Impact of acetylsalicylic acid on tumor angiogenesis and lymphangiogenesis through inhibition of VEGF signaling in a murine sarcoma model.

Aspirin is a salicylate drug that is widely used, and recently it has been shown to influence the development of various types of cancers. Our previous study revealed that aspirin had an inhibitory effect on the growth of S180 sarcoma and 3AO human ovarian cancer cells. The present study utilized a murine S180 sarcoma model to investigate the molecular mechanisms involved in aspirin-induced tumor growth inhibition. Tumor-bearing mice were randomly divided into five groups with 10 mice in each group: i) control; ii) 5-fluorouracil (5-FU); iii) high-dose aspirin (250 mg/kg); iv) low-dose aspirin (50 mg/kg); and v) combination of 5-FU and aspirin (50 mg/kg). The effect of aspirin on tumor growth was observed by measuring tumor volume and evaluating the antitumor effect. Tumor histology and immunohistochemistry were performed to detect the microvessel density (MVD), lymphatic vessel density (LVD), and the expression levels of vascular endothelial growth factor A (VEGF-A) and VEGF-C. The expression of VEGF-A and VEGF-C was also confirmed and quantified by western blotting. We discovered significant growth delay in murine S180 sarcoma as a result of aspirin treatment. The inhibition rate of tumor growth induced by high-dose and low-dose aspirin was 33.5 and 22.2%, respectively (P<0.05). The expression of VEGF-A and VEGF-C in tumor tissues inhibited by aspirin was demonstrated by immunohistochemistry, and the MVD was decreased in a dose-dependent manner (p<0.05). Reduced LVD was particularly apparent in the high-dose aspirin group (p<0.05). Western blot data showed that the expression of both VEGF-A and VEGF-C was reduced after treatment with aspirin. In conclusion, the impact of aspirin-induced tumor growth delay of murine S180 sarcoma may correlate with the inhibition of angiogenesis and lymphangiogenesis by reducing VEGF-A and VEGF-C expression in tumor tissues.

Synergistic antitumor effect of CXCL10 with hyperthermia.

PURPOSE: IFN-inducible protein 10 (IP-10)/CXCL10 (CXC chemokine ligand 10) has been described as an antiangiogenic chemokine and displays a potent antitumor activity in vivo. In the present study, we try to investigate whether the combination therapy of hyperthermia, a physical antiangiogenic modality, with CXCL10 would completely eradicate the established solid tumors. METHODS: Immunocompetent BALB/c mice bearing Meth A fibrosarcoma were established. Mice were treated with either CXCL10 at 25 microg/kg once a day for 20 days, hyperthermia was given twice (at 42 degrees C for 1 h, on day 6 and 12 after the initiation of CXCL10), or together. Tumor volume and survival time were observed. The microvessel density was determined by CD31 immunofluorescence. Histologic analysis and assessment of apoptotic cells were also conducted in tumor tissues. RESULTS: The results showed that CXCL10 and hyperthermia inhibited the growth of Meth A fibrosarcoma and interestingly, the combination therapy enhanced the antiangiogenic effects and completely eradicated the established solid tumors. Histological examination revealed that CXCL10 + hyperthermia led to increased induction of apoptosis, tumor necrosis, and elevated lymphocyte infiltration compared with the controls. Moreover, the tumor eradicated animals developed a protective T-cell-dependent antitumor memory response against Meth A tumor cells rechallenge. CONCLUSIONS: Our finding is that the combination therapy can achieve a synergistic antitumor efficacy, supporting the idea that the combination of two antiangiogenic agents may lead to improved clinical outcome. These findings could open new perspectives in clinical antitumor therapy.

The effect of electromagnetic field and local inductive hyperthermia on nonlinear dynamics of the growth of transplanted animal tumors.

