Comparison of the cellular molecular stress responses after treatments used in bladder cancer.

OBJECTIVE: To investigate the molecular stress responses related to the quality of recovery of normal tissue after various treatments for bladder cancer, i.e. hyperthermia, ionizing radiation, mitomycin-C and 5-aminolaevulinic acid photodynamic therapy (ALA-PDT). MATERIALS AND METHODS: The study focused particularly on intracellular fibroblast levels of heat-shock protein-47 (HSP47) and HSP72, which are associated with collagen metabolism and the development of tolerance to repeated treatment, respectively. Iso-effective treatment doses (50% clonogenic cell survival) of each method were delivered to a 3T6 murine fibroblast model. Intracellular extracts were analysed at 3, 6, 9, 12 and 24 h after treatment, using Western blot analysis to compare the levels of HSP47 and HSP72. Time-matched treatment and control groups were quantified by comparison with actin and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) expression using appropriate software. RESULTS: There were various changes in levels of HSP expression with treatment method; HSP47 levels were significantly higher after hyperthermia and radiation but not with mitomycin-C or ALA-PDT. HSP72 levels were significantly higher with all methods except ALA-PDT. CONCLUSIONS: Hyperthermia and ionizing radiation are associated with early increases in levels of HSP47 (a marker of collagen metabolism), in contrast to ALA-PDT and mitomycin-C. These findings are compatible with clinical findings where fibrosis/scarring is common with the first two but not the last two methods. In addition, all methods except ALA-PDT are associated with an increase in HSP 72 (a protein associated with cellular tolerance) and this may help to explain, at a cellular level, why resistance to repeated ALA-PDT treatments does not seem to occur.

Photodynamic therapy for superficial bladder cancer under local anaesthetic.

OBJECTIVES: To evaluate the use of local anaesthesia (LA) in 5-aminolaevulinic acid (ALA) photodynamic therapy (PDT) for superficial transitional cell carcinoma (TCC) of the bladder, and to provide further toxicity and tolerability data on this new method within the context of a phase 1 trial. PATIENTS AND METHODS: ALA PDT was administered to 19 patients with recurrent superficial TCC (stage Ta/carcinoma in situ, grades 1-3) using escalating doses of ALA (3-6%) and 633 nm laser light (25-50 J/cm2) under various LA (lignocaine) protocols. Pain was assessed using a linear analogue scale from 0 to 10. The endpoints of tolerability and toxicity were assessed for the different LA, light and ALA doses, with lignocaine levels. RESULTS: ALA PDT is painful and requires some form of anaesthesia. The discomfort was immediate, associated with bladder spasm, and was a function of the ALA concentration rather than the total light dose given. Simple passive diffusion (PD) of 2% lignocaine instilled for 40 min before PDT gave adequate anaesthesia with 3% ALA (n=8; median pain score 1, range 0-2). With 6% ALA the pain was dramatically increased using PD (n=6; median pain score 8, range 5-10) and therefore the more potent LA technique of electromotive drug administration (EMDA) of 2% lignocaine was used, with excellent results (n=3; median pain score 1, range 0-2). All patients had transient bladder irritability that typically lasted 9-12 days, with no subjective/objective change in long-term bladder function. No other toxicity was reported. Serum lignocaine levels were minimal. CONCLUSION: Bladder ALA PDT is both safe and feasible under LA. At a dose of 3% ALA, the procedure was well-tolerated using PD of lignocaine. At higher doses (6% ALA) more effective anaesthesia is required and this can be obtained satisfactorily with EMDA of lignocaine. With refinement, ALA PDT may be feasible as an outpatient treatment for superficial bladder TCC.

In vivo expression of the collagen-related heat shock protein HSP47, following hyperthermia or photodynamic therapy.

Heat shock protein 47 (HSP 47), a molecule expressed constitutively in cells that synthesise collagen, is involved in collagen type I biosynthesis, and after insult acts as a stress response molecule to sequester abnormal procollagen. Photodynamic therapy (PDT) is claimed not to result in extensive collagen damage, such as that which can occur after other laser treatments, e.g. hyperthermia (HT) or coagulation, thereby conferring on PDT a potential therapeutic advantage. In previous studies on mouse fibroblasts in vitro we demonstrated HSP47 elevation in the first hours after the application of conditions known to damage collagen, and an absence of HSP47 elevation following PDT with two well-established photosensitisers, haematoporphyrin ester (HpE) and meta-tetrahydroxyphenylchlorin (mTHPC). The present study examines HSP47 metabolism in murine skin following (1) HT, (2) PDT with HpE and (3) PDT with riboflavin (RB). Riboflavin was examined because of reports of collagen injury induced by its photoactivation. All three stresses were applied at grossly equitoxic, 'tolerance' doses. Three months after these doses, linear extensometry revealed the skin to have fibrotic characteristics after HT and RB PDT, but not after HpE PDT. HSP47 expression levels were analysed at transcriptional (Northern) and translational (Western) levels at early time intervals up to 24 h after the treatment application, starting immediately after the treatment for mRNA and 6 h post-treatment for protein. Highly significant upregulation of HSP47 was detected following HT, and PDT with RB. PDT mediated by HpE did not have any impact on HSP47 levels. These results were thus consistent with those from in vitro work and support the hypothesis of early elevation of HSP47 expression only by modalities affecting collagen or its precursors.

A comet assay of DNA damage and repair in K562 cells after photodynamic therapy using haematoporphyrin derivative, methylene blue and meso-tetrahydroxyphenylchlorin.

