Imaging hypoxia after oxygenation-modification: comparing [18F]FMISO autoradiography with pimonidazole immunohistochemistry in human xenograft tumors.

PURPOSE: Hypoxia is one of the reasons for radiation therapy resistance. Positron emission tomography using (18)F-labeled misonidazole ([(18)F]FMISO) is a non-invasive method of imaging tumor hypoxia. Aim of this study was to validate [(18)F]FMISO against the clinically most widely used hypoxic cell marker pimonidazole under different oxygenation conditions. MATERIALS AND METHODS: One human head and neck squamous cell carcinoma (SCCNij3) and two human glioblastoma (E102 and E106) xenograft tumor lines were studied after injection of [(18)F]FMISO and pimonidazole. Control mice were compared with a second group breathing carbogen to reduce tumor hypoxia and with a third group with clamped tumors to increase hypoxia. Tumor sections were analyzed on a phosphor imaging system and consecutively stained immunohistochemically (IHC) for visualization of pimonidazole. Pixel-by-pixel analysis was performed and the hypoxic fraction, obtained after segmentation of the pimonidazole signal, was related to the mean optical density of [(18)F]FMISO and pimonidazole. RESULTS: A moderate pixel-by-pixel correlation between [(18)F]FMISO autoradiography and pimonidazole IHC was found for the control tumors, after carbogen breathing and after clamping for SCCNij3. For E102 and E106, mean signal intensities for pimonidazole significantly decreased after carbogen breathing and increased after clamping, mean [(18)F]FMISO signal intensities increased significantly after clamping and a significant correlation between the hypoxic fractions and the mean [(18)F]FMISO signal intensities was found. CONCLUSIONS: [(18)F]FMISO autoradiography and pimonidazole immunohistochemistry can both be used to visualize treatment induced changes in tumor hypoxia. However, the response to these modifications differs widely between xenograft tumor lines.     

Effects of nicotinamide and carbogen in different murine colon carcinomas: immunohistochemical analysis of vascular architecture and microenvironmental parameters

PURPOSE: To investigate oxygenation, perfusion, and cell proliferation in two murine colon carcinoma lines with known differences in chemotherapy sensitivity and analyze the effect of nicotinamide and carbogen on these tumor characteristics. METHODS AND MATERIALS: Mice with s.c. transplanted C38 and C26a murine colon tumors were treated with nicotinamide and carbogen and compared with control tumors. Two markers of hypoxia, CCI-103F and pimonidazole, were injected before and after treatment with nicotinamide/carbogen, respectively, allowing each tumor to serve as its own control. Hoechst33342 was used as a perfusion marker and bromodeoxyuridine (BrdUrd) as a proliferation marker. Frozen tumors were cut for multistep immunostaining and computer-controlled microscope scanning for hypoxic fractions (HF), perfused fractions (PF), vascular density, and BrdUrd-labeling index (LI). RESULTS: Microscopic observation of C38 and C26a tumors showed extensive differences in vascular architecture, distribution patterns of hypoxia, and BrdUrd-labeling. Quantitative analysis of C38 and C26a tumors showed a decrease in HF in response to all treatment modalities. For C38 tumors, the average decrease in HF in response to carbogen containing treatments was larger than to nicotinamide alone. In C26a tumors, no difference in average decrease in HF was observed between the treatments. The PF of C38 and C26a did not change in response to treatment. The LI of C38 and C26a decreased upon all treatments, which was statistically significant in the combination treatment of C38. CONCLUSIONS: The mechanism that can simultaneously explain all the observed changes in response to treatment may be the conversion of metabolism from less respiration toward more glycolysis due to increased glucose levels (Crabtree effect), although other mechanisms of actions cannot be excluded.     

Changes in tumor hypoxia measured with a double hypoxic marker technique

Purpose: Development of a double hypoxic cell marker assay, using the bioreductive nitroimidazole derivatives CCI-103F and pimonidazole, to study changes in tumor hypoxia after treatments that modify tumor oxygenation.

Methods and Materials: Both hypoxic markers were visualized by immunohistochemical techniques to detect changes in hypoxic fraction induced by carbogen breathing (95% O₂ and 5% CO₂) or hydralazine injection. The protocol was tested in a human laryngeal squamous cell carcinoma xenograft line. Quantitative measurements were derived from consecutive tissue sections that were analyzed by a semiautomatic image analysis system. Qualitative analysis was obtained by double staining of the two hypoxic markers on the same tissue section.