AIM: To examine the effects of electromagnetic field with amplified magnetic component and local inductive hyperthermia (IH) on nonlinear dynamics of the growth of animal tumors. MATERIALS AND METHODS: Guerin carcinoma, Lewis lung carcinoma, sarcoma 45, Walker 256 carcinosarcoma and Pliss lymphosarcoma were studied. The animal tumors were exposed inside of loop aerial, 3 cm in diameter locally for 30 min. Parameters of electromagnetic irradiation (EI): frequency 40 MHz, magnetic intensity 72 A/m, electric intensity 200 V/m and the output power 50 W. The temperature measured by immersion of thermocouple inside the center of the tumor didn't exceed 38.5-39.5 degrees C. Nonlinear dynamics of the growth of animal tumors was analyzed by autocatalytic equation. The heterogeneity of ultrasonic image of the tumor was analyzed by Moran spatial autocorrelation. RESULTS: The strongest inhibition effect under the influence of EI was in Pliss lymphosarcoma and sarcoma 45. The growth stimulation of animal tumors after EI was recorded in Walker 256 carcinosarcoma. The use of mild IH increased the blood flow in the tumor of Guerin carcinoma. CONCLUSION: These results are important for clinical application because they testify the necessity of optimization of schemes for local EI during anticancer neoadjuvant therapy with the use of drugs or magnetic nanoparticles. The use of mild IH as a basis for the monotherapy of malignant tumors is not expedient.

Fungal polysaccharopeptide inhibits tumor angiogenesis and tumor growth in mice.

Angiogenesis is crucial to tumor growth and metastasis, and interruption of this process is a prime avenue for therapeutic intervention of tumor proliferation. The present study has made use of the S180 tumor-bearing mouse model to investigate the polysaccharopeptide, PSP, isolated from the edible mushroom Coriolus versicolor, a herbal medicine known for its anti-angiogenesis properties. Quantitative analysis of microcorrosion casting of the tumor tissue showed more angiogenic features such as dense sinusoids and hot spots, in control (untreated) than in PSP-treated animals. Immunostaining of tumor tissues with antibody against the endothelial cell marker (Factor VIII) demonstrated a positive correlation in that both the vascular density and tumor weight were lower in mice treated with PSP. Morphometric analysis of corrosion casts revealed that, even though the total amount of new vessel production was reduced, the basic tumor type-specific vascular architecture was retained. However, the expression of vascular endothelial cell growth factor (VEGF) in these tumors was suppressed. In conclusion, anti-angiogenesis should be one of the pathways through which PSP mediated its anti-tumor activity.

[Angioroentgenologic response of rat M-1 sarcoma to low-energy infrared laser irradiation at varying frequency]. / Angiorentgenograficheskie izmeneniia v opukholi M-1 krys v otvet na deistvie nizkointensivnogo infrakrasnogo lazernogo izlucheniia razlichnoi chastoty.

After rats with sarcoma M-1 inoculated in the femur area were exposed to low-energy (0.54 mT1) infra-red laser irradiation, 100Hz, for 10 min, the number of contrast-enhanced vessels of tumor fell sharply as compared with controls. That effect lasted for almost 24 hrs. At 1kHz, the total-sum of diameters of such vessels still increased 24 hrs after the exposure. When at 10kHz, that index decreased, and by day 3 vascular pattern and diameter came back to normal in all experiments.

The effect of acetylshikonin isolated from Lithospermum canescens roots on tumor-induced cutaneous angiogenesis.

This study has demonstrated that acetylshikonin (ACS), the isolated ingredient from Lithospermum canescens Lehm. roots, in a daily dose of 200 microg for 3 days, inhibited cutaneous angiogenesis induced by L-1 sarcoma cells in Balb/c mice.

Preclinical evaluations of therapies combining the vascular targeting agent combretastatin A-4 disodium phosphate and conventional anticancer therapies in the treatment of Kaposi's sarcoma.

The antitumor efficacy of the vascular targeting agent combretastatin A-4 disodium phosphate (CA4DP) was evaluated in a xenograft model of Kaposi's sarcoma (KS) grown in athymic mice. Response to CA4DP alone or in combination with localized radiation treatment or systemic chemotherapy (cisplatin or vinblastine) was assessed using a clonogenic cell survival or tumor growth delay assay. Administering increasing doses of CA4DP to tumor-bearing mice resulted in a dose-dependent increase in tumor cell kill. CA4DP also enhanced the antitumor effects of radiation and chemotherapy approximately 10-100-fold. Although single doses of CA4DP as large as 300 mg/kg failed to alter tumor growth, the same total dose, administered as 3 fractions in 5 or 9 days, resulted in significant growth delay. Such repeated CA4DP exposures also significantly increased the response of KS xenografts to cisplatin. These findings suggest that CA4DP ought to be considered as a candidate agent for therapeutic evaluation in AIDS-KS patients.

Enhancement of radiation therapy by the novel vascular targeting agent ZD6126.

