Distribution of hematoporphyrin derivative in the rat 9l gliosarcoma brain tumor analyzed by digital video fluorescence microscopy

A digital video fluorescence microscopy technique was used to evaluate the distribution of hematoporphyrin derivative (HPD) in the rat intracerebral 9L gliosarcoma brain-tumor model at 4, 24, 48, and 72 hours after intravenous administration of 10 mg/kg of the drug. Compared to surrounding normal brain, there was significant preferential uptake of HPD into the tumor. In sections surveyed, fluorescence reached a maximum value by 24 hours; however, only 33% to 44% of the tumor was fluorescent. In contrast, fluorescence within the surrounding normal brain was maximum at 4 hours, but was present in less than 1% of the brain tissue evaluated. The effect of HPD sensitization to a laser light dose (633 nm) of 30 joules/sq cm delivered through the intact skull was evaluated histologically in 10 rats. A patchy coagulation necrosis, possibly corresponding to the distribution of HPD fluorescence seen within the tumor, was observed. There was evidence that photoradiation therapy (PRT) affects defective tumor vasculature and that a direct tumor cell toxicity spared normal brain tissue. Despite these findings, limited uptake of HPD in tumor and the brain adjacent to tumor may decrease the effectiveness of PRT in the 9L gliosarcoma brain-tumor model. Because of the similarity between the capillary system of the 9L tumor and human brain tumors, PRT may have a limited therapeutic effect in patients with malignant brain tumors.     

Photoradiation therapy causing selective tumor kill in a rat glioma model

We evaluated the effect of photoradiation therapy using the photosensitizer, hematoporphyrin derivative (HpD), and the argon-pumped rhodamine dye laser tuned to 630 nm in the rat C6 glioma model. Animal models of cerebral glioma were established by implanting 10(6) C6 glioma cells in adult Wistar rats, and craniotomies were performed on normal and tumor-bearing animals. HpD in doses of up to 80 mg/kg followed by craniotomy resulted in no damage to the normal brain, and laser light at doses of up to 1200 joules/cm2 without the prior administration of HpD produced no significant damage if the craniotomy site was irrigated with normal saline to prevent a temperature rise. Photoradiation caused no brain necrosis in non-tumor bearing animals if less than 20 mg of HpD per kg and 200 joules of red light per cm2 were used. At higher doses of HpD and light, cerebral necrosis did occur. The depth of necrosis depended on the dose of both HpD and light. Treatment with 40 mg of HpD per kg and 400 joules of light per cm2 resulted in cerebral necrosis in 50% of the treated animals. The mean depth of brain necrosis was 1.3 mm. Selective kill of a cerebral glioma with sparing of the normal brain was achieved with photoradiation therapy at doses of HpD of less than 20 mg/kg and light doses of less than 200 joules/cm2. At these doses, the mean depth of tumor kill was 4.5 mm. In 2 of 10 animals, the depth of tumor destruction was more than 6 mm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Photodynamic effects of SIM01, a new sensitizer, on experimental brain tumors in rats

BACKGROUND: Glioblastomas are the third most common cause of cancer death in patients between 15 and 35 years old. Literature suggests that PDT could represent a promising treatment, providing that sensitizers could accumulate within the cancer tissues despite the blood-brain barrier. METHODS: Distribution and PDT effect of SIM01, a promising photosensitizer, have been evaluated on orthotopic C6 tumor model in rats by comparison with HPD and m-THPC. Pharmacokinetics had been analyzed with fluorescence and ROS. Photodynamic treatment was done using a 630-nm light with an energy density of 100 J cm(-2) for HPD and a 652-nm light with an energy density of 20 J cm(-2) for m-THPC and SIM01. RESULTS: The correlation between fluorescence and ROS dosimetry was found to be excellent. An optimal concentration was found after 12 hours for SIM01 (4 mg/kg), 24 hours for HPD (10 mg/kg), and 48 hours for m-THPC (4 mg/kg). The best normal tissue/cancer ratio of concentration had been found after 12 hours for SIM01 and 48 hours for HPD and m-THPC. Pathological examinations after PDT showed that the criteria for histology of glioblastic origin were absent in SIM01-treated rats 12 hours after injection but were present in 50% of rats treated 24 hours after injection and in all after a 48-hour delay. Mean survival of rats treated 12 or 24 hours after SIM01 injection was significantly improved compared with controls, HPD-, or m-THPC-treated groups. Survival of rats treated 12 or 24 hours after SIM01 injection reached 20 days but decreased for longer delays. On the contrary, survival reached 18 days at the maximum for rats treated 48 hours after m-THPC or HPD injection. CONCLUSIONS: Our results confirm that PDT is a promising treatment for glioblastomas. SIM01 efficacy is as efficient as m-THPC but with much more favorable pharmacokinetics.     

