An improved photochemical model of embolic cerebral infarction in rats.
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To provide further evidence that the multiple cerebral infarcts found in rats following photochemical damage to the carotid artery are caused by emboli and to eliminate the systemic hypotension and heating of the blood reported with the previous photochemical embolic stroke model (rose bengal and a green laser), I have modified the photochemical technique. Brain pathology was studied in 18 Wistar rats following carotid artery irradiation with a red laser (632 nm) at powers ranging from 100 to 800 mW/cm2 for 10 or 20 minutes following the injection of the photosensitizing dye Photofrin II. Multiple cerebral arterioles were occluded by platelet aggregates containing frequent erythrocytes and leukocytes, identical to the thrombotic material in the carotid artery but different from the platelet aggregates seen in the carotid artery and the brain in the rose bengal model. Eighty infarcts were distributed randomly throughout the brain ipsilateral to the nonocclusive carotid thrombus. Significant heating (0.5 degree C or more) of the blood occurred only with laser powers higher (1,600 mW/cm2) or laser irradiations longer (25 minutes) than those used in the improved model of embolic stroke. This model mimics one mechanism of stroke in humans and provides a means to study systematically the morphological evolution of small cerebral infarcts. (+info)
Photosensitized release of von Willebrand factor from cultured human endothelial cells.
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Cultured endothelial cells from the human umbilical vein were incubated with low concentrations (1 microgram/ml) of the photosensitizer Photofrin II. Following a sublethal light exposure, a light dose-dependent release of von Willebrand factor (vWf) into the culture medium was observed. Analysis of the multimeric composition of the released protein indicated that it originated from the intracellular pool of large vWf multimers stored in the Weibel-Palade bodies. This release was detected as early as 1 h postirradiation. Release was inhibited at low temperature and was dependent upon the presence of extracellular calcium. Photosensitization resulted in an influx of calcium whose time course paralleled vWf release from the cells. Since vWf mediates platelet adhesion to the vascular subendothelium, it is possible that its photochemically stimulated release in vivo could contribute to platelet thrombus formation observed in tissue following photodynamic therapy. (+info)
Potentiation of thermal inactivation of glyceraldehyde-3-phosphate dehydrogenase by photodynamic treatment. A possible model for the synergistic interaction between photodynamic therapy and hyperthermia.
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Thermal inactivation of glyceraldehyde-3-phosphate dehydrogenase appeared to be caused by a conformational mechanism, without involvement of covalent reactions. On the other hand, photodynamic inactivation of the enzyme (induced by illumination in the presence of Photofrin II) was caused by photo-oxidation of the essential thiol group in the active centre. A short photodynamic treatment of the enzyme, leading to only a limited inactivation, caused a pronounced potentiation of subsequent thermal inactivation, as measured over the temperature range 40-50 degrees C. Analysis of the experimental results according to the Arrhenius equation revealed that both the activation energy of thermal inactivation and the frequency factor (the proportionality constant) were significantly decreased by the preceding photodynamic treatment. The experimental results indicate a mechanism in which limited photodynamic treatment induced a conformational change of the protein molecule. This conformational change did not contribute to photodynamic enzyme inhibition, but was responsible for the decreased frequency factor and activation energy of subsequent thermal inactivation of the enzyme. The opposing effects of decreased activation energy and decreased frequency factor resulted in potentiation of thermal inactivation of the enzyme over the temperature range 40-50 degrees C. With other proteins, different results were obtained. With amylase the combined photodynamic and thermal effects were not synergistic, but additive, and photodynamic treatment had no effect on the frequency factor and the activation energy of thermal inactivation. With respect to myoglobin denaturation, the photodynamic and thermal effects were antagonistic over the whole practically applicable temperature range. Limited photodynamic treatment protected the protein against heat-induced precipitation, concomitantly increasing both the frequency factor and the activation energy of the process. These results offer a model for one of the possible mechanisms of synergistic interaction between photodynamic therapy and hyperthermia in cancer treatment. (+info)
Hetergeneous tumour response to photodynamic therapy assessed by in vivo localised 31P NMR spectroscopy.
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Photodynamic therapy (PDT) is efficacious in the treatment of small malignant lesions when all cells in the tumour receive sufficient drug, oxygen and light to induce a photodynamic effect capable of complete cytotoxicity. In large tumours, only partial effectiveness is observed presumably because of insufficient light penetration into the tissue. The heterogeneity of the metabolic response in mammary tumours following PDT has been followed in vivo using localised phosphorus NMR spectroscopy. Alterations in nucleoside triphosphates (NTP), inorganic phosphate (Pi) and pH within localised regions of the tumour were monitored over 24-48 h following PDT irradiation of the tumour. Reduction of NTP and increases in Pi were observed at 4-6 h after PDT irradiation in all regions of treated tumours. The uppermost regions of the tumours (those nearest the skin surface and exposed to the greatest light fluence) displayed the greatest and most prolonged reduction of NTP and concomitant increase in Pi resulting in necrosis. The metabolite concentrations in tumour regions located towards the base of the tumour returned a near pre-treatment levels by 24-48 h after irradiation. The ability to follow heterogeneous metabolic responses in situ provides one means to assess the degree of metabolic inhibition which subsequently leads to tumour necrosis. (+info)
Isolation and initial characterization of mouse tumor cells resistant to porphyrin-mediated photodynamic therapy.