PURPOSE: The aim of this study was to evaluate the antitumor efficacy of the novel vascular targeting agent ZD6126 (N-acetylcochinol-O-phosphate) in the rodent KHT sarcoma model, either alone or in combination with single- or fractionated-dose radiation therapy. METHODS: C3H/HeJ mice bearing i.m. KHT tumors were injected i.p. with ZD6126 doses ranging from 10 to 150 mg/kg. Tumors were irradiated locally in unanesthetized mice using a linear accelerator. Tumor response to ZD6126 administered alone or in combination with radiation was assessed by clonogenic cell survival assay or tumor growth delay. RESULTS: Treatment with ZD6126 led to a rapid tumor vascular shutdown as determined by Hoechst 33342 diffusion. Histologic evaluation showed morphologic damage of tumor cells within a few hours after drug exposure, followed by extensive central tumor necrosis and neoplastic cell death as a result of prolonged ischemia. When combined with radiation, a 150 mg/kg dose of ZD6126 reduced tumor cell survival 10-500-fold compared with radiation alone. These enhancements in tumor cell killing could be achieved for ZD6126 given both before and after radiation exposure. Further, the shape of the cell survival curve observed after the combination therapy suggested that including ZD6126 in the treatment had a major effect on the radiation-resistant hypoxic cell subpopulation associated with this tumor. Finally, when given on a once-weekly basis in conjunction with fractionated radiotherapy, ZD6126 treatment was found to significantly increase the tumor response to daily 2.5 Gy fractions. CONCLUSION: The present results demonstrated that in the KHT sarcoma, ZD6126 caused rapid tumor vascular shutdown, induction of central tumor necrosis, tumor cell death secondary to ischemia, and enhancement of the antitumor effects of radiation therapy.

The effect of evening primrose oil on the radiation response and blood flow of mouse normal and tumour tissue.

PURPOSE: To investigate the effect of the oral administration of evening primrose oil on the radiation response and the blood flow of normal tissue and a tumour in BALB/c mice. METHODS AND MATERIALS: Aliquots of evening primrose oil were fed to BALB/c mice daily and the radiation response of the skin was assessed by the determination of ED50 values for the incidence of moist desquamation, using probit analysis. Tumour radiosensitivity was investigated by determining the growth delay caused by irradiation of a transplantable rhabdomyosarcoma. The 86RbCl uptake technique was used to determine the blood flow in normal foot and tumour tissue. The fatty-acid content of red blood cells, plasma and tumour tissue was measured using gas chromatography. RESULTS: Daily evening primrose oil dietary supplementation reduced the sensitivity of skin to radiation-induced moist desquamation and prevented the radiation-associated increase in blood flow that was observed in this tissue. No modification of tumour blood flow or of tumour sensitivity to radiation resulted from evening primrose oil supplementation of mice. Evening primrose oil supplementation resulted in changes in plasma levels of linoleic acid (LA), gamma-linolenic acid (GLA), dihomo-gamma-linolenic acid (DGLA) and arachidonic acid (AA). These changes were contingent on whether the mice had been irradiated or not. In red blood cells evening primrose oil supplementation increased the GLA level of unirradiated mice and the LA level at 20 days after irradiation. There were no changes in tumour fatty-acid levels as a result of evening primrose oil treatment. CONCLUSIONS: Daily evening primrose oil supplementation reduced the sensitivity of skin to radiation-induced moist desquamation but did not alter tumour sensitivity to radiation.

Temperature-dependent changes in physiologic parameters of spontaneous canine soft tissue sarcomas after combined radiotherapy and hyperthermia treatment.

PURPOSE: The objectives of this study were to evaluate effects of hyperthermia on tumor oxygenation, extracellular pH (pHe), and blood flow in 13 dogs with spontaneous soft tissue sarcomas prior to and after local hyperthermia. METHODS AND MATERIALS: Tumor pO2 was measured using an Eppendorf polarographic device, pHe using interstitial electrodes, and blood flow using contrast-enhanced magnetic resonance imaging (MRI). RESULTS: There was an overall improvement in tumor oxygenation observed as an increase in median pO2 and decrease in hypoxic fraction (% of pO2 measurements <5 mm Hg) at 24-h post hyperthermia. These changes were most pronounced when the median temperature (T50) during hyperthermia treatment was less than 44 degrees C. Tumors with T50 > 44 degrees C were characterized by a decrease in median PO2 and an increase in hypoxic fraction. Similar thermal dose-related changes were observed in tumor perfusion. Perfusion was significantly higher after hyperthermia. Increases in perfusion were most evident in tumors with T50 < 44 degrees C. With T50 > 44 degrees C, there was no change in perfusion after hyperthermia. On average, pHe values declined in all animals after hyperthermia, with the greatest reduction seen for larger T50 values. CONCLUSION: This study suggests that hyperthermia has biphasic effects on tumor physiologic parameters. Lower temperatures tend to favor improved perfusion and oxygenation, whereas higher temperatures are more likely to cause vascular damage, thus leading to greater hypoxia. While it has long been recognized that such effects occur in rodent tumors, this is the first report to tie such changes to temperatures achieved during hyperthermia in the clinical setting. Furthermore, it suggests that the thermal threshold for vascular damage is higher in spontaneous tumors than in more rapidly growing rodent tumors.