Hematoporphyrin derivative photoradiation therapy of the rat 9L gliosarcoma brain tumor model

The distribution of hematoporphyrin derivative (HPD) in the rat 9L gliosarcoma intracerebral brain tumor model at 4, 24, 48, and 72 hours after intravenous administration was evaluated using a digital video fluorescence microscopy technique. Maximum tissue fluorescence in the normal brain was observed at 4 hours, whereas maximum fluorescence in the tumor regions occurred at 24 hours. Although the fluorescence counts suggested that there was significant uptake of HPD within the tumors when compared to normal brain, only 33% to 44% of each of the eight tumors surveyed showed fluorescence. In response to a laser light dose (633 nm) of 30 J/cm2, six rats that had been sensitized with HPD had a patchy coagulation necrosis involving up to 70% of the total tumor volume. In contrast, four rats given HPD only or exposed to laser only had no areas of necrosis, as observed on histological examination. In a group of 30 rats, no prolongation of survival was observed in response to photoradiation therapy.     

Photodynamic therapy of superficial bladder tumors

Photodynamic therapy (PDT), using hematoporphyrin derivative (HPD) and the red light (wavelength 630 nm) of an argon-dye laser as the source of excitation energy was performed on 46 patients with superficial bladder tumors. Two methods of laser irradiation, (1) focal PDT using a 400 micron quartz fiber through a cystourethroscope in 22 patients with superficial bladder tumors and (2) whole bladder wall total PDT using a motor-driven laser light scattering device in 24 patients with multifocal carcinoma in situ and/or dysplasia of bladder mucosa associated with multicentric concurrent superficial tumors, were used. The patients in (2) had been referred for total cystectomy, and 19 of these 24 patients had a history of several transurethral resections, hyperthermia and/or instillation therapy. HPD 2-4 mg/kg was i.v. injected 48 to 72 hours before PDT. Judging from the results of 60 protrusions treated by focal PDT, the light power should be 200 mW/cm2 for 5-10 minutes or more and the total light energy should be 100 J/cm2 or more in tumors up to 2 cm in size. With focal PDT, 4 of the 22 patients had no recurrence with the mean tumor free time of 20.8 months. In 6 of the 24 patients treated with total PDT using 10, 20 or 30 J/cm2 of light energy, there was no recurrence with a mean tumor-free time of 7.5 months and there was no significant relationship between the recurrence rate and total light energy used.     

Effect of hematoporphyrin derivative 2 on estrogen receptors in experimental mammary tumors

This study reports the effect of hematoporphyrin derivative 2 (HPD2) on estrogen receptors (ER) in the animal model used to develop the clinical ER assay. Fifty 200-g female Sprague-Dawley rats were given 20 mg of dimethylbenzanthracene by gastric intubation. Spontaneous mammary tumors occurred in 35 animals. Animals were anesthetized and 50% of each tumor was removed when the tumors were 2 cm in diameter. Animals were then randomized to receive 5 mg/kg (group A), 10 mg/kg (group B), or 0 mg/kg (group C) HPD2 intravenously 48 hours after biopsy. The remaining tumor was excised 48 hours post HPD2 injection. All samples were weighed, placed on ice, and frozen to -70 degrees C. ER assay was performed by batch run. Results (fmol/mg cytosol) were as follows: All animals (n = 35) pre HPD2 34.2 +/- 5.4, post HPD2 34.2 +/- 5.8; group A: (n = 11) pre HPD2 33.9 +/- 7.9, post HPD2 37.1 +/- 7.8; group B: (n = 13) pre HPD2 29.2 +/- 3.8, post HPD2 25.5 +/- 3.6; group C: (n = 11) pre HPD2 40.3 +/- 5.2, post HPD2 41.5 +/- 7.9. HPD2 does not affect ER in this animal model. Confirmatory studies with human tumor material must be completed.     

