Relationship of tumor hypoxia and response to photodynamic treatment in an experimental mouse tumor.

The relationship between tumor oxygenation and the effectiveness of photodynamic therapy (PDT) was studied in vitro and in vivo using the RIF mouse tumor model. The oxygen dependence of photodynamic inactivation of RIF cells, which had been exposed to 25 mg/kg porphyrin (dihematoporphyrin ether) in vivo, isolated and illuminated in vitro, was determined. No cell kill was achieved under anoxic conditions, full effect was reached at 5% O2, and the half value of cell inactivation was found to be at 1% O2. Tumor hypoxia was assessed after in vivo gamma-irradiation of control and PDT-treated tumors by in vitro clonogenic assay of cell radiosensitivity. In vitro control experiments established that the radio-sensitivity of PDT-surviving RIF cells was identical to that of untreated control cells. RIF tumors of treatment size (80-120 mg) contained no detectable hypoxic tumor cell fraction. PDT treatment consisting of i.p. injection of 10 mg/kg dihematoporphyrin ether 24 h prior to 45 J/cm2 of 630 nm light, rendered approximately 9% of tumor cells severely hypoxic within 10 min of treatment time. An illumination period of 30 min (135 J/cm2) induced a hypoxic tumor cell fraction of 17%, which increased to 47% within 1 h posttreatment. Despite the prompt induction of tumor hypoxia during PDT light treatment, the tumors proved highly curable (81% cures) under the present treatment conditions (depilation of tumor area, 10 mg/kg dihematoporphyrin ether i.p., 135 J/cm2). Considering the reduced effectiveness of photodynamic cell kill at low oxygen concentrations, the rapid induction of tumor hypoxia by PDT itself, and the high tumor cure rate, it has to be concluded that in the RIF tumor hypoxic tumor cells are inactivated by a mechanism other than direct photodynamic cytotoxicity, and are thus not limiting to PDT tumor response.

[1]  T J Dougherty,et al.  Identification of singlet oxygen as the cytotoxic agent in photoinactivation of a murine tumor. , 1976, Cancer research.

[2]  I. Churchill-Davidson The Oxygen Effect in Radiotherapy — Historical Review , 1968 .

[3]  E. Hall,et al.  Cytotoxicity of Ro-07-0582; enhancement by hyperthermia and protection by cysteamine. , 1977, British Journal of Cancer.

[4]  Oxygen dependency of photocytotoxicity with haematoporphyrin derivative. , 1984, Photochemistry and photobiology.

[5]  J. Moan,et al.  The mechanism of photodynamic inactivation of human cells in vitro in the presence of haematoporphyrin. , 1979, British Journal of Cancer.

[6]  B. Henderson,et al.  Effects of scavengers of reactive oxygen and radical species on cell survival following photodynamic treatment in vitro: comparison to ionizing radiation. , 1986, Radiation research.

[7]  C. Gomer,et al.  ACUTE SKIN RESPONSE IN ALBINO MICE FOLLOWING PORPHYRIN PHOTOSENSITIZATION UNDER OXIC AND ANOXIC CONDITIONS , 1984, Photochemistry and photobiology.

[8]  T. Dougherty Photosensitization of malignant tumors. , 1986, Seminars in surgical oncology.

[9]  W. Star,et al.  Destruction of rat mammary tumor and normal tissue microcirculation by hematoporphyrin derivative photoradiation observed in vivo in sandwich observation chambers. , 1986, Cancer research.

[10]  J. Gray,et al.  A new mouse tumor model system (RIF-1) for comparison of end-point studies. , 1980, Journal of the National Cancer Institute.

[11]  S. Britton,et al.  Blood flow in transplantable bladder tumors treated with hematoporphyrin derivative and light. , 1984, Cancer research.

[12]  T. Mang,et al.  Tumor destruction and kinetics of tumor cell death in two experimental mouse tumors following photodynamic therapy. , 1985, Cancer research.

[13]  I. Freitas Role of Hypoxia in Photodynamic Therapy of Tumors , 1985, Tumori.

[14]  L. Tolmach,et al.  A Multicomponent X-ray Survival Curve for Mouse Lymphosarcoma Cells irradiated in vivo , 1963, Nature.

[15]  S. Zamvil,et al.  Response to the RIF-1 tumor in vitro and in C3H/Km mice to X-radiation (cell survival, regrowth delay, and tumor control), chemotherapeutic agents, and activated macrophages. , 1980, Journal of the National Cancer Institute.

[16]  M R Arnfield,et al.  Treatment of Dunning R3327-AT rat prostate tumors with photodynamic therapy in combination with misonidazole. , 1986, Cancer research.

[17]  B W Henderson,et al.  Interaction of photodynamic therapy and hyperthermia: tumor response and cell survival studies after treatment of mice in vivo. , 1985, Cancer research.

[18]  H. Reinhold,et al.  Tumour microcirculation as a target for hyperthermia. , 1986, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[19]  W. Degraff,et al.  Oxygen dependence of hematoporphyrin derivative-induced photoinactivation of Chinese hamster cells. , 1985, Cancer research.

[20]  T J Dougherty,et al.  The structure of the active component of hematoporphyrin derivative. , 1984, Progress in clinical and biological research.

[21]  J Moan,et al.  Oxygen dependence of the photosensitizing effect of hematoporphyrin derivative in NHIK 3025 cells. , 1985, Cancer research.

[22]  T. Dougherty,et al.  Haematoporphyrin derivative photosensitization and gamma-radiation damage interaction in Chinese hamster ovary fibroblasts. , 1986, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[23]  Oxygenation status of a transplantable tumor during fractionated radiation therapy. , 1968, Journal of the National Cancer Institute.