Magnetically responsive photosensitizing reagents for possible use in photoradiation therapy

Electric field-enhanced activation of hematoporphyrin derivative: effects on a human tumour cell line

In a recent report we described the effects of combined electroactivation and photoactivation of hematoporphyrin derivative (HPD) on human erythrocytes and established that activation-induced cell lysis was more pronounced when both modes of activation were sequentially applied to the system. Here we demonstrate that electric field-induced activation of HPD-treated HeLa cells results in cell death. This effect is shown to be dependant on both electric field strength and on HPD concentration. In addition, we demonstrate that exposure of HPD-treated cells to short and intense electric pulses prior to photoactivation, results in increased cell mortality. The results confirm our earlier suggestion that HPD may be activated in the presence of an applied electric field. The results further suggest that activation of photosensitizers using combined exposure to electric fields and light may play an important role in increasing the efficiency of photodynamic therapy (PDT) in the treatment of cancer.

Differential response of photosensitized young and old human erythrocytes to photodynamic activation

It has recently been proposed that photosensitized erythrocytes may play an important role in the delivery and targeting of agents such as photosensitizers and chemotherapeutics for use in cancer treatment. It has been suggested that loading of photosensitized erythrocytes with chemotherapeutic agents would provide an ideal means of combining both treatment modalities. The recent application of real-time confocal laser scanning microscopy to the study of immediate effects of photodynamic activation on photosensitized erythrocytes has enabled us, in this study, to distinguish between the differential susceptibility of age-density resolved sub-populations of human erythrocytes to photodynamic activation. In this study we demonstrate that younger (low age-density) sub-populations of photosensitized erythrocytes are less susceptible than older (high age-density) sub-populations to photodynamic activation. We also demonstrate that this phenomenon is exhibited by cells photosensitized using hematoporphyrin derivative and rose bengal as photosensitizers. In both cases no significant difference in uptake of photosensitizer by both populations could be observed using absorbance spectrophotometry. The study suggests that age-density resolution of erythrocytes prior to loading and photosensitization might provide a means of enhancing the release of loaded components from the photosensitized system and this would, in turn, enhance the potential use of photosensitized erythrocytes as delivery or targeting systems for use in combination cancer therapies.

Use of real-time confocal laser scanning microscopy to study immediate effects of photodynamic activation on photosensitized erythrocytes

With a view towards the design of systems capable of combining the use of chemotherapy and photodynamic therapy in the treatment of cancer and other disorders, it has been proposed that photosensitized erythrocytes might be employed as carriers/vehicles for agents such as cancer chemotherapeutics. In studying the light dependent release of entrapped agents from such a system, the efficacy of light induced release is usually studied by measuring release of an entrapped component into centrifugation supernatants following photoactivation. It has hitherto been extremely difficult to examine what occurs upon immediate irradiation at the microscopic level in real-time. In this study we demonstrate that, using real-time confocal laser scanning microscopy, it is possible to directly observe immediate short-term events occurring during direct irradiation with the visualizing beam. Following irradiation of photosensitized erythrocytes with the visualizing beam form the confocal scanning system, it was noticed that some from of cell-disruptive event occurred. In this study we demonstrate a dose dependent response between this relatively immediate, light induced disruptive event with respect to both irradiation exposure and photosensitizer concentration. We suggest that this system may provide a novel means of observing, at a microscopic level, events occurring in real-time during photodynamic therapy.