Determination of the in vivo pharmacokinetics of palladium-bacteriopheophorbide (WST09) in EMT6 tumour-bearing Balb/c mice using graphite furnace atomic absorption spectroscopy.

Palladium-bacteriopheophorbide (WST09), a novel bacteriochlorophyll derivative, is currently being investigated for use as a photodynamic therapy (PDT) drug due to its strong absorption in the near-infrared region and its ability to efficiently generate singlet oxygen when irradiated. In this study, we determined the pharmacokinetics and tissue distribution of WST09 in female EMT6 tumour-bearing Balb/c mice in order to determine if selective accumulation of this drug occurs in tumour tissue. A total of 41 mice were administered WST09 by bolus injection into the tail vein at a dose level of 5.0 +/- 0.8 mg kg(-1). Three to six mice were sacrificed at each of 0.08, 0.25, 0.5, 1.0, 3.0, 6.0, 9.0, 12, 24, 48, 72, and 96 h post injection, and an additional three control mice were sacrificed without having been administered WST09. Terminal blood samples as well as liver, skin, muscle, kidney and tumour samples were obtained from each mouse and analyzed for palladium content (from WST09) using graphite furnace atomic absorption spectroscopy (GFAAS). The representative concentration of WST09 in the plasma and tissues was then calculated. Biphasic kinetics were observed in the plasma, kidney, and liver with clearance from each of these tissues being relatively rapid. Skin, muscle and tumour did not show any significant accumulation at all time points investigated. No selective drug accumulation was seen in the tumour and normal tissues, relative to plasma. Thus the results of this study indicate that vascular targeting resulting from WST09 in the circulation, as opposed to selective WST09 accumulation in tumour tissues, may be responsible for PDT effects in tumours that have been observed in other WST09 studies.

Effects of Pd-bacteriopheophorbide (TOOKAD)-mediated photodynamic therapy on canine prostate pretreated with ionizing radiation.

The aim of this study was to evaluate the effects of photodynamic therapy (PDT) using a novel palladium bacteriopherophorbide photosensitizer TOOKAD (WST09) on canine prostate that had been pretreated with ionizing radiation. To produce a physiological and anatomical environment in canine prostate similar to that in patients for whom radiotherapy has failed, canine prostates (n = 4) were exposed to ionizing radiation (54 Gy) 5 to 6 months prior to interstitial TOOKAD-mediated PDT. Light irradiation (763 nm, 50-200 J/cm at 150 mW/cm from a 1-cm cylindrical diffusing fiber) was delivered during intravenous infusion of TOOKAD at 2 mg/kg over 10 min. Interstitial measurements of tissue oxygen profile (pO(2)) and of local light fluence rate were also measured. The prostates were harvested for histological examination 1 week after PDT. The baseline pO(2) of preirradiated prostate was in the range 10-44 mmHg. The changes in relative light fluence rate during PDT ranged from 12 to 43%. The acute lesions were characterized by hemorrhagic necrosis, clearly distinguishable from the radiotherapy-induced pre-existing fibrosis. The lesion size was correlated with light fluence and comparable to that in unirradiated prostate treated with a similar TOOKAD-PDT protocol. There was no noticeable damage to the urethra, bladder or adjacent colon. The preliminary results obtained from a small number of animals indicate that TOOKAD-PDT can effectively ablate prostate pretreated with ionizing radiation, and so it may provide an alternative modality for those prostate cancer patients for whom radiotherapy has failed.

Endobronchial phototoxicity of WST 09 (Tookad), a new fast-acting photosensitizer for photodynamic therapy: preclinical study in the pig.

Photodynamic therapy (PDT) has been used for many years for both palliative and curative treatment of bronchial carcinomas. However, prolonged skin phototoxicity and reduced depth of penetration has limited the widespread use of PDT. We studied the endobronchial phototoxicity of a novel photosensitizer, WST 09 (Tookad). Fourteen pairs of Large White-Landrace male piglets were given intravenous WST 09 followed by laser light illumination of the left mainstem bronchus. Different settings for light dose (fluence), fluence rate (FR), drug dose (D) and drug-light interval (DLI) were applied to each pair. Bronchial toxicity was assessed with repeat bronchoscopic photographic evaluation as well as by pathologic examination following autopsy. Animals developed no toxicity, moderate toxicity or severe toxicity. Increased toxicity was seen with increasing D and fluence and decreasing DLI, whereas no increased toxicity was seen with higher FR. PDT-related histological changes in the normal bronchus confirm the vascular effect of WST 09. Depending on the parameter settings for fluence, D and DLI, the lesions ranged from focal intramucosal ischemia to transmural infarction with subsequent acute inflammation and fibrosis. Clinically feasible parameters for drug and light dosimetry were documented. These data will be important in determining safe starting doses for human phase I/II studies.

Preclinical studies in normal canine prostate of a novel palladium-bacteriopheophorbide (WST09) photosensitizer for photodynamic therapy of prostate cancers.

Photodynamic therapy (PDT) uses light to activate a photosensitizer to achieve localized tumor control. In this study, PDT mediated by a second-generation photosensitizer, palladium-bacteriopheophorbide WST09 (Tookad) was investigated as an alternative therapy for prostate cancer. Normal canine prostate was used as the animal model. PDT was performed by irradiating the surgically exposed prostate superficially or interstitially at 763 nm to different total fluences (100 or 200 J/cm2; 50, 100 or 200 J/cm) at 5 or 15 min after intravenous administration of the drug (2 mg/kg). Areas on the bladder and colon were also irradiated. The local light fluence rate and temperature were monitored by interstitial probes in the prostate. All animals recovered well, without urethral complications. During the 1 week to 3 month post-treatment period, the prostates were harvested for histopathological examination. The PDT-induced lesions showed uniform hemorrhagic necrosis and atrophy, were well delineated from the adjacent normal tissue and increased linearly in diameter with the logarithm of the delivered light fluence. A maximum PDT-induced lesion size of over 3 cm diameter could be achieved with a single interstitial treatment. There was no damage to the bladder or rectum caused by scattered light from the prostate. The bladder and rectum were also directly irradiated with PDT. At 80 J/cm2, a full-depth necrosis was observed but resulted in no perforation. At 40 J/cm2, PDT produced minimal damage to the bladder or rectum. On the basis of optical dosimetry, we have estimated that 20 J/cm2 is the fluence required to produce prostatic necrosis. Thus, the normal structure adjacent to the prostate can be safely preserved with careful dosimetry. At therapeutic PDT levels, there was no structural or functional urethral damage even when the urethra was within the treated region. Hence, Tookad-PDT appears to be a promising candidate for prostate ablation in patients with recurrent, or possibly even primary, prostate cancer.