Amelioration of Airway Stenosis in Rabbit Models by Photodynamic Therapy with Talaporfin Sodium (NPe6)

It is difficult to treat patients with acquired airway stenosis, and the quality of life of such patients is therefore lowered. We have suggested the application of photodynamic therapy (PDT) as a new treatment for airway stenosis and have determined the efficacy of PDT in animal disease models using a second-generation photosensitizer with reduced photosensitivity. An airway stenosis rabbit model induced by scraping of the tracheal mucosa was administered NPe6 (5 mg kg⁻¹), and the stenotic lesion was irradiated with 670 nm light emitted from a cylindrical diffuser tip at 60 J cm⁻² under bronchoscopic monitoring. PDT using NPe6 improved airway stenosis ( P  = 0.043) and respiratory stridor. A significant prolongation of survival time was seen in the PDT-treated animals compared to that in the untreated animals ( P  = 0.025) and 44% of the treated animals achieved long-term survival (>60 days). In conclusion, PDT using NPe6 is effective for improvement in airway stenosis.     

Photodynamic Therapy of 9L Gliosarcoma with Liposome-Delivered Photofrin

Abstract— The effect of Photofrin encapsulated in a liposome delivery vehicle for photodynamic therapy (PDT) of the 9L gliosarcoma and normal rat brain was tested. We hypothesized that the liposome vehicle enhances therapeutic efficacy, possibly by increasing tumor tissue concentration of Photofrin. Male Fisher rats bearing a 9L gliosarcoma were treated 16 days after intracerebral tumor implantation with either Photofrin in dextrose (n = 5) or Photofrin in liposome (n = 6). Nontumor-bearing animals were treated with Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle. Tissue concentrations of Photofrin delivered either in dextrose (n = 4) or liposome (n = 4) vehicle were measured in tumor, brain adjacent to tumor and in normal brain tissue. Photofrin was administered (intraperitoneally) at a dose of 12.5 mg/kg and PDT (17 J/cm₂ of 632 nm light at 100 mW/cm₂) was performed 24 h after Photofrin administration. Brains were removed 24 h after PDT and stained with hematoxylin and eosin for analysis of cellular damage. The PDT using Photofrin in the liposome vehicle caused significantly more damage to the tumor ( P < 0.001) than did PDT with Photofrin in dextrose. The PDT of tumor with Photofrin delivered in liposomes caused a 22% volume of cellular necrosis, while PDT of tumor with Photofrin delivered in dextrose caused only scattered cellular damage. Photofrin concentration in tumors was significantly higher ( P = 0.021) using liposome (33.8 ± 18.9 μg/g) compared to dextrose delivery (5.5 ± 1.5 μg/g). Normal brain was affected similarly in both groups, with only scattered cellular necrosis. Our data suggest that the liposome vehicle enhances the therapeutic efficacy of PDT treatment of 9L tumors.     

Photodynamic Therapy of Human Glioma (U87) in the Nude Rat

Abstract— We measured the response of normal brain and the human U87 glioma implanted in the brain of rats (n = 65) to photodynamic therapy (PDT) using Photofrin as the sensitizer. Normal brain and U87 tumor implanted within brain of athymic (nude) rats were subjected to PDT (12.5 mg/kg of Photofrin) at increasing optical energy doses (35 J/cm², 140 J/cm², 280 J/cm²) of 632 nm light. Photofrin concentration in tumor, brain adjacent to tumor and normal brain were measured in a separate population of rats. Twenty-four hours after PDT, the brains were removed, sectioned, stained with hematoxylin and eosin (H&E), and the volumes of the PDT-induced lesion measured. Photofrin concentration in tumor greatly exceeded that of normal brain and brain adjacent to tumor (>20×). Both normal brain and U87 tumor exhibited superficial tissue damage with PDT at 35 J/cm². However, both normal and tumor-implanted brain exhibited tissue damage with increasing optical dose. A heterogeneous pattern of pannecrosis along with a uniform volume of pannecrosis was detected in the tumor. In contrast, normal brain exhibited a uniform sharply demarcated volume of necrosis. Our data indicate that the U87 human brain tumor model and the normal brain in the athymic rat are sensitive to PDT and Photofrin with an optical dose-dependent response to treatment.     