Results: A significant correlation between the hypoxic fractions for the two markers, CCI-103F and pimonidazole, was found in air breathing animals. After carbogen breathing, the hypoxic fraction decreased significantly from 0.07 to 0.03, and after hydralazine treatment, the hypoxic fraction increased significantly. Reduction of hypoxia after carbogen breathing was most pronounced close to well-perfused tumor regions.

Conclusions: With this method, employing two consecutively injected bioreductive markers, changes in tumor hypoxia can be studied. A significant reduction in hypoxia after carbogen breathing and a significant increase in hypoxia after hydralazine administration was demonstrated.     

Tumor-line specific pO(2) fluctuations in human melanoma xenografts

PURPOSE: A large number of studies have demonstrated that tumors are heterogeneous in oxygen tension (pO(2)) and may develop regions with chronically or acutely hypoxic cells during growth. In the present study, it was investigated whether experimental tumors of different lines may show characteristic pO(2) fluctuation patterns and hence may differ with respect to the kinetics of acute hypoxia. METHODS AND MATERIALS: A total of 70 xenografted tumors of two human melanoma lines (A-07 and R-18) were included in the study. Tissue pO(2) was measured simultaneously in two positions in each tumor for periods of at least 60 min using a two-channel fiberoptic oxygen-sensing device (OxyLite 2000, Oxford Optronix, Oxford, UK). RESULTS: The mean pO(2) was calculated for each pO(2) trace, and this parameter was significantly greater in A-07 than in R-18 tumors (p <0.000001). Fluctuations in pO(2) around 3, 5, or 10 mm Hg were seen in a large fraction of the tumors of both lines. The pO(2) fluctuation frequency differed among individual traces from 0 to 20/h (A-07) and from 0 to 12/h (R-18) and was significantly greater in A-07 than in R-18 tumors (p = 0.0026). The absolute amplitude of the pO(2) fluctuations ranged from 1 to 16 mm Hg (A-07) and 1 to 33 mm Hg (R-18) and did not differ between the tumor lines. The relative amplitude was significantly higher in R-18 than in A-07 tumors (p <0.000001). The pO(2) values recorded simultaneously in the same tumor were in general not temporally coordinated. CONCLUSION: Experimental tumors of different lines may show individual and characteristic pO(2) fluctuation patterns. The pO(2) fluctuations may result in regions with acutely hypoxic cells. The kinetics of the acute hypoxia may differ among tumors of different lines, individual tumors of the same line, and different regions within the same tumor.     

A pilot study comparing intratumoral oxygenation using the comet assay following 2.5% and 5% carbogen and 100% oxygen

PURPOSE: Tumor hypoxia has been purported to be an important biologic factor in the failure of radical radiotherapy to achieve local control in many tumor types. This study was designed to evaluate the effect of breathing high oxygen content gas mixtures (oxygen with 0%, 2.5%, or 5% carbon dioxide) on tumor oxygenation measured using the Eppendorf polarographic oxygen electrode and the comet assay in accessible, hypoxic human tumors. METHODS AND MATERIALS: Using Eppendorf pO2 histography to identify hypoxic tumors (median pO2 < or = 10 mmHg), eligible patients were systematically allocated either 100% oxygen (O2) or oxygen with 2.5% or 5% carbon dioxide (CO2). Tumors were treated with 6-10 Gy during which two fine needle aspirates (FNA) were obtained from different regions of the lesion, one at midway and the other at completion of the radiation exposure. Gas breathing was initiated 4 min before radiation was commenced. A 10-min interval was specified between the first and second halves of the radiation exposure to allow near maximal DNA repair prior to the second half of the radiation treatment. FNAs were performed within 2 min of cessation of radiation and the cells immediately suspended in buffered saline at 4 degrees C for analyses of hypoxic fraction using the comet assay. RESULTS: Fifteen evaluations were performed in 13 patients with hypoxic tumors (median O2 tension 2.75 mmHg) treated with a median dose of 8 Gy. The median hypoxic fraction determined using the comet assay fell from 0.36 to 0.13 (p = 0.001, Wilcoxon signed rank test) due to the addition of high oxygen content gases. CONCLUSIONS: In tumors defined as hypoxic using Eppendorf pO2 histography, a statistically significant reduction in the hypoxic fraction with the comet assay was found following administration of high oxygen content gases. These preliminary findings reveal a trend suggesting that 5% carbogen may reduce the hypoxic fraction by a greater margin than either 100% oxygen or 2.5% carbogen.     