Photodynamic therapy for head and neck cancer xenografts in athymic mice

This study examines efficacy and optimal treatment variables of photodynamic therapy (PDT) for human head and neck squamous cancer (HNSC) xenografts in athymic mice. Two and four days after injection of hematoporphyrin derivative (HPD), tumors were illuminated with red light from an argon-dye laser. Sixty-three tumors were treated. With HPD dose and light intensity constant at 7.5 mg/kg and 100 mW/cm2, respectively, the extent of tumor necrosis was strongly dependent on duration of light exposure. There was no substantial difference in results for 30- and 60-minute treatment durations between animals injected with HPD 2 and 4 days before treatment. After 30 minutes treatment time, responses were seen in 8 of 10 mice (2 days post-HPD) and 11 of 12 mice (4 days post-HPD). After 60 minutes treatment time, toxicity was high. We conclude that, in this model, PDT is effective in selective killing of HNSC. For future comparison studies in this model, if the indicated HPD dose and light intensity are used we recommend a 2-day delay after HPD injection and a light exposure duration of 30 minutes.     

Synergistic enhancement of the efficacy of the bioreductively activated alkylating agent RSU-1164 in the treatment of prostatic cancer by photodynamic therapy

Bioreductively activated alkylating agents (BAA) require metabolic reduction to become cytotoxic. Hypoxia induces a massive increase in reductive metabolism activating BAA to their cytotoxic form. One of these BAA agents is cis-2,3-dimethyl 1-(2-nitro-1-imidazolyl)-3-(1-aziridinyl)-2-propanol referred to as RSU-1164. In a hypoxic environment, RSU-1164 is activated to a highly reactive bifunctional alkylating agent capable of crosslinking macromolecules which results in cell death. Photodynamic therapy (PDT) is a treatment modality which consists of the initial accumulation of hematoporphyrin derivative (HPD) within a tumor followed by the activation of the HPD by 630 nm. light to induce a cytotoxic response. The precise mechanism of PDT is not known, however, two actions of the activated HPD have been documented. The first is a direct cytotoxic effect, secondary to singlet oxygen production. The second is through vascular collapse and subsequent hypoxia. The combination of a chemotherapeutic agent like RSU-1164, which is activated by hypoxia, with PDT to produce such hypoxia, therefore, should greatly increase the efficiency and utility of RSU-1164. To test this hypothesis, Copenhagen rats bearing established Dunning R-3327 AT-2 prostate cancers were treated with PDT treatment alone (HPD 20 mg./kg. injected IP and then 24 hr. later, the tumor exposed to 630 nm. light at 400 mW/cm.2 for 30 min. [total dose 720 J/cm.2]), RSU-1164 alone (injected IP at a dose of 200 mg./kg.) or with the combination of this PDT treatment plus RSU-1164 given 30 min. before light exposure. These results demonstrated that this combinational treatment synergistically produces a greater retardation in the growth of the AT-2 tumor than either of the monotherapies of RSU-1164 or PDT alone.     

Photodynamic therapy: Optimal treatment parameters in murine fibrosarcoma

We have investigated the efficacy of photodynamic therapy (PDT) by using two preparations of haematoporphyrin derivative (HPD) that demonstrated different biological activities against experimental murine fibrosarcoma RIF-1 in C3H/He mice. We have been able to demonstrate a minimum clonogenic survival rate of 0.25% by using the more active HPD at 20 mg/kg with a 40-h retention time and a total laser light dose of 100 J/cm². Further, we noted that clonogenic survival rates of 21.6% and 25.0% respectively could be achieved by using the less active HPD (at 20 mg/kg) with a laser light dose of 150 J/cm², or the more active HPD (at 20 mg/kg) with a laser light dose of 20 J/cm². In both cases necrosis of the surrounding normal tissue was absent. Necrosis of the normal tissue surrounding the tumour was shown to be associated with high laser energy (100 J/cm² and higher) in conjunction with a high dose (20 mg/kg) of the more active HPD. A comparison of survival curves as a function of laser energy for the RIF-1 cells following PDT with the two different preparations of HPD showed a difference in the kinetics of cell death. A curve with a shoulder region and aD _o (mean lethal dose) of 41 J/cm² was obtained when the less active HPD was used, whereas PDT using the more active HPD resulted in a curve with no shoulder and aD _o of 16 J/cm².     