Distribution and pharmacokinetics of Photofrin in human bile duct cancer

Prognosis of patients with bile duct tumors is mostly poor due to late diagnosis and a lack of adequate curative and palliative treatment modalities. To evaluate the potential of photodynamic therapy (PDT) as a novel and alternative treatment approach, we have investigated the uptake and tumor-specific localization of the photosensitizer Photofrin in human biliary tract neoplasms. We have quantified the distribution and the pharmacokinetics of Photofrin in normal and tumor tissue biopsies of the human bile duct by quantitative fluorescence microscopy and digital image analysis of cryosections. Fluorescence intensities (expressed as a percentage of a standard) are 19.0 +/- 11.4% and 25.2 +/- 12.7% for tumors and 10.9 +/- 2.9% and 13.2 +/- 9.1% (mean +/- SD) for normal bile duct tissue at 24 h (n = 5) and 48 h (n = 8) after Photofrin administration (2 mg kg-1 i.v.), respectively, and decrease afterwards in normal bile duct tissue over the period of investigation (4-35 days). The ratios of fluorescence in tumor versus normal tissue are found to be 1.7 +/- 0.7 and 2.3 +/- 1.2 (mean +/- SD) at days one and two after Photofrin administration, respectively. Thus, Photofrin preferentially accumulates in bile duct neoplasms, reaching peak values during the first two days. These data suggest that laser irradiation should be performed within this period after Photofrin injection to achieve tumor selectivity of PDT for effective treatment of bile duct carcinoma.     

Damage Threshold of Normal Rat Brain in Photodynamic Therapy

Normal brain tissue response to photodynamic therapy (PDT) must be quantified in order to implement PDT as a treatment of brain neoplasm. We therefore calculated the threshold for PDT-induced tissue necrosis in normal brain using Photofrin (porfimer sodium, Quadralogic Technologies Inc., Vancouver, BC) as the photosensitizer. The absolute light fluence-rate distribution for superficial irradiation and effective attenuation depth were measured in vivo using an invasive optical probe. Photosensitizer uptake in cerebral cortex was measured with chemical extraction and fluorometric analysis. Photodynamic therapy-induced lesion depths at various drug dose levels were measured as a biological end point. The PDT threshold for normal brain necrosis was calculated as in the magnitude of 10¹⁶ photons/cm³. Thus normal rat brain is extremely vulnerable to PDT damage. This suggests that extra precautions must be exercised when PDT is used in brain.     

Simultaneous two-photon excitation of photofrin in relation to photodynamic therapy

Photodynamic therapy (PDT), the use of light-activated drugs (photosensitizers), is an emerging treatment modality for tumors as well as various nononcologic conditions. Single-photon (1-gamma) PDT is limited by low specificity of the photosensitizer, leading to damage to healthy tissue adjacent to the diseased target tissue. One solution is to use simultaneous two-photon (2-gamma) excitation with ultrafast pulses of near-IR light. Due to the nonlinear interaction mechanism, 2-gamma excitation with a focused beam is localized in three dimensions, allowing treatment volumes on the order of femtoliters. We propose that this will be valuable in PDT of age-related macular degeneration (AMD), which causes blindness due to abnormal choroidal neovasculature and which is currently treated by 1-gamma PDT. Here, Photofrin has been used as the photosensitizer to demonstrate proof-of-principle of 2-gamma killing of vascular endothelial cells in vitro. The 2-gamma absorption properties of Photofrin were investigated in the 750-900 nm excitation wavelength range. It was shown that 2-gamma excitation dominates over 1-gamma excitation above 800 nm. The 2-gamma absorption spectrum of Photofrin in the 800-900 nm excitation wavelength range was measured. The 2-gamma cross section decreased from about 10 GM (1 GM = 10(-50) cm4 s/photon) at 800 nm to 5 GM at 900 nm. Adherent YPEN-1 endothelial cells were then incubated with Photofrin for 24 h and then treated by PDT at 850 nm where the 1-gamma contribution was negligible. Cell death was monitored with the use of 2-gamma scanning laser microscopy. The light doses required for killing were high (6300 J cm(-2) for approximately 50% killing), but 2-gamma cytotoxicity was unequivocally demonstrated. Although Photofrin is, per se, not a good choice for 2-gamma PDT due to its low 2-gamma cross section, this work provides baseline data to guide the development of novel photosensitizers with much higher 2-gamma cross sections (>100 GM), which will be required for 2-gamma PDT of AMD (and other conditions) to be clinically practical.     

