The morphological changes in rat bladder after photodynamic therapy with 5-aminolaevulinic acid-induced protoporphyrin IX

OBJECTIVE: To assess the optimum light energy needed to induce only superficial bladder wall damage during photodynamic therapy (PDT) as a treatment for bladder cancer. Materials and methods The urinary bladder (with normal epithelium) of 64 female rats was treated with PDT using a continuous-wave argon-ion laser as an energy source and aminolaevulinic acid (ALA)-induced protoporphyrin IX photosensitizer. Four hours after the intravenous administration of ALA (300 mg/kg) the bladders were intravesically exposed to light fluences of 20-80 J/cm2. The control rats received no ALA and were exposed to 20 J/cm2 light. After 1, 3, 7 and 21 days the animals were killed and the morphological changes in bladder wall analysed both macroscopically and using light and scanning electron microscopy. RESULTS: At the dose of ALA given, a fluence of 20-40 J/cm2 caused mainly superficial damage, whereas 80 J/cm2 produced full-thickness injuries to the bladder wall. The maximum effect of PDT occurred after 1 and 3 days of irradiation. After 3 weeks of PDT the histology showed few full-thickness injuries and only in those treated with 80 J/cm2 light. CONCLUSION: These results indicate that PDT can be used to safely induce a selective superficial removal of bladder mucosa with no fibrotic effects on detrusor musculature, when optimum photosensitizing drug and fluences are used. These findings support the use of PDT in the therapy of superficial bladder cancer.     

The effect of photodynamic therapy on rat urinary bladder with orthotopic urothelial carcinoma

OBJECTIVE: To assess the effect of whole-bladder photodynamic therapy (PDT) on a rat model with orthotopic superficial bladder cancer, as PDT is an alternative intravesical therapy for treating superficial bladder cancer, based on an interaction between a photosensitizer and light energy to induce oxygen radicals that destroy tissue by lipid peroxidation. MATERIALS AND METHODS: In all, 76 female Fischer F344 rats were inoculated intravesically with AY-27 tumour cells. After establishing superficial tumour, 24 rats were treated with PDT using aminolaevulinic acid (ALA)-induced protoporphyrin IX as a photosensitizer, and a continuous-wave argon pumped-dye laser (638 nm). At 4 h after intravenous (300 mg/kg) or intravesical (100 mg/mL) administration of ALA the bladders were intravesically exposed to a 40 J/cm(2) light dose; 12 rats received no ALA but were exposed to the same light dose. Before administering ALA, urine cytology samples were taken for analysis. At 3 or 21 days the treated rats were killed and morphological changes in the bladder walls analysed by light microscopy. Forty rats served as controls to examine the presence of tumour. RESULTS: The tumour established in 33 of 40 rats (83%) in the controls, but after PDT with intravesical ALA there was carcinoma in only in one of 12 (P < 0.001, Pearson's chi(2) test). After PDT with intravenous ALA there was carcinoma in five of 11 rats (P = 0.063, Pearson's chi2 test). In the control group of 12 rats receiving only light energy there was carcinoma in three (P = 0.001, Pearson's chi(2) test). Histologically, at 3 days after PDT there was only mild superficial damage in all six rats treated intravesically. Bladder wall destruction reached the muscular layer, with an abscess in one of six rats treated intravenously. After 3 weeks of PDT there was muscular necrosis with perforation and abscess from catheterization two of six rats treated intravesically and in three the bladder wall totally recovered. In the intravenous group the bladder walls were normal or had only mild superficial damage. Cytology of the urine sediment failed to detect half the tumours in the treatment groups. CONCLUSION: These results support the use of PDT with intravesical ALA-induced protoporphyrin X for treating superficial bladder carcinoma. Intravesical was better than intravenous ALA in eradicating bladder carcinoma with PDT.     

Effect of aspirin on photodynamic therapy utilizing chloroaluminum sulfonated phthalocyanine (CASP).

