Photochemical and spectral characterization of peripherally modified porphyrazines

Abstract

The photochemical properties of a new family of porphyrazines with annulated strongly electron-withdrawing 1,2,5-selenadiazole rings were studied. The experiments were performed on three compounds, two metallated at the core with Mg(II) or Zn(II) ions, and a third one that was demetallated. The photostability of these porphyrazines was studied in solution according to the conditions recommended in the first version of the document issued by ICH. The substances analyzed were irradiated with a high-pressure mercury lamp (HBO-50). The samples were irradiated with wavelengths corresponding to the Soret and Q bands, selected by the use of appropriate filters. The method used for evaluation of porphyrazine photodecomposition was subjected to a validation procedure by determination of linearity, LOD, LOQ and precision. The photodegradation appeared to follow first-order kinetics. Quantitative evaluation of the photochemical decomposition was performed on the basis of the photodegradation parameters. Furthermore, quantum yields have been estimated using the quinine solution as a chemical actinometer. The experimental quantum yields were extrapolated to the initial concentration of porphyrazine to obtain the actual quantum yields. The photochemical stability of the PzMg(II) hexapropyl(selenadiazole)porphyrazine complex was found to be greater than that of the PzZn(II) complex and the demetallated Pz2H. The photosensitizing activity of the porphyrazines was evaluated by application of 1,3-diphenylisobenzofuran (DPBF) as a singlet oxygen chemical quencher. The values of singlet oxygen generation obtained for the compounds were compared with zinc phthalocyanine (ZnPc), used as a standard. The results revealed that the PzZn(II) derivative is the most efficient sensitizer. The quantum yield of singlet oxygen generation was φ = 0.85, 0.67 and 0.17 for PzZn, PzMg and Pz2H, respectively.