Single-cell electrophoresis (comet assay) has been used to evaluate DNA damage and repair in the human myeloid leukaemia cell line K562 after low-dose (predominantly sub-lethal) treatments of hyperthermia and photodynamic therapy (PDT). Three different photosensitizers were examined: haematoporphyrin derivative (HpD), methylene blue (MB) and meso-tetrahydroxyphenylchlorin (mTHPC). None of the drugs in the absence of light, nor in light alone, resulted in detectable DNA damage. However, a significant amount of DNA damage was detected immediately after treatment with haematoporphyrin derivative or methylene blue PDT compared with drug-only or light-only treatments; no residual level of DNA damage was evident for either drug following a 4-h post-treatment incubation at 37 degrees C. No significant DNA damage was detected after meso-tetrahydroxyphenylchlorin PDT or hyperthermia either immediately or 4 h after treatment. We conclude that the alkaline comet assay can be applied as an effective screening assay for DNA damage induced by a range of laser therapies.

Expression of the collagen-related heat shock protein HSP47 in fibroblasts treated with hyperthermia or photodynamic therapy.

Heat shock protein (HSP) 47 is associated with collagen type I metabolism, both constitutively and after stress-inflicted injury. It has been claimed that, in contrast to hyperthermia (HT), photodynamic therapy (PDT) does not damage collagen, as measured at the level of tissue. We have studied HSP47 expression in normal murine skin fibroblasts (3T6) treated with hyperthermia or photodynamic therapy (PDT) mediated by three different photosensitizers: (1) haematoporphyrin ester (HpE), (2) meta tetra hydroxyphenyl chlorin (mTHPC) and (3) riboflavin (RB). Riboflavin is not an established photosensitizer for PDT and was chosen here because it is known to provoke collagen damage. The applied doses of the treatments were isoeffective in terms of 3T6 clonogenic cell survival. Analysis, at both transcriptional and translational levels, revealed HSP47 elevation after hyperthermia and after PDT with RB. PDT sensitized by HpE and mTHPC did not significantly alter HSP47 expression. These observations are consistent with our hypothesis that this collagen chaperone is up-regulated by laser-mediated modalities known to damage collagen (i.e. HT and RB PDT) but not by more conventional PDT treatments. Additionally, unexpected significant up-regulation of HSP47 was detected after illumination alone (no photosensitizer) of 3T6 cells at 653 nm laser light, but not at 630 nm.

Low-level direct electrical current therapy for hepatic metastases. I. Preclinical studies on normal liver.

Low-level direct electrical current has shown promise as a potential therapeutic modality (direct current therapy; DCT) in the treatment of malignant disease, including metastases, but to date much experimental work has been empirical and has added little to our knowledge of the mechanisms involved. As a prerequisite to a clinical trial for metastases in the liver, we have employed an in vivo liver model to examine the quantitative and qualitative relationships between electrode polarity, charge and tissue necrosis. Two distinct regions of necrosis were induced, distinguishable histologically and by magnetic resonance imaging: (i) a cylindrical region of primary necrosis centred on the electrode, its volume directly proportional to the charge passed, but greater at the anode than cathode; and (ii) a wedge-shaped infarct, apex at the electrode and base extending to the liver edge. The extent of this infarct was again greater at the anode than the cathode, but showed a sigmoidal relationship with charge. Results indicate pH changes at the electrodes as likely mediators of tissue injury, but show also that significant distant ischaemic injury can occur as a consequence of primary damage. These findings should be considered when selecting tumours for possible direct current therapy and when determining the sites of electrode placement.

The effects of low-level direct current therapy on a preclinical mammary carcinoma: tumour regression and systemic biochemical sequelae.

Low-level direct electric current has been shown to be capable of destroying tumour tissue. Using an early-passage subcutaneous murine mammary carcinoma, the relationships between the volume of tumour destruction, charge and polarity have been examined. The results revealed a direct correlation between charge passed and absolute volume regression when the intratumoral electrode was made either an anode or a cathode. Tumour destruction for a given charge was significantly greater following anodic than cathodic treatment. A direct correlation was also observed between the percentage volume of prompt treatment-induced regression and the in situ end point of tumour growth delay. During the course of these experiments, a highly reproducible toxic effect was discovered, which has not been previously reported for this modality. An anodic charge greater than 10.6 coulombs or a cathodic charge greater than 21.6 coulombs resulted in 100% mortality at 24-72 h, while lower charges had no influence on mortality. Quantitative assays of a number of blood parameters showed that mortality was associated with serum electrolyte imbalances and appeared to be the result of the metabolic load of tumour breakdown products. These effects are similar to the tumour lysis or surgical crush syndromes and should not constitute a significant problem in clinical practice, where the tumour mass to total body mass ratio will normally be much smaller.

Vascular function and tissue injury in murine skin following hyperthermia and photodynamic therapy, alone and in combination.

The murine tail has been used as a model for injury to skin when hyperthermia (HT) and photodynamic therapy (PDT) using haematoporphyrin derivative, are used in combination. Skin injury by either agent alone was quantitated by the probability of tail necrosis as a function of dose of agent. 'Tolerance' doses of each modality were given and changes in skin vascular function were measured by the rate of clearance of 133Xenon. This was promptly inhibited but restored to normal by 7 days. The absolute numbers of hypodermal vessels of different sizes were measured in tail cross-sections and capillary numbers were found to be greatly reduced between 1 and 7 days, and restored to normal by 21-28 days. When a tolerance dose of PDT was followed at 1, 7, 21 and 28 days by test doses of HT, or vice versa, marked enhancements in probability of necrosis were observed when the interval was 1 or 7 days (Enhancement ratio (ER)PDT-HT = 1.5 and ERHT-PDT = 1.8). Prolonging the interval between modalities to 21-28 days spared the tissue (ERHT-PDT/21 DAYS = 1.1; ERPDT-HT/28 DAYS = 1.0). Close temporal apposition of PDT and HT, such as has been advocated to improve tumour control, may also increase injury to normal tissue through vascular effects common to both.