The influence of photodynamic therapy on the ultrastructure of the normal rat bladder.

Reduced bladder capacity is a major side effect for patients receiving photodynamic therapy (PDT) for bladder cancer. A rat bladder model has been developed to address both the vascular and tissue effects of the photodynamic treatment of the urinary bladder. Bladders were exteriorized and positioned in a plexiglass tissue bath. Effects on microvasculature were assessed during PDT of the bladder by recording luminal diameter changes in arterioles and venules. Animals receiving Photofrin II (10 mg kg-1) 30 min prior to PDT scored a statistically significant reduction in the diameter of the red blood cell column in the vessels, whereas administration of Photofrin II 48 h prior to PDT was ineffective. Morphological changes included significant endothelial and vascular myocyte damage in the 30 min PDT group alone. Among the other tissue components, the mucosal lining was minimally affected and the response of the muscularis was highly variable. Smooth muscle cell changes ranged from mild contraction to frank necrosis with many of the affected cells located near the altered vascular beds. These data suggest that the clinical symptoms of reduced bladder capacity can be accounted for by vascular damage and myocyte sensitivity. Further refinements in the Photofrin II and light doses used in therapy may reduce bladder complications and allow for better management of bladder cancer.     

Photofrin as a specific radiosensitizing agent for tumors: studies in comparison to other porphyrins, in an experimental in vivo model

The use of ionizing radiation for tumor treatment represents a well established therapeutic modality. The efficiency and selectivity of radiotherapeutic protocols can be often enhanced by the addition of specific chemical compounds that optimise the response of the tumor to the incident radiation as compared with peritumoral tissue districts. The results of this study showed that Photofrin, a porphyrin derivative which is presently used as a tumor-photosensitizing agent in photodynamic therapy (PDT), can also act as an efficient tumor radiosensitizer. To test this possibility, we used nude mice subcutaneously implanted with human bladder cancer RT4. The mice were injected with different porphyrin-type photosensitizing agents, including Photofrin, 5-aminolevulinic acid, chlorin e(6), haematoporphyrin, protoporphyrin, Zn-tetrasulphophtalocyanine, and irradiated with 5 and 15 Gy using a Siemens X-ray device. Even though all the porphyrins accumulated in significant amounts in the neoplastic lesion, only Photofrin significantly improved the response of the tumor to irradiation by increasing the doubling time of the tumor volume from 6.2 days in the untreated control group to 10.9 days in the 5 and 15 Gy-irradiated groups. The tumor response was maximal with injected Photofrin doses of 7.5 mg/kg, and was not further enhanced by injection of higher doses. Our hypothesis is, that the radiosensitizing effect of Photofrin seems to be due to some oligomeric constituents which could specifically react with radiogenerated-radicals thereby amplifying the effect of the X-ray radiation.     

A COMPARISON OF SERUM KINETICS AND TISSUE DISTRIBUTION OF PHOTOFRIN II FOLLOWING INTRAVENOUS AND INTRAPERITONEAL INJECTION IN THE MOUSE

Abstract Although hematoporphyrin derivative (HPD) and its 'purers' variety Photofrin II are the most widely used tissue sensitizers in both clinical and experimental photodynamic therapy (PDT), quantitative studies of tissue distribution have been few. We have extracted and measured Photofrin II in several organs of the normal mouse including those of relevance to urological practice. In view of the reported heterogeneities in the distribution within tissues of various cytotoxics when administered intraperitoneally. we have compared results for Photofrin II given by this route with those for intravenous injection. Although both routes of administration gave equally consistent results, differences in absolute tissue concentration as a function of time after injection were found for several but not all tissues. Furthermore, the porphyrin accumulated following intravenous administration seemed to contain more of the non-polar photodynamically active component than that accumulated following the intraperitoneal route. We attempt to explain these differences by reference to published data on porphyrin binding to serum proteins.     