Radiosensitization of two murine tumours with mild temperature hyperthermia and carbogen breathing.

PURPOSE: To test the individual and combined effects of local mild temperature hyperthermia (MTH) at 41.5 degrees C for 60 min and carbogen breathing on tumour radiosensitivity. MATERIALS AND METHODS: The FSall fibrosarcoma of C3H mice and the SCK mammary carcinoma of A/J mice were used. The effect of various treatments on tumour cell survival was determined using the in vivo/in vitro tumour excision assay, and the radiobiological hypoxic fraction was calculated. The tumour radiation sensitivity was tested with the tumour growth delay assay. RESULTS: The radiobiological hypoxic cell fraction (HF) in control FSall and SCK tumours was 0.45 and 0.78, respectively, and these values decreased to 0.12 in FSall tumours and 0.22 in SCK tumours when determined immediately after the tumours were treated with MTH. The HF was 0.32 in FSall tumours and 0.33 in SCK tumours after carbogen breathing was applied. When tumours were treated with MTH and the animals breathed carbogen the HF decreased to 0.03-0.04 in both FSall and SCK tumours. MTH treatment alone had only a small effect on tumour growth, but MTH treatment applied before irradiating the tumours significantly increased the radiation-induced tumour growth delay. Carbogen breathing modestly improved the radiation-induced tumour growth delay while the combination of MTH treatment and carbogen breathing caused the largest increase in radiation-induced tumour growth delay. CONCLUSIONS: MTH treatment alone and combined with carbogen breathing substantially increased the tumour radiation response probably through an increase in the tumour oxygenation status.

Localized hypothermia: impact on oxygenation, microregional perfusion, metabolic and bioenergetic status of subcutaneous rat tumours.

The effect of localized hypothermia on microcirculatory and metabolic parameters in s.c. DS sarcomas on the hind foot dorsum of Sprague-Dawley rats was investigated. Tumours were cooled by superfusion of the tumour surface with cooled saline solution to 25 degrees C or 15 degrees C. Control tumours remained at 35 degrees C. These temperatures were maintained for 30 min. In tumour oxygenation measurements, hypothermia at 25 degrees C and 15 degrees C caused progressive decreases in the size of the fraction of pO2 measurements between 0 and 2.5 mmHg together with a reduction in pO2 variability. No significant changes in median or mean pO2 or in the fraction of pO2 measurements between 0 and 5 mmHg, and 0 and 10 mmHg were observed. Using laser Doppler flowmetry, red blood cell flux was found to decrease significantly upon 25 degrees C or 15 degrees C hypothermia treatment to 67% and 37% of starting values respectively, whereas no significant changes were seen in control tumours over the whole observation period. Viscosity was measured in blood and plasma samples over a range of temperatures and was found to increase with decreasing temperature. Assessment of tumour glucose levels showed an increased concentration of glucose following 15 degrees C hypothermia, an observation consistent with a 'slowing down' of glycolysis. No changes in lactate or adenylate phosphate levels were observed. As a way of improving tumour oxygenation, localized hypothermia may therefore be a useful means of radiosensitization.

Tumor oxygenation after mild-temperature hyperthermia in combination with carbogen breathing: dependence on heat dose and tumor type.