Photoradiation therapy of endobronchial lung cancers employing the photodynamic action of hematoporphyrin derivative

Thirty-five patients with tumors within the tracheobronchial tree were treated with photoradiation therapy (PRT) employing the photodynamic action of hematoporphyrin derivative (HPD). An effective protocol has been developed consisting of 3.0 mg/kg HPD given intravenously 72 hours prior to the bronchoscopic illumination of the endobronchial tumor sites with red light (630 nm) from an argon pumped dye laser. Light applicators were developed that provided surface (area) and insertion (volume) illumination of tumor masses. Average light dosages of 100 J/cm2 and 200 J/cm were used for surface and insertion illumination, respectively. Delivery rates were 200 mW/cm2 and 400 mW/cm. There was no immediate visible effect such as coagulation or charring noted. All malignant endobronchial tumors responded. Tumors included primary and metastatic lesions of various histologic types. Response was complete for tumor within the bronchus after one treatment in 80% of instances. The remaining cases required two treatments to obtain a complete response due to the extensive length of bronchus involved or because multiple sites were present. A complete response, that is, the full opening up of the lumen to the bronchial wall, was accomplished in all but one instance. Atelectatic lungs or lobes were re-expanded and reaerated. Dyspnea and cough became significantly less. The follow-up achieved to date indicates improvement in symptoms, activity level, and the return to work in a significant number of cases.     

Effects of photoradiation therapy on normal rat brain

Laser photoradiation of the brain via an optical fiber positioned 5 mm above a burr hole was performed after the injection of hematoporphyrin derivative (HpD) in 33 normal rats and 6 rats with an intracerebral glioma. Normal rats received HpD, 5 or 10 mg/kg of body weight, followed by laser exposure at various doses or were exposed to a fixed laser dose after the administration of HpD, 2.5 to 20 mg/kg. One control group received neither HpD nor laser energy, and another was exposed to laser energy only. The 6 rats bearing an intracranial 9L glioma were treated with HpD, 5 mg/kg, followed by laser exposure at various high doses. The temperature in the cortex or tumor was measured with a probe during laser exposure. The rats were killed 72 hours after photoradiation, and the extent of necrosis of cerebral tissue was measured microscopically. In the normal rats, the extent of brain damage correlated with increases in the dose of both the laser and the HpD. In all 6 glioma-bearing rats, the high laser doses produced some focal necrosis in the tumors but also damaged adjacent normal brain tissue. We conclude that damage to normal brain tissue may be a significant complication of high dose photoradiation therapy for intracranial tumors.     

Fluorescence localization of early colonic cancer in the rat by hematoporphyrin derivative.

Laser excitation of hematoporphyrin derivatives (HPD) localizing in tumors of the tracheobronchial tree and bladder is useful in the identification and treatment of those tumors. A comparable utility for HPD in the endoscopic localization of colonic tumors may be possible. In this study the ability of HPD to identify 1,2 dimethylhydrazine (DMH) induced colon cancer in rats is evaluated. A total of 111 rats were studied with HPD. Sixty-nine rats received weekly injections of DMH (20 mg/kg) and 42 received injections of the vehicle alone. Twenty-four hours after the intravenous injection of 5 mg/kg of HPD, 18 DMH-induced tumors were identified by visual fluorescence using excitation by either a blue light (390-436 nm) or an argon laser (488 and 514 nm). This represented 100% of the visually or microscopically detected tumors. Seventy-five fluorescent areas were noted that did not contain evidence of cancer. The majority (63) of false positive areas contained lymphoid follicles. All but 2 false positive areas (73/75, 97%, p less than .001) were seen in DMH-treated animals, suggesting that they were an artifact of DMH treatment. HPD fluorescence did not identify microscopic dysplasia. We conclude that HPD fluorescence is an effective method of identifying early colonic cancer and may have a potential clinical role in patients at high risk for colorectal cancer.     