The efficacy of photodynamic therapy (PDT) is mediated through a direct vascular effect. Interference with platelet function and resulting vascular stasis have been recently demonstrated utilizing the photosensitizer dihematoporphyrin ether (DHE). We examined the effect of aspirin, a known inhibitor of both cyclooxygenase and platelet activity, on PDT using chloroaluminum sulfonated phthalocyanine (CASP). Thirty-six rats implanted with a window chamber were given either 0.1 mg/kg (low dose) or 10 mg/kg (high dose) aspirin immediately before, immediately after, or 6 hours after the completion of CASP-PDT. Aspirin in either dosage did not appear to have any effect on the window vasculature when given immediately after light exposure. A moderate inhibition of vascular response was seen in animals treated with aspirin pre-PDT, whereas high-dose aspirin completely abrogated the CASP-PDT vascular response when given 6 hours post-PDT. These data indicate that aspirin can effect CASP-PDT in both time-dependent and dose-dependent fashions.     

Fluorescence detection and photodynamic treatment of photosensitized tumours in special consideration of urology

Most methods of modern laser tumour therapy are physically based on the conversion of light to heat. Recently tumours have also been treated using ionizing processes for tissue ablation. Photodynamic laser therapy (PDT), however, involves light-induced non-thermal biochemical processes and the use of a photosensitizer.Several drugs are known to be stored selectively in tumours after systemic application. This transient marking can be used for diagnostic and therapeutic procedures. The marker most commonly used is dihaematoporphyrin ether/ester (DHE) intravenously injected at doses of 0.2–3.0 mg/kg bodyweight for diagnosis and therapy, respectively. The corresponding clearance intervals after injection of DHE range from 3–48 h to 25–75 h.Detection of photosensitized tumours might offer great advantages. The highly sensitive two-wavelength laser excitation method with computerized fluorescence imaging recently has been transferred to the hospital for clinical tests.Photoinduced production of singlet oxygen is claimed to be the initial process which leads to later tumour destruction and therapy. PDT has been applied to 20 patients suffering from superficial tumours (TIS GII–III) recurred after application of other treatments. The results after PDT were evaluated by three-monthly check-ups (endoscopy, cytology, bladder mapping, renal ultrasonography) as well as by computed tomography (CT) examination at 8–13 month intervals. In six patients treated by PDT no tumour recurrence has been found over the whole observation period of up to 5 years. Four patients have remained free of tumour (12 and 14 months) after repeated transurethral resection (TUR) and Nd-YAG laser therapy following PDT. Due to an initial application of insufficient irradiation four patients required a second PDT. In one patient a circumscribed dysplasia appeared at the left ostium 26 months following PDT and was treated successfully by means of thermal Nd-YAG laser irradiation following TUR. In six patients slight mucosal atypia persisted for a period of at least 2.5 years. One cystectomy had to be performed because of bladder shrinkage. The dissected bladder, however, was free of tumour.These preliminary results suggest that PDT is justified in patients who are in a worst-case situation with cystectomy recommended in case of recurrent superficial TIS bladder carcinoma and indicate the future potential of photodynamic therapy of tumours.Homogeneous irradiation of the area to be treated and a reliable light dosimetry are prerequisites for an effective tumour therapy. Standard instruments for a routine application do not exist, but are under development.     

Green light photodynamic therapy in the human bladder

We conducted this pilot clinical study to investigate the safety, primarily acute toxicity, of green light (514.5 nm) whole bladder photodynamic therapy (PDT) in human bladders with transitional cell carcinoma. We enrolled five patients who were scheduled to undergo radical cystectomy and urinary diversion for locally muscle invasive bladder cancer. Four patients received intravenous injection of Photofrin at 1 mg/kg, while one patient received no drug, 48 hr before undergoing green light whole bladder photoactivation with light doses of 20-60 J/cm 2. Each patient underwent radical cystectomy on day 7 following light treatment. Post-PDT evaluation included daily monitoring of voiding symptoms, cystometric measurements of bladder capacity, and gross and histopathologic examination of the excised bladders. Our results show that the intensity of acute bladder irritation and acute post-PDT loss in bladder volume depended on the light dose and extent of bladder tumor with the associated inflammation. There was no transmural bladder injury and no treatment related morbidity. These data on acute toxicity suggest that green light whole bladder PDT treatment with 1 mg/kg of Photofrin and 20-40 J/cm 2 of laser power is safe.     