We investigated the effect of hyperthermia at 40.5-42.5 degrees C as well as the combination of hyperthermia and carbogen breathing on oxygenation in the SCK murine mammary carcinoma. In addition, the important question of how long the effect of heating on tumor oxygenation lasts was addressed in both SCK and FSaII (murine fibrosarcoma) tumors. The median pO2 in control SCK tumors was 4.4 +/- 0.2 mm Hg, and it increased to a maximum of 12.6 +/- 1.2 mm Hg when the tumors were heated at 41.5 degrees C for 1 h. Carbogen breathing increased the median pO2 of SCK tumors to 17.1 +/- 1.4 mm Hg, but after heating at 41.5 degrees C, it elevated the pO2 in SCK tumors markedly to 31.3 +/- 4.2 mm Hg. The kinetics of the return to baseline oxygenation after hyperthermia was found to vary with the type of tumor and the heat dose. The pO2 of FSaII tumors remained significantly higher than that of control tumors 24 h after heating at 41.5 degrees C for 60 min. The pO2 of SCK tumors remained elevated for up to 3 h after heating at 41.5 degrees C for 30 min, but if the tumors were heated for 60 min at this temperature, the median oxygen tension declined to the control level within 1 h after heating. It was concluded that mild-temperature hyperthermia, i.e. 41.5 degrees C, alone and in combination with carbogen breathing dramatically improves the oxygenation of these murine tumors and that the tumor type influences the duration of changes in oxygenation induced by mild-temperature hyperthermia.

Augmentation in chemosensitivity of intratumor quiescent cells by combined treatment with nicotinamide and mild hyperthermia.

C3H/He and Balb/c mice bearing SCC VII and EMT6/KU tumors, respectively, received continuous administration of 5-bromo-2'-deoxyuridine (BrdU) for 5 days using implanted mini-osmotic pumps to label all proliferating (P) cells. Nicotinamide was administered intraperitoneally before cisplatin injection and/or tumors were locally heated at 40 degrees C for 60 min immediately after cisplatin injection. The tumors were then excised, minced and trypsinized. The tumor cell suspensions were incubated with cytochalasin-B (a cytokinesis-blocker), and the micronucleus (MN) frequency in cells without BrdU labeling (quiescent (Q) cells) was determined using immunofluorescence staining for BrdU. The MN frequency in total (P+Q) tumor cells was determined from tumors that had not been pretreated with BrdU labeling. The sensitivity to cisplatin was evaluated in terms of the frequency of induced micronuclei in binuclear tumor cells (MN frequency). In both tumor systems, the MN frequency in Q cells was lower than that in the total cell population. Nicotinamide treatment elevated the MN frequency in total SCC VII cells. Mild heating raised the MN frequency more markedly in Q cells than in total cells. The combination of nicotinamide and mild heat treatment increased the MN frequency more markedly than either treatment alone. In total SCC VII cells, nicotinamide increased 195mPt-cisplatin uptake. Mild heating elevated 195mPt-cisplatin uptake in total EMT6/KU cells. Cisplatin-sensitivity of Q cells was lower than that of total cells in both tumor systems. Nicotinamide sensitized tumor cells including a large acutely hypoxic fraction, such as those of SCC VII tumors, through inhibition of the fluctuations in tumor blood flow. Tumor cells including a large chronically hypoxic fraction such as Q cells were thought to be sensitized by mild heating through an increase in tumor blood flow.

Efficacy and mechanism of aluminium phthalocyanine and its sulphonated derivatives mediated photodynamic therapy on murine tumours.

The efficacy of photodynamic therapy (PDT) mediated by aluminium phthalocyanine (AlPc) and its mono- and disulphonated derivatives (AlPcS1 and AlPcS2, respectively) on murine EMT-6 tumour were compared in vivo. AlPc (0.25 mumol/kg) PDT resulted in no tumour recurrence in all treated mice. In contrast, PDT with AlPcS1 (2 mumol/kg) and AlPcS2 (1 mumol/kg) only produced tumour cure in 75% and 86% of mice, respectively. Immediately after AlPc-PDT, tumour cells were found to be viable as determined by in vitro clonogenicity, but progressive cell death occurred thereafter. In contrast, AlPcS1 and AlPcS2 PDT produced substantial cell death (approximately 35% and 70%, respectively, of entire tumour) immediately after phototherapy, and yet further loss of tumour cell viability continued after PDT. In all cases, few vascular effects were observed at 0 h post-PDT, as indicated by the retention of 99mTc-MIBI in the tumour. However, the reduction of blood flow in tumours progressed with time, such that blood flow in tumours fell to approximately 25% of the control level by 24 h after both AlPc and AlPcS1 PDT. With AlPcS2, there was only an approximate 50% fall in tumour blood flow by 24 h. These results demonstrate a greater PDT efficiency with AlPc on tumour destruction, which is an indirect mechanism involving damage of tumour vasculature, whereas AlPcS2 has a greater effect on direct tumour cytotoxicity and AlPcS1 exerts both direct and indirect modes of action against tumours.