Subcellular Localization of Photofrin and Aminolevulinic Acid and Photodynamic Cross-Resistance in Vitro in Radiation-Induced Fibrosarcoma Cells Sensitive or Resistant to Photofrin-Mediated Photodynamic Therapy

Abstract— The subcellular and, specifically, mitochondrial localization of the photodynamic sensitizers Photofrin and aminolevulinic acid (ALA)-induced protoporphyrin-IX (PpIX) has been investigated in vitro in radiation-induced fibrosarcoma (RIF) tumor cells. Comparisons were made of parental RIF-1 cells and cells (RIF-8A) in which resistance to Photofrin-mediated photodynamic therapy (PDT) had been induced. The effect on the uptake kinetics of Photofrin of coincubation with one of the mitochondria-specific probes 10N-Nonyl acridine orange (NAO) or rhodamine-123 (Rh-123) and vice versa was examined. The subcellular colocalization of Photofrin and PpIX with Rh-123 was determined by double-label confocal fluorescence microscopy. Clonogenic cell survival after ALA-mediated PDT was determined in RIF-1 and RIF-8A cells to investigate cross-resistance with Photofrin-mediated PDT. At long (18 h) Photofrin incubation times, stronger colocalization of Photofrin and Rh-123 was seen in RIF-1 than in RIF-8A cells. Differences between RIF-1 and RIF-8A in the competitive mitochondrial binding of NAO or Rh-123 with Photofrin suggest that the inner mitochondrial membrane is a significant Photofrin binding site. The differences in this binding may account for the PDT resistance in RIF-8A cells. With ALA, the peak accumulations of PpIX occurred at 5 h for both cells, and followed a diffuse cytoplasmic distribution compared to mitochondrial localization at 1 h ALA incubation. There was rapid efflux of PpIX from both RIF-1 and RIF-8A. As with Photofrin, ALA-induced PpIX exhibited weaker mitochondrial localization in RIF-8A than in RIF-1 cells. Clonogenic survival demonstrated cross-resistance to incubation in PpIX but not to ALA-induced PpIX, implying differences in mitochondrial localization and/or binding, depending on the source of the PpIX within the cells.     

A self-expandable C-shaped 3D printing tracheal stent for combinatorial controlled paclitaxel release and tracheal support

Current tracheal stents palliatively relieve malignant tracheal stenosis but cannot treat the tumor, resulting in the occurrence of restenosis due to tumor progressive over-growth. Moreover, the stents block the entire tracheal mucosa contact with them and thus prevent mucus/sputum discharge, causing an airway blockage. In order to overcome those shortcomings, we study a novel self-expandable C-shaped tracheal stent loaded with paclitaxel (PTX), which consists of an inner poly (ε-caprolactone) layer, a middle Fe₃O₄ magnetic nanoparticles loaded poly (ε-caprolactone) layer and an outer PTX-loaded ethylene-vinyl acetate copolymer layer containing phase-change 1-hexadecanol. The C-shaped tracheal stents are easily fabricated on a roller by using a self-made specific three-dimensional printer. It is found that the stents present unidirectional PTX release, good self-expanding and appropriate trachea supporting properties, and generate heat to raise temperature under an alternating magnetic field, which facilitates temperature-responsive PTX release and permeation in tracheal tissue. The stents have good biosafety in rabbits and keep airway patency for the investigated period (1 month) without the occurrence of mucus/sputum blockage after implantation in rabbit trachea. This study provides a scientific basis for the development of novel self-expandable C-shaped tracheal stents with combinatorial tracheal support and local chemotherapy.     