Comparison of two routes of photosensitizer administration for photodynamic therapy of bladder cancer

Photodynamic therapy (PDT) consists in administration of a photosensitizer and subsequent irradiation of the tumor with visible light. Routinely the photosensitizer is given intravenously (i.v.). The goal of our study was to examine whether intravesical (i.b.) instillation of the photosensitizer for PDT of bladder cancer might be feasible. Therefore, the uptake of chlor-aluminum-sulfonated phthalocyanine (CASPc) in bladder, bladder tumor, skin, and muscle in a rat bladder cancer model after i.v. injection and i.b instillation was compared. The efficacy of PDT after either method of administration was also evaluated. The CASPc concentration in bladder tumor after i.v. injection was approximately 1.5-fold that after i.b. instillation. The ratio of CASPc concentration between bladder tumor and normal bladder was approximately 2:1 after administration by either route. There was no systemic absorption of CASPc after i.b. instillation; hence no systemic side effects are expected. PDT showed similar effects on bladder tumor after either method of administration, but less side effects on normal bladder wall after i.b instillation. Our results demonstrate that i.b. instillation of CASP for PDT of superficial bladder cancer seems to have advantages over i.v. injection.     

Morphological effects of photodynamic therapy on rabbit bladder using Photofrin II and Photosan intravesically and intravenously.

Photodynamic therapy (PDT) has proved effective against superficial papillary bladder tumours and focal and diffuse carcinoma in situ. Effective topical administration of the sensitiser would be a welcome improvement. The morphological effects of PDT on the normal bladder were examined in 13 rabbits when 2 photosensitisers (Photofrin II and Photosan III) were applied intravesically (5 mg/kg for 1 h) and compared with intravenous administration (3 or 5 mg/kg). Four animals served as controls without a sensitiser. Intravesical red light (630 nm) from an argon dye laser was used to activate the photosensitiser, using light doses of 12 or 24 J/cm2. The animals were sacrificed either 1 or 5 to 7 days after the laser treatment. Intravenous dosage induced bladder wall oedema/haemorrhage and total necrosis of the epithelium. There was no difference between the effects of the 2 sensitisers. Intravesical application induced superficial epithelial necrosis. The control animals treated with laser light alone showed slight superficial injury to the cell layer.     

Lasers in surgery and medicine reviewers. November 1, 1992 through October 31, 1993

Chloro-aluminum sulfonated phthalocyanine (CASPc) is a photo-chemically active dye employed in photodynamic therapy (PDT). CASPc is a potent generator of singlet oxygen when irradiated with 675 nm light and is also capable of fluorescence, allowing visualization of the dye in tissues. We devised an angiography system using CASPc fluorescence to determine its localization in experimental choroidal neovascularization in monkeys and then investigated the ability of CASPc to produce photochemical closure of neovascularization upon irradiation with 675nm laser light. Fluorescent imaging indicated that CASPc localized angio-graphically in areas of neovascularization for at least 24 hours. Irradiation with 675 nm laser light 5–30 minutes after CASPc injection produced complete closure of choroidal neovascularization with minimal damage to overlying retina. We conclude that CASPc localizes in neovascular choroidal vessels and that CASPc photodynamic therapy can produce closure of these choroidal vessels. © 1994 Wiley-Liss, Inc.     