Enhanced tumor control following sequential treatments of photodynamic therapy (PDT) and localized microwave hyperthermia in vivo

Photodynamic therapy (PDT), or photoradiation therapy (PRT), utilizing hematoporphyrin derivative (HPD) as photosensitizer and an argon-dye laser system as the light source, was used alone and in combination with localized microwave hyperthermia (2450 MHz) to treat axillary tumors of the SMT-F mammary carcinoma in mice. Thirty-minute heat treatments were applied either immediately before or immediately after a standard PDT treatment of 630 nm light at 75 mW/cm2 for 30 min (135 J/cm2) given 24 hr post-7.5 mg/kg HPD, intraperitoneally (i.p.). Tumor control as judged by lack of tumor regrowth 35 days or longer after the combined treatments was compared to that following each treatment when given alone. Little or no enhancement of tumor control was seen when sublethal temperatures of 37.5, 38.5, and 39.5 degrees C were applied for 30 min immediately following the PDT treatment. However, increasing levels of enhancement were seen when heat treatments of 40.5 and 41.5 degrees C or 44.5 degrees C, given for 30 min, were applied immediately before or after the photodynamic treatment.     

A phase I trial of naloxone treatment in acute spinal cord injury

Results of a Phase I trial of the opiate antagonist naloxone for treatment of patients with acute spinal cord injury are reported. Naloxone was administered in doses ranging from 5 to 200 mg/sq m (0.14 to 5.4 mg/kg) for up to 48 hours. The patients ranged in age from 16 to 79 years (mean 37 years). Twenty patients received naloxone as a loading dose of 5 to 50 mg/sq m (0.14 to 1.43 mg/kg), followed by a maintenance dose of 20% of the loading dose given as a continuous infusion hourly for 47 hours (Group 1). Nine patients received a loading dose of 100 to 200 mg/sq m (2.7 to 5.4 mg/kg) and a maintenance dose of 75% of the initial dose hourly for 23 hours (Group 2). These higher doses (2.7 to 5.4 mg/kg) have been found to be effective in experimental spinal cord injury. Neurological examinations were performed and somatosensory evoked potentials (SEP's) were obtained as soon after admission as possible and again 1, 2, 3, and 7 days, 3 weeks, and 6 weeks to 6 months after admission. The 20 Group 1 patients who received 1.43 mg/kg or less of naloxone showed no improvement in neurological status or SEP's. All but three (15%) of these patients had a complete neurological deficit at the time of admission. Treatment was begun an average of 12.9 hours after injury. Among the nine Group 2 patients treated with 2.7 mg/kg or more, there were five patients (56%) with incomplete deficits. This group received naloxone an average of 6.6 hours after admission. Two of the five Group 2 patients with incomplete lesions showed improvement in their neurological condition and/or SEP's within 36 hours of receiving the drug. One of the four Group 2 patients with a complete lesion at the time of admission was able to localize pressure sensation in his legs 36 hours after completion of the drug infusion. Four Group 2 patients (two with complete and two with incomplete lesions) have shown improvement in their SEP's, suggesting recovery of SEP's in a dose-related fashion. Four patients experienced increased pain after administration of the loading dose and during the maintenance infusion; in only one patient was this severe enough to require discontinuation of the drug. Of the 29 patients treated with naloxone, four died within 6 weeks of admission, for a mortality rate of 13.8%.(ABSTRACT TRUNCATED AT 400 WORDS)     

Photodynamic therapy with PAD-S31, a new hydrophilic chlorin photosensitizer, in an orthotopic rat bladder tumor model

PURPOSE: PAD-S31 (13,17-bis (1-carboxypropion) carbamoylethyl-3-ethenyl-8-ethoxyiminoethylidene-7-hydroxy-2,7,12,18-tetramethyl-porphyrin sodium) (Photochemical Co., Ltd., Okayama, Japan), 1 of the latest second-generation photosensitizers, has hydrophilic characteristics and excitation wavelengths of around 670 nm. Using an orthotopic rat bladder tumor model we investigated the biodistribution of PAD-S31 and assessed the antitumor effects of photodynamic therapy (PDT) with PAD-S31. MATERIALS AND METHODS: An orthotopic rat bladder tumor was established by implanting AY-27 cells in the bladder wall. After intravenous PAD-S31 administration the accumulation of PAD-S31 in the tumor and normal bladder wall was investigated by a fluorometric technique. One or 3 hours after intravenous administration of PAD-S31 (5 mg/kg) bladder tumors in rats were transurethrally irradiated at 100 mW/cm with a light dose of 50 to 200 J/cm. The efficacy of PDT was evaluated 7 days later by observation with an ultrathin cystoscope and histopathological examination. RESULTS: The ratio of PAD-S31 concentration in tumor tissue to that in normal bladder wall was more than 1 at all time points and it achieved a maximum (more than 10) 150 to 240 minutes after PAD-S31 administration. All rats that were irradiated at 100 J/cm 3 hours after PAD-S31 administration showed more than 50% tumor destruction. When the light dose was more than 150 J/cm, more than half of the rats showed complete tumor eradication, of which the average size was 6 mm. CONCLUSIONS: We report that PDT using PAD-S31 is effective for destroying bladder tumors in an orthotopic rat model. These experimental results suggest that this therapy could be a clinically promising method for the treatment of patients with bladder cancer.     