Experimental tests of the feasibility of singlet oxygen luminescence monitoring in vivo during photodynamic therapy

Singlet oxygen (1O2) is thought to be the cytotoxic agent in photodynamic therapy (PDT) with current photosensitizers. Direct monitoring of 1O2 concentration in vivo would be a valuable tool in studying biological response. Attempts were made to measure 1O2 IR luminescence during PDT of cell suspensions and two murine tumour models using the photosensitizers Photofrin II and aluminium chlorosulphonated phthalocyanine. Instrumentation was virtually identical to that devised by Parker in the one positive report of in vivo luminescence detection in the literature. Despite the fact that our treatments caused cell killing and tissue necrosis, we were unable to observe 1O2 emission under any conditions. We attribute this negative result to a reduction in 1O2 lifetime in the cellular environment. Quantitative calibration of our system allowed us to estimate that the singlet oxygen lifetime in tissue is less than 0.5 microsecond. Some technical improvements are suggested which would improve detector performance and perhaps make such measurements feasible.     

PHOTODYNAMIC THERAPY OF NORMAL CEREBRAL TISSUE IN THE CAT: A NONINVASIVE MODEL FOR CEREBROVASCULAR THROMBOSIS

The early neuropathological response of normal cat brain to photodynamic therapy was investigated. Photofrin II was injected (IV) into a cat and photoactivated with red light from a filtered incandescent lamp. Animals were subjected to phototherapy either through the intact skull or with energy deposition onto the intact dura. Following photoactivation the animals were maintained for 6 h after which time the brain was removed and sections submitted for electron microscopic and or light microscopic study. Gross anatomical analysis of the photoactivated brain revealed hemorrhagic dusky discoloration limited to the area of the tissue illuminated. Animals that failed to show a lesion were cats characterized by low Photofrin II dosage and low photoactivation intensity. The microscopic cortical features of cats with lesions included prominent capillary congestion and regions of marked vacuolization and rarefaction. Blood vessels were structurally altered and the lumen of many vessels was completely filled with tightly packed erythrocytes. Our study suggests that the acute neuropathological response of cerebral tissue to photoactivation resembles that of microvascular thrombosis. It is thus reasonable to explore PDT of normal tissue as a non invasive model of cerebrovascular thrombosis in the cat.     

The role of the p53 tumor suppressor in the response of human cells to photofrin-mediated photodynamic therapy

Although there is evidence that the p53 tumor suppressor plays a role in the response of some human cells to chemotherapy and radiation therapy, its role in the response of human cells to photodynamic therapy (PDT) is less clear. In order to examine the role of p53 in cellular sensitivity to PDT, we have examined the clonogenic survival of normal human fibroblasts that express wild-type p53 and immortalized Li-Fraumeni syndrome (LFS) cells that express only mutant p53, following Photofrin-mediated PDT. The LFS cells were found to be more resistant to PDT compared to normal human fibroblasts. The D37 (LFS cells)/D37 (normal human fibroblasts) was 2.8 +/- 0.3 for seven independent experiments. Although the uptake of Photofrin per cell was 1.6 +/- 0.1-fold greater in normal human fibroblast cells compared to that in LFS cells over the range of Photofrin concentrations employed, PDT treatment at equivalent cellular Photofrin levels also demonstrated an increased resistance for LFS cells compared to normal human fibroblasts. Furthermore, adenovirus-mediated transfer and expression of wild-type p53 in LFS cells resulted in an increased sensitivity to PDT but no change in the uptake of Photofrin per cell. These results suggest a role for p53 in the response of human cells to PDT. Although normal human fibroblasts displayed increased levels of p53 following PDT, we did not detect apoptosis or any marked alteration in the cell cycle of GM38 cells, despite a marked loss of cell viability. In contrast, LFS cells exhibited a prolonged accumulation of cells in G2 phase and underwent apoptosis following PDT at equivalent Photofrin levels. The number of apoptotic LFS cells increased with time after PDT and correlated with the loss of cell viability. A p53-independent induction of apoptosis appears to be an important mechanism contributing to loss of clonogenic survival after PDT in LFS cells, whereas the induction of apoptosis does not appear to be an important mechanism leading to loss of cell survival in the more sensitive normal human fibroblasts following PDT at equivalent cellular Photofrin levels.     

