sites as a measure for DNA damage. Furthermore, expression changes of 84 genes related to oxidative stress were investigated by quantitative polymerase chain reaction. RESULTS: Already at TP0, the number of dead cells was significantly higher after PDT versus controls and at TP24 more than 90% of cells had been destroyed. PDT resulted in a severe damage of both RNA and DNA. Gene expression analyses revealed an impact of PDT on pathways for oxidative and metabolic stress, heat shock, proliferation and carcinogenesis, growth arrest, inflammation, DNA repair and apoptosis signaling. CONCLUSIONS: Mechanisms of Foslipos-mediated PDT comprise a combination of acute and delayed lethal effects in PC-3 cells. The latter may include death processes initiated by nucleic acid damage, activation of stress and growth arrest genes in combination with a reduced capability to adequately cope with oxidative toxicity. Our results will help to better understand molecular photodynamic effects.