Photodynamic therapy (PDT) is an experimental treatment modality for malignant tumors. It is based on the principle that a photosensitizer, such as hematoporphyrin derivative (HPD), is retained in higher concentrations in tumors than in surrounding nonmalignant tissues and that photoactivation of the sensitizer can be used to evoke tumor destruction. However, retention of the systemic injection of HPD is not limited to malignant tissues. This lack of specific tumor localization thus reduces the therapeutic ratio of the treatment and causes skin photosensitivity and possible systemic toxicity. Injection of HPD directly into the tumor, on the other hand, has been shown to yield higher levels of the drug in the tumor and lower levels in normal tissues, in comparison with systemic administration. In this study, we examined the photodynamic effect on s.c. implanted mouse bladder tumors subjected to intratumor (i.t.) and i.p. HPD injections. Tumor cell killing, measured by cell survival, was observed in both the it. and i.p. groups and was dependent on fluence and HPD dosage. However, no significant enhancement of cell killing was observed in the i.t. injected tumors, despite the higher porphyrin levels in these tumors. Histological examination of the effect of PDT on the blood vessels indicated that while cell death accompanied severe hemorrhage in the i.p. injected tumors, in the i.t. tumors there was much less hemorrhage and intact blood vessels remained. This observation suggests that with i.t. administration, direct photodynamic action may play a significant role in the tumor cell killing, in contrast to systemic administration, in which destruction of the blood vessels is believed to be the main cause of tumor destruction.