Photodynamic treatment as a novel approach in the therapy of arthritic joints

BACKGROUND AND OBJECTIVE: Minimal invasive local treatment of joints is a desirable option in the therapy of rheumatoid arthritis (RA). Aim of this study was to evaluate the effects of photodynamic treatment (PDT) with different doses of the photosensitizer meta-tetra(hydroxyphenyl)chlorin (m-THPC; or temoporfin) in a murine model of RA (antigen-induced arthritis, AIA). METHODS IN VIVO DISTRIBUTION: The distribution of native and liposomal m-THPC (including a formulation with polyethylene glycol [PEG] coating) was assessed by fluorescence spectrometry in arthritic joints, normal joints, and skin. TREATMENT: AIA mice received different concentrations of pegylated liposomal m-THPC (0.1, 0.05, 0.01, or 0.005 mg/kg body weight; n = 5 per group) and subjected to PDT with a laser system 12 hours post-injection of the photosensitizer. Treatment effects were evaluated histologically in comparison to untreated AIA (n = 5). RESULTS: Pegylated liposomal m-THPC showed the most favorable accumulation in arthritic joints compared to native m-THPC and to non-peg-liposomal m-THPC, therefore it was selected as photosensitizer for PDT treatment. In comparison to untreated AIA, PDT reduced the arthritic score with all doses of pegylated liposomal m-THPC; statistical significant effects were obtained with doses of 0.05 and 0.01 mg/kg. CONCLUSION: Our study demonstrated that local PDT of arthritic joints is feasible. Application of pegylated liposomal m-THPC for PDT resulted in significant reduction of arthritis scores.     

Comparison of intravenous and intravesical administration of chloro-aluminum sulfonated phthalocyanine for photodynamic treatment in a rat bladder cancer model.

Photodynamic therapy is an experimental treatment of superficial bladder tumors. Photofrin, a mixture of porphyrins, is the only photosensitizer in clinical use in the U.S.A. and its major side effect is prolonged cutaneous phototoxicity. In order to circumvent this problem of phototoxicity, new photosensitizers are being examined. Cutaneous phototoxicity may also be minimized by local administration of photosensitizer. Therefore, in this study, we investigated the photosensitizer chloro-aluminum sulfonated phthalocyanine (CASPc) in vivo in a rat bladder carcinoma model, and compared two different routes of CASPc administration. AY-27 rat bladder carcinoma cells were transplanted into rat bladders. Eight days after tumor transplantation the biodistribution of CASPc in bladder, skin, muscle and bladder tumor was determined by fluorescence measurements after dye extraction. Photosensitizer administered by intravenous injection and intravesical instillation, were compared. The concentration of CASPc in bladder and bladder tumor after intravenous injection and intravesical instillation was similar. The ratio of dye uptake between tumor and normal bladder after either administration was approximately two. Although no systemic absorption of the photosensitizer was observed after intravesical instillation, there was no reduction in tumor uptake or in the ratio between tumor to normal surrounding tissue. Therefore, no systemic side effects of skin phototoxicity are expected upon intravesical instillation. The microscopic biodistribution of CASPc after intravenous injection and intravesical instillation was also compared. After intravenous injection, the photosensitizer was distributed within the whole tumor with increased fluorescence around the microvasculature. In the normal bladder wall, weak fluorescence was seen in the area of the vasculature in the submucosa and the muscularis. After intravesical instillation, strong fluorescence was detected only at the tumor surface and in normal urothelium; no fluorescence was found in other areas of the tumor or in submucosa or muscularis. A comparison of the photodynamic treatment of model bladder tumors showed that tumor destruction after either method was similar but that there were less side effects to normal bladder wall after intravesical instillation of the CASPc. Intravesical administration of photosensitizers may, therefore, be a viable alternative to intravenous injection with potential for reduced systemic and normal tissue toxicity.     