Effect of nitro-L-arginine on blood flow, oxygenation and the activity of hypoxic cell cytotoxins in murine tumours.

This study was an investigation into the ability of nitro-L-arginine to change blood flow, oxygenation status and the activity of hypoxic cell cytotoxic agents in two different transplanted murine tumours. The tumour models were the C3H mammary carcinoma grown in the feet of female CDF1 mice and the SaF grown on the backs of CBA mice. Treatments were carried out in restrained non-anaesthetised animals when tumours were about 100 to 200 mm3 in size. Blood flow was monitored using laser Doppler flowmetry; oxygen partial pressure (pO2) distributions were obtained with an Eppendorf oxygen electrode; and response to treatment with hyperthermia (43.5 degrees C; 30 min) and RB6145 (250 mg kg-1;i.p.) assessed using a tumour growth delay assay. Nitro-L-arginine (10 mg kg-1; i.v.) significantly reduced blood flow by around 40-60% within 15 min after injection in C3H tumour and by 30 min in the SaF. However, nitro-L-arginine had absolutely no effect on tumour pO2 measured at the time of maximal blood flow reduction in both tumour types. It also failed to enhance the response of the C3H tumour to heat, but did produce a small yet significant increase in the response of the SaF tumour to RB6145.

Changes in microregional perfusion, oxygenation, ATP and lactate distribution in subcutaneous rat tumours upon water-filtered IR-A hyperthermia.

The effect of hyperthermia on microcirculatory and metabolic parameters in s.c. DS-sarcomas of different sizes on the hind foot dorsum of SD-rats was investigated. Hyperthermia was carried out using a novel water-filtered, infrared-A radiation technique. Heating was performed at a rate of 0.5 degrees C/min until 44 degrees C was achieved in the tumour centre, which was maintained for 60 min. Using a multichannel laser Doppler flowmeter, red blood cell flux could be assessed continuously and at several sites within the tumour tissue simultaneously. Substantial inter-site variations in laser Doppler flux (LDF) were observed during hyperthermia which were independent of tumour size, site of measurement, and temperature at the site of measurement, indicating that single site measurements of tumour LDF are poor predictors of the mean response of a tumour to hyperthermia. When mean LDF was considered, decreases in red blood cell fluxes occurred that were more pronounced the greater the tumour volume. In no case was vascular stasis observed. Hyperthermia did not affect tumour oxygenation substantially. Microregional and global assessment of lactate and ATP concentrations demonstrated increased lactate and decreased ATP levels following hyperthermia. Tumour glucose levels were increased following hyperthermia, possibly due to an enlarged distribution space resulting from development of interstitial oedema. Changes in lactate and ATP levels and the lack of changes in tumour oxygenation suggest a modification of energy metabolism following hyperthermia in the form of increased ATP hydrolysis, intensified glycolysis and impaired oxidative phosphorylation.

Magnetic resonance spectroscopic studies on 'real-time' changes in RIF-1 tumour metabolism and blood flow during and after photodynamic therapy.

Magnetic resonance spectroscopy (MRS) in situ was used to study changes in 31P metabolism occurring during and after treatment of murine RIF-1 tumours with photodynamic therapy (PDT). Tumours were irradiated using a fibreoptic light delivery system while the mice were in position within the magnet. Changes in 31P-MRS were observable during and immediately after treatments of several minutes' duration. Both the extent and duration of the increase in the Pi/total ratio were light dose dependent. The effect on the metabolism was also affected by the time interval (TL) between administering the photosensitiser disulphonated phthalocyanine, (A1S2Pc) and the light. With a dose of 50 J the increase in Pi/total was much faster when TL was 1 h than when TL was 24 h. This difference in rate probably reflects differences in the distribution of A1S2Pc within the tumour. Significant decreases in pH were only seen after a light dose of 50 J when TL was 1 h. Blood flow measurements using deuterium uptake were also carried out using MRS. These experiments showed that for a dose of 50 J the level of blood flow was reduced by approximately 90% of the control value within 10 min from the end of the 8 min light treatment. This occurred irrespective of the value of TL. The data indicate that it is possible to observe very early changes in 31P metabolism that can be attributed to direct cellular damage as opposed to the later changes indicative of overall tumour hypoxia caused by vascular damage.