Theranostic Properties of Crystalline Aluminum Phthalocyanine Nanoparticles as a Photosensitizer.

The study of phthalocyanines, known photosensitizers, for biomedical applications has been of high research interest for several decades. Of specific interest, nanophotosensitizers are crystalline aluminum phthalocyanine nanoparticles (AlPc NPs). In crystalline form, they are water-insoluble and atoxic, but upon contact with tumors, immune cells, or pathogenic microflora, they change their spectroscopic properties (acquire the ability to fluoresce and become phototoxic), which makes them upcoming agents for selective phototheranostics. Aqueous colloids of crystalline AlPc NPs with a hydrodynamic size of 104 ± 54 nm were obtained using ultrasonic dispersal and centrifugation. Intracellular accumulation and localization of AlPc were studied on HeLa and THP-1 cell cultures and macrophages (M0, M1, M2) by fluorescence microscopy. Crystallinity was assessed by XRD spectroscopy. Time-resolved spectroscopy was used to obtain characteristic fluorescence kinetics of AlPc NPs upon interaction with cell cultures. The photodynamic efficiency and fluorescence quantum yield of AlPc NPs in HeLa and THP-1 cells were evaluated. After entering the cells, AlPc NPs localized in lysosomes and fluorescence corresponding to individual AlPc molecules were observed, as well as destruction of lysosomes and a rapid decrease in fluorescence intensity during photodynamic action. The photodynamic efficiency of AlPc NPs in THP-1 cells was almost 1.8-fold that of the molecular form of AlPc (Photosens). A new mechanism for the occurrence of fluorescence and phototoxicity of AlPc NPs in interaction with cells is proposed.

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.

Fluorescence investigation of the detachment of aluminum phthalocyanine molecules from aluminum phthalocyanine nanoparticles in monocytes/macrophages and skin cells and their localization in monocytes/macrophages.

BACKGROUND: Nanoparticles made from aluminum phthalocyanine (AlPc) are non-fluorescent in the nanoparticle form. Once AlPc molecules become detached from the particle, fluorescence occurs. Preliminary work showed the benefit of using aluminum phthalocyanine nanoparticles (nAlPc) for the rating of the rejection risk of skin autografts in mice by measuring fluorescence intensities of detached AlPc. Skin autografts showing a high fluorescence intensity were finally rejected suggesting an inflammatory process. In contrast, autografts with normal autofluorescence were accepted. This work was focused on the mechanism of this finding. The aim is detecting inflammatory processes and the potential use of nAlPc for PDT as a new treatment modality. METHODS: The effect of the lipopolysaccharide-stimulated monocyte/macrophage murine cell line J774A.1 on the monomerization of internalized nAlPc was tested. Further, we investigated the influence of J774A.1 cells and the normal skin cell lines L-929 or HaCaT on the dissolution of nAlPc by laser scanning microscopy and flow cytometry. Localization of AlPc molecules after uptake and dissolution of nanoparticles by the cells was surveyed. RESULTS: In co-culture models composed of J774A.1 and HaCaT/L-929 cells, the AlPc fluorescence intensity in J774A.1 cells is 1.38/1.89 fold higher, respectively. According to localization measurements in J774A.1 cells it can be assumed that nAlPc is taken up via endocytosis and remains in endosomes and/or lysosomes dissolving there. Detached molecules of AlPc cause rapture of the endosomal and/or lysosomal membrane after irradiation to become quite uniformly distributed in the cytoplasm. CONCLUSIONS: Evidence for monocytes/macrophages being the origin of the measured AlPc fluorescence in rejected skin autografts was confirmed.