Phthalocyanine mediated photodynamic thrombosis of experimental corneal neovascularization: Effect of phthalocyanine dose and irradiation onset time on vascular occlusion rate

The aim of this study was to evaluate the possible influence of phthalocyanine dose and of time interval between phthalocyanine injection and irradiation commencement on the rate of experimental corneal neovascularization photodynamic thrombosis in albino rabbits. New corneal vessels were irradiated with a diode laser (670 nm, 2 mW) after the intravenous injection of chloroaluminum sulfonated phthalocyanine. Different animals were irradiated either 5 min after the injection of different phthalocyanine doses (3, 6, 8, 12, or 14 mg/kg), or at different times (5 min, 24 h, or 58 h) after a standard phthalocyanine dose (3 mg/kg) injection. Irradiation time necessary for vascular occlusion was recorded. Decrease of phthalocyanine dose as well as delay of irradiation onset resulted in a statistically significant increase of irradiation time. Electron and light histological examination revealed platelet thrombi inside irradiated corneal new vessels. Damage in the vascular endothelial cell membrane and in intercellular contact structure was noted, leading to disorganization of the endothelial cells layer and death of most endothelial cells. These results indicate that both early commencement of irradiation after phthalocyanine injection and phthalocyanine dose increase accelerate the rate of phthalocyanine mediated corneal neovascularization photodynamic thrombosis. Thrombosis seems to result from photochemically induced vascular endothelial cell damage. © 1994 Wiley-Liss, Inc.     

The fluorescence biodistribution and kinetics of aminolevulinic acid induced protoporphyrin IX in the bladder of a rat model with orthotopic urothelial carcinoma

PURPOSE: Photodynamic therapy is an alternative intravesical therapy modality for superficial bladder cancer. Aminolevulinic acid (ALA) induces the production of the endogenous photosensitizer protoporphyrin IX (PpIX). We compared intravenous versus intravesical administration of ALA and established the proper timing and dose of ALA for photodynamic therapy. To characterize the distribution of ALA in rat bladder tumor and normal bladder layers a cooled charge coupled device camera was used. MATERIALS AND METHODS: A total of 40 female Fisher F344 rats were used as test animals, including 36 inoculated with AY-27 tumor cells intravesically. PpIX accumulation was investigated by fluorescence microscopy comparing 100 and 300 mg./kg. intravenous administration with a 100 mg./ml. intravesical dose of ALA. Three areas of urothelium, submucosa and muscularis of the bladder wall were chosen for analysis. The software used allowed semiquantitative analysis by calculating the mean fluorescence count plus or minus standard error of mean within any chosen area on the fluorescence image. RESULTS: In this study the highest fluorescence difference in PpIX accumulation in tumor and the normal epithelium to the muscularis layer was achieved at 2 hours with intravenous administration (7:1 to 50:1). The highest absolute fluorescence levels were observed at 2 hours with the 100 mg./kg. intravenous dose and at 4 hours with the higher 300 mg./kg. dose. The difference in fluorescence intensity in tumor tissue to normal urothelium was 2:1 to 3:1 at 2 hours. At 4 hours it was less than 2:1. After intravesical administration no difference in PpIX accumulation in tumor and normal urothelium was observed. However, there was a 7:1 ratio in regard to the muscularis layer at 4 hours. CONCLUSIONS: According to the results of this study a difference in PpIX accumulation in urothelial carcinoma or normal urothelium and the muscular layer of the bladder can be achieved by each route of ALA administration. Although intravesical installation provided tumor and normal urothelium labeling comparable to the intravenous route, it lost the selectivity of PpIX accumulation in tumor and normal urothelium. The effect of this finding on clinical therapy results remains to be resolved in the future.     

PHOTODYNAMIC THERAPY USING PORFIMER SODIUM AS AN ALTERNATIVE TO CYSTECTOMY IN PATIENTS WITH REFRACTORY TRANSITIONAL CELL CARCINOMA IN SITU OF THE BLADDER

Purpose

Photodynamic therapy combines a photosensitizer, such as porfimer sodium (Photofrin), with red laser light (630 nm.) to destroy cancer cells. Investigators have reported the effectiveness of photodynamic therapy in the treatment of patients with recurrent superficial bladder cancer. We assess the safety and efficacy of 1 or 2 photodynamic treatments using porfimer sodium and controlled uniform laser light (630 nm.) as an alternative to cystectomy in patients with refractory vesical carcinoma in situ of the bladder.

