Induction of systemic neutrophil response in mice by photodynamic therapy of solid tumors.

Photodynamic therapy (PDT) of solid tumors elicits a strong, acute inflammatory response characterized by a rapid and massive infiltration of activated neutrophils into the tumor. The present study investigated the impact of PDT on the systemic and local (treatment site) kinetics of neutrophil trafficking and activity in mouse SCCVII and EMT6 tumor models. Differential leukocyte counts in the peripheral blood of treated mice revealed a pronounced neutrophilia developing rapidly after Photofrin porfimer sodium (Photofrin)- or tetra(m-tetrahydroxyphenyl)chlorin (mTHPC)-based PDT. Significant neutrophilia was also observed upon PDT treatment of normal dorsal skin but not on the footpad of tumor-free mice. The changes in circulating neutrophil numbers were accompanied by an efflux of these cells from the bone marrow. An increased proportion of cells with high L-selectin (CD62L antigen) expression was found among bone-marrow-residing neutrophils 6-24 h after PDT, and in neutrophils in the peripheral circulation and treated tumors 24 h after therapy. Complement inhibition completely prevented the development of PDT-induced neutrophilia. The results of the present study demonstrate that treatment of solid tumors by PDT induces a strong and protracted increase in systemic neutrophil numbers mediated by complement activation. This reaction reflects rapid and massive mobilization and activation of neutrophils for the destruction of PDT-treated tumor tissue.

Nitric oxide production by tumour tissue: impact on the response to photodynamic therapy.

The role of nitric oxide (NO) in the response to Photofrin-based photodynamic therapy (PDT) was investigated using mouse tumour models characterized by either relatively high or low endogenous NO production (RIF and SCCVII vs EMT6 and FsaR, respectively). The NO synthase inhibitors Nomega-nitro-L-arginine (L-NNA) or Nomega-nitro-L-arginine methyl ester (L-NAME), administered to mice immediately after PDT light treatment of subcutaneously growing tumours, markedly enhanced the cure rate of RIF and SCCVII models, but produced no obvious benefit with the EMT6 and FsaR models. Laser Doppler flowmetry measurement revealed that both L-NNA and L-NAME strongly inhibit blood flow in RIF and SCCVII tumours, but not in EMT6 and FsaR tumours. When injected intravenously immediately after PDT light treatment, L-NAME dramatically augmented the decrease in blood flow in SCCVII tumours induced by PDT. The pattern of blood flow alterations in tumours following PDT indicates that, even with curative doses, regular circulation may be restored in some vessels after episodes of partial or complete obstruction. Such conditions are conducive to the induction of ischaemia-reperfusion injury, which is instigated by the formation of superoxide radical. The administration of superoxide dismutase immediately after PDT resulted in a decrease in tumour cure rates, thus confirming the involvement of superoxide in the anti-tumour effect. The results of this study demonstrate that NO participates in the events associated with PDT-mediated tumour destruction, particularly in the vascular response that is of critical importance for the curative outcome of this therapy. The level of endogenous production of NO in tumours appears to be one of the determinants of sensitivity to PDT.

Contribution of myeloid and lymphoid host cells to the curative outcome of mouse sarcoma treatment by photodynamic therapy.

Selective depletion or inactivation of specific myeloid populations (neutrophils, macrophages) and lymphoid populations (helper T cells, cytolytic T cells) in EMT6 sarcoma-bearing mice was used to determine the contribution of each of these host immune cell types to the curative outcome of Photofrin-based photodynamic therapy (PDT). Immunodepletion of neutrophils and cytolytic T cells initiated immediately after PDT resulted in a marked reduction in PDT-mediated tumor cures. Significant reduction in the cures of EMT6 tumors was also achieved by immunodepletion of helper T cells and inactivation of macrophages by silica treatment. The initial tumor ablation by PDT was not affected by any of the above depletion treatments. These results provide direct evidence that the contribution of neutrophils, macrophages and T lymphocytes is essential for the maintenance of long-term control of PDT-treated tumors.

Enhancement of tumour response to photodynamic therapy by adjuvant mycobacterium cell-wall treatment.

Mycobacterium cell-wall extract (MCWE) is a potent non-specific immunostimulant that elicits a local inflammatory response associated with antitumour activity. Tumour-localized administration of MCWE has been examined as an adjuvant to photodynamic therapy (PDT) mediated by the photosensitizers Photofrin, benzoporphyrin derivative monoacid (BPD), metatetrahydroxyphenylchlorin (mTHPC), or zinc (II)-phthalocyanine (ZnPc). A single MCWE treatment, given immediately after light treatment of murine EMT6 tumours, potentiates the curative effect of PDT. A similar enhancement of tumour response to Photofrin-based PDT is obtained with the live Bacillus Calmette-Guérin (BCG) vaccine. Despite differences in the kinetics/intensity of damage induction to tumour microvasculature and other characteristics underlying the mechanism of antitumour activity of Photofrin, BPD, mTHPC and ZnPc, there appear to be no marked differences in the therapeutic benefit of adjuvant MCWE therapy combined with the PDT mediated by these various photosensitizers. This may be related to the fact that MCWE elicits a wide range of immunomodulatory effects that could amplify and sustain the inflammatory/immune responses triggered by PDT. The enhancement of inflammatory effector cell activity is indicated by the increased infiltration of neutrophils and other myeloid cells at the expense of malignant cells found in the MCWE plus mTHPC-based PDT treatment group compared to the PDT-only group.