HOW DOES PHOTODYNAMIC THERAPY WORK?

Those readers already familiar with the field of photodynamic therapy (PDT)t will consider this title somewhat presumptuous since it implies that the answer to the posed question is known. Indeed, answers to many questions regarding PDT have been found over the past decade, but a comprehensive understanding of all mechanisms involved in PDT tumor destruction has not yet emerged. This paper will attempt to deal with this complex subject by giving a sequential account of the effects occurring during PDT tissue treatment on a cellular and tissue level. Photodynamic therapy is based on the dye-sensitized photooxidation of biological matter in the target tissue (Foote, 1990). This requires the presence of a dye (sensitizer) in the tissue to be treated. Although such sensitizers can be naturally occurring constituents of cells and tissues, in the case of PDT they are introduced into the organism as the first step of treatment. In the second step, the tissuelocalized sensitizer is exposed to light of wavelength appropriate for absorption by the sensitizer. Through various photophysical pathways, also involving molecular oxygen, oxygenated products harmful to cell function arise and eventual tissue destruction results. In keeping with the chronological nature of this review, the subject matter will be divided into the

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