Materials and Methods

A total of 36 patients with carcinoma in situ were treated with whole bladder photodynamic therapy as an alternative to cystectomy. In all patients at least 1 course of bacillus Calmette-Guerin (BCG) had failed. Each patient received a single whole bladder photodynamic therapy treatment, consisting of 2 mg./kg. porfimer sodium intravenously followed 40 to 50 hours later by intravesical red light (630 nm.) at 15 J./cm.². Post-photodynamic therapy evaluations included weekly telephone contact to assess acute adverse reactions, and assessment of efficacy and bladder toxicity at 3 months and quarterly thereafter.

Results

At initial clinical evaluation at 3 months 58% of the patients had a complete response as indicated by negative cystoscopy, bladder biopsy and urine cytology but in 42% treatment failed. At a mean followup of 12 months (range 9 to 48) 10 of the 21 complete responders had recurrence for an overall durable response rate of 31%. Fourteen patients subsequently underwent cystectomy for persistent carcinoma in situ (12) and carcinoma in situ recurrence (2). Of the 36 patients 7 experienced bladder contracture.

Conclusions

The initial results are encouraging for a single whole bladder photodynamic treatment of patients in whom prior intravesical therapy for carcinoma in situ has failed. While followup is short, porfimer sodium photodynamic therapy appears potentially promising as an alternative to cystectomy in patients with refractory carcinoma in situ.     

Photodynamic therapy inhibition of experimental intimal hyperplasia: Acute and chronic effects

Purpose: Intimal hyperplasia (IH) is a focal arterial problem that still eludes successful therapy. We have previously demonstrated the feasibility of use of photodynamic therapy (PDT) for the acute treatment of experimental IH with light to activate an otherwise biologically inert photosensitizer. The purpose of this study was to determine the acute and long-term effects of PDT inhibition of IH on the artery wall.Methods: Segmental IH was induced by balloon injury localized to the cervical common carotid artery of 33 rats. The photosensitizer chloroaluminum sulfonated phthalocyanine (5 mg/kg) for the experimental group or saline solution for the control group was administered intravenously. Twenty-four hours later, all instrumented portions of arteries were irradiated at 675 nm to induce cytotoxic injury in the PDT-treated arteries as compared with laser only – treated arteries for controls. Animals were killed at 1, 2, 4, and 16 weeks.Results: There were no untoward side effects in either group. All PDT-treated arteries were devoid of smooth muscle or inflammatory cells in the treated media. There was no evidence of arterial degeneration of PDT-treated arteries. Only three arteries in the PDT group developed IH, whereas it was universal in all controls. In control arteries, immunocytochemistry with bromodeoxyuridine revealed maximal intimal and medial cell proliferation at 1 week, and morphometric analysis demonstrated a maximal IH at 2 weeks. Immunocytochemistry staining for smooth muscle cell actin was positive for the IH in control and when present in PDT-treated arteries, whereas the adventitia of PDT-treated arteries were positive after 2 weeks. Electron microscopy demonstrated early myofibroblast migration to the adventitia, and at 16 weeks occasional myofibroblasts were noted in the media of PDT-treated arteries. There was complete reendothelial cell covering of the intima by 4 weeks.Conclusions: These in vivo data demonstrate that PDT is an effective local method for the treatment of experimental IH. There is no evidence of significant recurrence of IH or arterial degeneration. Further studies with PDT may provide novel approaches to the understanding and treatment of arterial IH. (J VASC SURG 1994;19:321-31.)     