Photodynamic modulation of wound healing with BPD-MA and CASP.

BACKGROUND AND OBJECTIVE: Wound healing is an intricate process requiring the orchestration of cells, growth factors, cytokines, and the extracellular matrix. Cytokines, specifically TGF-beta, are believed to be instrumental in sustaining the fibrotic process, which leads to scarring. Photodynamic therapy (PDT) uses potent photosensitizers, which induce a wide range of effects on cells and the extracellular matrix. The influences of PDT on wound healing are not well known. STUDY DESIGN/MATERIALS AND METHODS: Seven full-thickness incisional wounds were placed on each of 24 hairless Sprague Dawly rats, three wounds on one flank serving as dark controls and four on the contralateral side treated with PDT. Wounds were created two days before, one hour before, or one hour after red light exposure with an argon ion pumped dye laser. Twelve rats were injected with 0.25 mg/kg or 0.5 mg/kg of the PDT drug, BPD-MA, and the other 12 with 5 mg/kg or 10 mg/kg of the PDT drug, CASP, 3 and 24 hours prior to irradiation of light, respectively. At low doses of both photosensitizers, animals were irradiated with 1, 5, 10, and 20 J/cm2. At higher doses of BPD-MA and CASP animals were treated with 10, 20, 50, and 100 J/cm2 of light. Wounds were examined each day for 14 days and noted for edema, erythema, inflammation, necrosis, and quality of scarring. Wounds were also photographed at day 0, 2, 5, 8, and 14 post-irradiation. All animals were sacrificed 14 days after irradiation and the wounds were evaluated by light microscopy. RESULTS: Grossly, animals treated with 0.25 mg/kg BPD-MA showed no effect with PDT. Animals treated with 0.5 mg/kg BPD, and 5 and 10 mg/kg CASP showed responses that varied with both light and drug dose. Erythema, edema, inflammation, and necrosis attributed to PDT were all observed, but there was no apparent influence of PDT on either the rate or final appearance of wound healing. Histologically, there were no apparent differences between treated and untreated sites, regardless of the drug, dose of light, or time of irradiation. CONCLUSION: A single PDT treatment given before or after skin wounds does not apparently alter wound healing even when PDT caused brisk inflammatory reactions. PDT may have effects that were not detected. We conclude that PDT does not greatly influence incisional skin wound healing in the rat model.     

Photodynamic therapy with chloroaluminum sulfonated phthalocyanine in the rat window chamber.

The efficacy of photodynamic therapy tumor destruction is dependent upon both the interruption of the tumor vasculature and the resultant production of unstable oxygen species causing cellular oxidation and death. Chloroaluminum sulfonated phthalocyanine (CASP) is a recently developed photosensitizer. In order to study the direct vascular effects of CASP on a non-tumor system, a rat window chamber was utilized. Twelve rats were implanted with the window chamber, and were divided into two groups of six. Three rats served as controls for each group (receiving light alone, CASP alone, or no treatment). The remaining 6 rats received 10 mg/kg CASP intravenously 4 days after chamber placement. Photoactivation with light was performed 24 hours after injection (power density 200 mW/cm2, irradiance 100 J/cm2, lambda = 675 nm). Utilizing integrating sphere measurements and image analysis, marked vascular changes in the form of initial vasospasm followed by vaso-constriction and loss of chamber neovascularization were noted in the CASP-PDT group. The control groups exhibited no significant changes. Manipulation of the chamber vasculature at strategic time-points may translate into improved response rates for photodynamic therapy in a tumor model.     