RESISTANCE TO PHOTODYNAMIC THERAPY IN RADIATION INDUCED FIBROSARCOMA-1 and CHINESE HAMSTER OVARY-MULTI-DRUG RESISTANT CELLS in vitro

A degree of resistance to photodynamic therapy (PDT) has been induced in radiation-induced fibrosarcoma-1 (RIF-1) tumor cells by repeated photodynamic treatment with Photofrin (4 or 18 h incubation) in vitro to the 0.1-1% survival level, followed by regrowth from single surviving colonies. The resistance is shown as increased cell survival in the strain designated RIF-8A, compared to the wild-type RIF-1 cells, when exposed to increasing Photofrin concentration for 18 h incubation and fixed light exposure. No difference was found between RIF-1 and RIF-8A in the uptake of Photofrin per unit cell volume at 18 h incubation. Resistance to PDT was also observed in Chinese hamster ovary-multi-drug resistant (CHO-MDR) cells compared to the wild-type CHO cells, possibly associated with decreased cellular concentration of Photofrin in the former. By contrast, the PDT-resistant RIF-8A cells did not show any cross-resistance to Adriamycin, nor was there any significant drug concentration difference between RIF-1 and RIF-8A. These findings suggest that different mechanisms are responsible for PDT-induced resistance and multi-drug resistance.     

A Comparative Analysis of Silicon Phthalocyanine Photosensitizers for in vivo Photodynamic Therapy of RIF-1 Tumors in C3H Mice

Photofrin® photodynamic therapy (PDT) has recently received FDA approval for the palliative treatment of to-tally and partially obstructing esophageal malignancies. However, there is a need for new PDT photosensitizers because Photofrin has a number of undesirable features. The purpose of this study was to evaluate the efficacy of four amine-bearing silicon phthalocyanines—Pc4, Pc10, Pc12 and Pc18—as potential PDT photosensitizers. Equimolar concentrations of these Pc were found to be highly effective at causing the regression of RIF-1 tumors trans-planted to C3H/HeN mice. The amount of Pc4 necessary to cause an equivalent amount of tumor regression in this model system was substantially less than the amount of Photofrin. The cutaneous phototoxicity of the silicon Pc photosensitizer was assessed by the utilization of the murine ear-swelling model. When C3H mice were exposed to 167 J/cm² of polychromatic visible light from a UVB-filtered solar simulator, which emitted UV radiation and visible light above 320 nm, the Pc produced little, if any, cutaneous photosensitivity. These results indicate that Pc4, Pc10, Pc12 and Pc18 are at least as effective as Photofrin in PDT protocols, while at the same time addressing many of the drawbacks of Photofrin.     

In vivo TUMOR OXYGEN TENSION MEASUREMENTS FOR THE EVALUATION OF THE EFFICIENCY OF PHOTODYNAMIC THERAPY

Among the sequence of events which occur during photodynamic therapy (PDT) are depletion of oxygen and disruption of tumor blood flow. In order to more clearly understand these phenomena we have utilized transcutaneous oxygen electrodes to monitor tissue oxygen disappearance. These results provide, for the first time, non-invasive real-time information regarding the influence of light dose on tissue oxygenation during irradiation. Measurements were conducted on transplanted VX-2 skin carcinomas grown in the ears of New Zealand white rabbits. Rabbits were treated with Photofrin II and tumors were irradiated with up to 200 kJ/m2 (500 W/m2) of 630-nm light. Substantial reductions in tumor oxygen tension were observed upon administration of as little as 20 kJ/m2. For a series of brief irradiations, oxygen tension was modulated by the appearance of laser light. Tissue oxygen reversibility appeared to be dependent upon PDT dose. Long-term, irreversible tissue hypoxia was recorded in tumors for large (200 kJ/m2) fluences. These results suggest that transcutaneous oxygen tension may be useful as a general indicator of the effectiveness of PDT and as an in situ predictor of the energy required to elicit tumor damage.     