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Photodynamic therapy (PDT)-resistant variants of the RIF-1 mouse tumor cell line have been isolated following a protocol of repeated porphyrin incubation and light treatments. Two porphyrin incubation procedures, employing either an extended (16 h) or a short (1 h) incubation, were used in order to obtain cell strains exposed to conditions with differing intracellular photosensitizer localization. Two clones from each PDT porphyrin incubation protocol were selected for in vitro and in vivo analyses based on degree of resistance and plating efficiency. Resistant variants had increased protein content and were larger than the parental RIF-1 cells. In vitro growth rates were similar for all cell strains. Both 16-h PDT-resistant variants exhibited modest resistance to ionizing radiation and one of the 16-h PDT-resistant variants demonstrated increased sensitivity to hyperthermia. The PDT-resistant variants did not exhibit a multidrug resistance phenotype nor did they have altered porphyrin uptake properties. The parental and resistant RIF cells had comparable basal levels of antioxidant enzymes, reduced glutathione and stress proteins, but the number of cells required to produce in vivo tumor growth in 50% of inoculated animals was increased for all PDT-resistant variants. The resistant cells exhibit a stable phenotype and should be useful in studies designed to define PDT mechanisms of action. (+info)
Glucose regulated protein induction and cellular resistance to oxidative stress mediated by porphyrin photosensitization.
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Photodynamic therapy (PDT) utilizes a tumor localizing porphyrin photosensitizer in the clinical treatment of cancer. At a mechanistic level, porphyrin photosensitization generates reactive oxygen species which initiate oxidative damage to a wide spectrum of biomolecules. Cellular stress proteins are also increased following oxidative stress treatments. In the current study, we examined porphyrin photosensitizing parameters associated with induction of the glucose regulated family of stress proteins. Elevated levels of mRNA encoding glucose regulated proteins (GRPs) as well as increases in GRP protein synthesis were observed for mouse radiation induced fibrosarcoma cells exposed to an extended (16-h) porphyrin incubation prior to light exposure. However, a short (1-h) porphyrin incubation prior to light treatment (designed to produce comparable phototoxicity as PDT using the 16-h porphyrin incubation protocol) was associated with only minimal increases in GRP mRNA levels or GRP protein synthesis. The relationship between GRP levels and PDT sensitivity was examined in radiation induced fibrosarcoma cells pretreated with the calcium ionophore A-23187 in order to overexpress GRPs prior to photosensitization. Resistance to PDT was observed in cells overexpressing GRPs only under photosensitizing conditions associated with the extended porphyrin incubation protocol, and this response was not due to changes in cellular porphyrin uptake. In separate experiments, a transient elevation of GRP mRNA levels was observed in transplanted mouse mammary carcinomas following in vivo PDT treatments. Our results indicate that specific targets of oxidative damage (modulated by porphyrin incubation conditions) instead of generalized cellular exposure to reactive oxygen species are correlated with PDT mediated GRP induction. In this regard, GRP induction may be a useful in vivo biochemical marker of PDT mediated injury. These results also support the hypothesis that GRPs may play a role in modulating sensitivity to cellular stresses including certain types of oxidative injury. (+info)
Correlation of histology with biomarker status after photodynamic therapy in Barrett esophagus.
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In vitro and in vivo photosensitizing applications of Photofrin in malignant melanoma cells.
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BACKGROUND: The object of the present study was to evaluate the feasibility of photodynamic therapy (PDT) for malignant melanomas through in vivo and in vitro processes. METHODS: Photofrin (porfimer sodium) was evaluated through in vitro processes with human malignant melanoma cells (MMCs). The in vitro absorption and photosensitizing activity of Photofrin was examined in an MMC culture system. The in vivo biological activity of Photofrin applied to subcutaneous implanted melanoma (SIM) in nude mice and exposed to different total light dosages at 630 nm was studied by determining the destruction of the tumors. Subcelluar localization and binding were observed under a fluorescent confocal microscope. RESULTS: MMCs incubated with Photofrin at a concentration of about 3.5 microg/ml and exposed to laser light at 630 nm with a power density of 100 mW/cm2, showed 50% cell killing. An electron microscopic study demonstrated significant destruction of the target after PDT. CONCLUSION: Detection of the photosensitizer Photofrin was localized and its distribution fully observed. PDT-Photofrin has the capability to destroy MMCs through in vitro and in vivo SIM treatment. (+info)