The morphological and functional changes in rat bladder following photodynamic therapy with phthalocyanine photosensitization

We have studied photodynamic therapy (PDT) in the rat bladder with a new photosensitizer, aluminium sulfonated phthalocyanine (AlSPc) given intravenously and intravesically. The microscopic distribution of photosensitizer fluorescence in the bladder wall was studied by laser fluorescence microscopy. Prior to PDT the bladder capacity and compliance were assessed by filling cystometry. Intravesical red light (675 nm.) from a copper vapour pumped dye laser was used to activate the photosensitizer using light doses of 20 to 200 J/cm2. Urodynamic and histologic changes were studied at intervals for up to three months. The fluorescence studies showed that AlSPc was eliminated from the deeper muscle layers more quickly than from the superficial layers of the bladder wall so that by 24 hours there was four times as much fluorescence from the mucosa and lamina propria compared to the deeper muscle. Control bladders illuminated with laser light alone showed no effects at these light doses. Animals treated 24 hours after sensitization showed a reduction in bladder capacity of up to 78% (20 J/cm2. light and 1.5 mg./kg.AlSPc). An initial reduction in compliance recovered in two weeks after low doses (0.5 mg./kg.) of AlSPc but was still abnormal at three months after higher doses (1.5 mg./kg.); though there was no long term histologic abnormality seen. Aluminium sulfonated phthalocyanine is a promising photosensitizer for bladder photodynamic therapy and using low doses of the drug it is possible to produce a superficial necrosis without muscle damage across a range of light doses. This heals by epithelial regeneration with no long term functional impairment. Direct absorption of this photosensitizer following intravesical administration seems unreliable.     

Photodynamic therapy of human ocular cancer

Photodynamic therapy (PDT), also known as photoradiation therapy, was employed in five patients with ocular tumors that had been photosensitized to hematoporphyrin derivative (HPD). In each case more conventional treatment had failed to control the tumor, or the patient was considered a poor candidate for surgical intervention because of advanced age or general health. Intravenous administration of 2.5-3.0 mg/kg HPD was followed by PDT 2-4 days later, using a dye laser tuned to a wavelength of 632 nm. Laser light was delivered either by a fiber optic probe maintained at a fixed distance, or via a slit lamp system, for intervals of up to 20 minutes. The levels of energy applied were mainly below 420 Joules/cm2, but for tumors less than 1 mm diameter energy levels were as high as 3000 J/cm2 with a conservative power value as low as 20 mW/cm2. Tumor response to PDT was disappointing. Although substantial superficial tumor necrosis occurred in several cases, it did not extend to the deeper levels of tumor tissue. In each instance surgical intervention became necessary. Deficiencies in the procedure are discussed.     

Photodynamic therapy for esophageal lesions: selectivity depends on wavelength, power, and light dose

BACKGROUND: Photodynamic therapy with 5-aminolevulinic acid-induced photosensitization could selectively eliminate esophageal epithelial lesions. This study aimed at optimizing laser parameters for 5-aminolevulinic acid photodynamic therapy of the normal rat esophagus. METHODS: Sixty rats received 200 mg/kg 5-aminolevulinic acid orally and were illuminated 3 hours later with either 633 or 532 nm light (n = 30 for each group) through an endoesophageal balloon catheter. Rats received either 8.3 or 25 J/cm diffuser, applied with a 33, 100, or 300 mW/cm diffuser. During illumination, tissue fluorescence measurements and light dosimetry were done. Rats were sacrificed at 48 hours after photodynamic therapy. RESULTS: During illumination, protoporphyrin IX fluorescence declined faster when a higher power output was used. Fluence rate at the esophageal surface was highest for 633-nm light. At 532 nm, light caused less damage to the epithelium and muscle than 633-nm light. Illumination with 33 mW resulted in selective epithelial ablation, whereas illumination with 300 mW caused muscle damage with minor epithelial damage. CONCLUSIONS: The assumed selective epithelial damage of 5-aminolevulinic acid photodynamic therapy in the esophagus largely depends on the combination of wavelength, power, and light dose applied. Most selective epithelial damage was found when low-power 633-nm light was used.