Silkworm-pheophorbide alpha mediated photodynamic therapy against B16F10 pigmented melanoma

In order to apply photodynamic therapy (PDT) to pigmented melanoma, the efficacy of PDT mediated by pheophorbide alpha from silkworm excreta (SPbalpha) and commercial Photofrin against B16F10 melanoma was comparatively studied from the in vivo assay using C57BL/6J mice. From in vitro PDT assay, the proliferation of B16F10 cells treated with SPbalpha (more than 0.5 microg/ml) and light illumination (1.2 J/cm2) were significantly inhibited with the necrotic response. This indicated that the photocytotoxicity of SPbalpha (665 nm) was not influenced by melanin from melanoma. From the assessment of the in vivo photosensitizing activity, the tumor growth was further delayed in groups treated with SPbalpha/PDT compared to that treated with Photofrin /PDT. The survival rate of tumor bearing mice treated with SPbalpha/PDT was closely associated with its photosensitizing effect. In addition, the photosensitizing effect of SPbalpha/PDT showed a dose dependent tendency in light illumination. These results demonstrated that B16F10 melanoma cells were significantly photosensitized by SPbalpha/PDT, regardless of the influence of melanin from melanoma, and SPbalpha/PDT at very low drug dose (1 mg/kg) and light dose (1.2 J/cm2) showed the photosensitizing efficacy surpassing Photofrin against B16F10 melanoma in mice system.     

Quantitative in vitro demonstration of two-photon photodynamic therapy using photofrin and visudyne

Photodynamic therapy (PDT), the combined action of a photosensitizer and light to produce a cytotoxic effect, is an approved therapy for a number of diseases. At present, clinical PDT treatments involve one-photon excitation of the photosensitizer. A major limitation is that damage may be caused to healthy tissues that have absorbed the drug and lie in the beam path. Two-photon excitation may minimize this collateral damage, as the probability of absorption increases with the square of the light intensity, enabling spatial confinement of the photosensitizer activation. A potential application is the treatment of the wet-form of age-related macular degeneration, the foremost cause of central vision loss in the elderly. Herein, the commercial photosensitizers Visudyne and Photofrin are used to demonstrate quantitative in vitro two-photon PDT. A uniform layer of endothelial cells (YPEN-1) was irradiated with a Ti:sapphire laser (300 fs, 865 nm, 90 MHz) using a confocal scanning microscope. Quantification of the two-photon PDT effect was achieved using the permeability stain Hoechst 33258 and a SYTOX Orange viability stain. Visudyne was found to be around seven times more effective as a two-photon photosensitizer than Photofrin under the conditions used, consistent with its higher two-photon absorption cross-section. We also demonstrate for the first time the quadratic intensity dependence of cellular two-photon PDT. This simple in vitro method for quantifying the efficacy of photosensitizers for two-photon excited PDT will be valuable to test specifically designed two-photon photosensitizers before proceeding to in vivo studies in preclinical animal models.     

DEPTH MEASUREMENTS AND HISTOPATHOLOGICAL CHARACTERIZATION OF PHOTODYNAMIC THERAPY GENERATED NORMAL BRAIN NECROSIS AS A FUNCTION OF INCIDENT OPTICAL ENERGY DOSE

The response of normal brain to photodynamic therapy (PDT) was investigated in 62 Fisher rats. The animals were injected i.p. with Photofrin II (12.5 mg/kg). Forty-eight hours following injection, an area of dura 5 mm in diameter over the frontal cortex was photoactivated with red light (632 +/- 2 nm) at 100 mW cm-2, with no contributing thermal increases, at optical energy doses ranging from 1-140 J cm-2 from an argon-pumped dye laser. Appropriate controls were also prepared. Brain tissue samples for histological analysis were taken 24 h following PDT treatment. Maximum lesion depth perpendicular to the pial brain surface, was measured using an eyepiece micrometer. Lesions of increasing depth were generated as the incident optical energy dose was increased. Fitting the depth of necrosis to a natural log dependence of incident optical dose yielded a slope of 0.83 mm/ln J cm-2 (r2 = 0.99). The intercept of 1.47 J cm-2 indicated the energy dose below which no normal tissue damage would occur at the incident laser intensity of 100 mW cm-2. The smallest lesions consisted almost exclusively of isolated neuronal injury and neuropil vacuolation, suggestive of an early ischemic lesion. Damage at the upper energy levels (35-140 J cm-2) consisted of complete coagulative necrosis identical to that induced by an arterial occlusion. The existence of viable tissue alongside neurons in various stages of necrosis at low energy levels (less than 35 J cm-2) is suggestive of reversible injury and possibly clinically relevant treatment levels.