Comparative study between pulsed and continuous wave lasers for Photofrin® photodynamic therapy

A study was conducted in the normal canine esophagus to compare continuous wave (CW) and pulsed laser light for photodynamic therapy with Photofrin® (4 mg/kg). Forty-eight hours postinjection, 630 nm laser light (CW light from an argon-pumped dye-laser and pulsed light from a KTP/532-pumped dye-laser) was delivered using a 24 mm diameter cylindrical esophageal PDT balloon positioned at either distal or proximal esophagus. A 1.0 cm cylindrical diffuser placed in the center of the balloon delivered 300 J/cm of light at an intensity of 400 mW/cm. Three dogs received CW light proximally and pulsed light distally. Four dogs received CW light distally and pulsed light proximally. The light dose delivered to the esophageal mucosa was measured using three isotropic probes placed on the balloon wall. laser–induced fluorescence technique was used to compare photosensitizer fluorescence intensities at distal and proximal locations. Similar mucosal light doses and drug fluorescence intensities were verified for sites receiving pulsed or CW laser light. Two days after light delivery, the dogs were endoscoped to evaluate the severity of the lesions. While some response variability was observed among different animals, endoscopic examination of the lesions revealed comparable injury from CW and pulsed light in each subject. The animals were then euthanized and necropsies were performed. Based on the gross and histological examination of the lesions, the CW and pulsed laser–induced injuries could not be distinguished. © 1993 Wiley-Liss, Inc.     

Photodynamic therapy of head and neck basal cell carcinoma according to different clinicopathologic features

BACKGROUND AND OBJECTIVES: We aimed to treat different pathologic types of basal cell carcinomas (BCCs) using photodynamic therapy (PDT). STUDY DESIGN/MATERIALS AND METHODS: Thirty lesions in six patients underwent PDT. The photosensitizer used was Photoheme, a hematoporphyrin derivative IX. It was injected intravenously at the dose of 2-3.25 mg/kg. After 24 hours, the lesions were illuminated by laser light (lambda = 632 nm, light exposure dose = 100-200 J/cm2). Lesions were evaluated pre and post-operatively and at follow-up sessions (of up to 6 months). RESULTS: After a single session of PDT, the average response rate in different histopathologic kinds of basal cell carcinoma (e.g., ulcerative, superficial, nodular, and pigmented forms) were 100%, 62%, 90%, and 14%, respectively. In patients who responded completely, the cosmetic results were excellent and there were no recurrence at 6th month of follow-up. CONCLUSION: Although PDT seems to be an effective treatment modality for superficial, ulcerative, and nodular BCCs, it is not recommended for pigmented lesions.     

Treatment of perianal Paget’s disease using photodynamic therapy with assistance of fluorescence examination: case report

Our aim was to determine the usefulness of fluorescence examination and photodynamic therapy (PDT) for the management of perianal extramammary Paget’s disease. A 75-year-old woman underwent two courses of PDT. The first treatment was carried out with topically applied 5-aminolevulinic acid (ALA) to the affected area (2.5 × 2.5 cm²) 3 h before light treatment. We used ALA/protoporphyrin IX (PpIX)-mediated fluorescence to visualize the lesion and its margins. The lesion was treated with a 630 nm laser at 120 J/cm². Forty days later, the residual lesion was given a second treatment at the same light dose after topical application of ALA and intravenous injection of HiPorfin. ALA/PpIX-mediated fluorescence served as a useful tool to visualize the lesion’s location. Complete cure was achieved after the second course of PDT. During 7 months of follow up, no recurrence, scarring or functional loss was noticed. We concluded that ALA-assisted fluorescence examination can be a useful tool to determine the lesion and its margins. ALA-PDT is effective for superficial lesions, but, for thicker and deeper lesions, the systemic administration of photosensitizer is needed.     

Photodynamic efficiency of liposome-administered tetramethyl hematoporphyrin in two human bladder cancer cell lines

The main problems presented by superficial bladder carcinoma, its high recurrence rate and multifocal appearance, require treatment of the bladder as a whole. Photodynamic therapy (PDT) is one such experimental treatment for superficial bladder carcinoma, involving the administration of a photosensitizer that accumulates in the tumor tissue, and subsequent irradiation of the tumor with light. Since the photosensitizers used in PDT suffer from several drawbacks, new photosensitizers are being sought. Drug delivery systems are also being investigated for the administration of hydrophobic photosensitizers and enhancement of photodynamic efficiency and tumor selectivity. In this study we examined a new photosensitizer, tetramethyl hematoporphyrin (TMHP), in two human bladder cancer cell lines. In the first pair of the experiments, TMHP was bound to unilamellar liposomes. Cellular uptake, dark toxicity and photodynamic efficiency were then studied. Fluorescence microscopy showed TMHP localization in the cytoplasm in a perinuclear region, sparing the nucleus. Dark toxicity occurred after incubation of cells with TMHP above a concentration of 20 g/ml. Irradiation was carried out using an argon-pumped dye laser emitting a wavelength of 630 nm at a fluence of 3.6 and 7.2 J/cm². Before irradiation, cells were incubated with TMHP at concentrations of 2.5 and 5 g/ml for 1 h. Cell survival rates after incubation with 5 g/ml TMHP and irradiation at 7.2 J/cm² were 15.7% of control cells for Rec and 4.5% for Waf cells. Uptake studies showed a higher intracellular TMHP concentration in Waf than in Rec cells. This correlates with the higher PDT efficiency seen in Waf cells. Our results show that TMHP can be encapsulated into unilamellar liposomes without losing its photodynamic efficiency. TMHP is taken up by human bladder carcinoma cells after an incubation time of only 1 h. This short incubation time seems to be appropriate for an intravesical instillation of the photosensitizer for PDT in bladder cancer patients. Intravesical instillation might demonstrate higher phototoxic efficiency with reduced side effects. TMHP acts as a potent photosensitizer and shows drug- and light-dose-dependent cell destruction. Thus, TMHP has the potential for use in PDT in bladder cancer.     

Whole bladder photodynamic therapy for orthotopic superficial bladder cancer in rats: a study of intravenous and intravesical administration of photosensitizers

PURPOSE: Photodynamic therapy after intravenous injection of Photofrin (QLT Phototherapeutics, Vancouver, British Columbia, Canada) results in a contracted bladder and skin photosensitivity, which limits its clinical application. In an attempt to overcome these limitations photodynamic therapy after intravesical instillation of Photofrin or 5-aminolevulinic acid (ALA) in an orthotopic rat bladder tumor model was explored and compared with intravenous Photofrin for photodynamic therapy efficacy and phototoxicity. MATERIALS AND METHODS: At 2 weeks after bladder implantation of 1.5 x 10(6) AY-27 tumor cells animals were randomly grouped. Photofrin was administered (5 mg./kg. intravenously and 2 mg./ml. intravesically). The ALA concentration for intravesical instillation was 300 mM. Whole bladder photodynamic therapy with graded doses of light (lambda = 630 nm.) was performed 4 hours after drug administration. Tumor control and complications were evaluated. RESULTS: Photodynamic therapy with intravenous Photofrin plus 100 J./cm.(2) light resulted in severe bladder damage. Of 10 rats 6 died and 2 of the 10 that received 50 J./cm.(2) died. There were no photodynamic therapy related deaths in groups receiving intravesical instillation of Photofrin or ALA that also received 50 to 100 J./cm.(2) Median survival in rats treated with ALA intravesically plus 75 J./cm.(2) (77 days), Photofrin intravesically plus 50 (67) or 100 J./cm.(2) (76) and Photofrin intravenously plus 50 J./cm.(2) (60) were significantly different from that in controls (44). CONCLUSIONS: Intravesical instillation of Photofrin or ALA can achieve the same photodynamic therapy efficacy as intravenous Photofrin in this orthotopic rat bladder tumor model with less phototoxicity to normal tissues.     

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.