Tumor oxygenation after hyperthermia in the rat 13762 mammary carcinoma and the DU-145 human prostate carcinoma

Tumor oxygenation was measured in the rat 13762 mammary carcinoma over a time course from 30 min to 3 days after hyperthermia treatment of 43 degrees C, 30 min or 40 degrees C, 80 min, while the animals breathed air, carbogen or after administration of a perflubron emulsion with air or carbogen breathing. Shortly (30 min and 3 h) after treatment with 43 degrees C, 30 min, the 13762 tumors were more hypoxic, as determined by the percent of pO(2) readings <5 mmHg and median pO(2), than prior to treatment and by 24 h had returned to initial oxygenation. Administration of the perflubron emulsion and carbogen breathing abrogated the increase in hypoxia and improved tumor oxygenation. Athymic mice bearing the DU-145 human prostate carcinoma were treated with hyperthermia regimens 40 degrees C, 41 degrees C, 42 degrees C or 43 degrees C for 60 min and tumor oxygenation was then measured over a time course while the animals breathed air or carbogen. Shortly (30 min) after hyperthermia, the DU-145 tumors were more hypoxic than initially when the animals breathed air. Three days later, the DU-145 tumors treated with 41 degrees C: 42 degrees C or 43 degrees C remained hypoxic but the tumors treated with 40 degrees C were better oxygenated than initially. When the animals bearing the DU-145 tumor breathed carbogen during the tumor oxygenation measurements only tumors treated with 43 degrees C were more hypoxic shortly after hyperthermia treatment. Three days after hyperthermia, the DU-145 tumors treated with 40 degrees C and 43 degrees C were better oxygenated than initially while those treated with 41 degrees C and 42 degrees C were less oxygenated when the animals breathed carbogen during the oxygen measurements. Thus, the effect of hyperthermia on tumor physiology can persist for days post treatment and vary with the temperature of the treatment.     

The influence of tumor oxygenation on hypoxia imaging in murine squamous cell carcinoma using [64Cu]Cu-ATSM or [18F]Fluoromisonidazole positron emission tomography

[64Cu]Cu(II)-ATSM (64Cu-ATSM) and [18F]-Fluoromisonidazole (18F-FMiso) tumor binding as assessed by positron emisson topography (PET) was used to determine the responsiveness of each probe to modulation in tumor oxygenation levels in the SCCVII tumor model. Animals bearing the SCCVII tumor were injected with 64Cu-ATSM or 18F-FMiso followed by dynamic small animal PET imaging. Animals were imaged with both agents using different inspired oxygen mixtures (air, 10% oxygen, carbogen) which modulated tumor hypoxia as independently assessed by the hypoxia marker pimonidazole. The extent of hypoxia in the SCCVII tumor as monitored by the pimonidazole hypoxia marker was found to be in the following order: 10% oxygen>air>carbogen. Tumor uptake of 64Cu-ATSM could not be changed if the tumor was oxygenated using carbogen inhalation 90 min post-injection suggesting irreversible cellular uptake of the 64Cu-ATSM complex. A small but significant paradoxical increase in 64Cu-ATSM tumor uptake was observed for animals breathing air or carbogen compared to 10% oxygen. There was a positive trend toward 18F-FMiso tumor uptake as a function of changing hypoxia levels in agreement with the pimonidazole data. 64Cu-ATSM tumor uptake was unable to predictably detect changes in varying amounts of hypoxia when oxygenation levels in SCCVII tumors were modulated. 18F-FMiso tumor uptake was more responsive to changing levels of hypoxia. While the mechanism of nitroimidazole binding to hypoxic cells has been extensively studied, the avid binding of Cu-ATSM to tumors may involve other mechanisms independent of hypoxia that warrant further study.     

Validation of the fluorinated 2-nitroimidazole SR-4554 as a noninvasive hypoxia marker detected by magnetic resonance spectroscopy.

PURPOSE: Tumor hypoxia is associated with poor prognosis and a more malignant tumor phenotype. SR-4554, a fluorinated 2-nitroimidazole, is selectively bioreduced and bound in hypoxic cells. We present validation studies of SR-4554 as a noninvasive hypoxia marker detected by fluorine-19 magnetic resonance spectroscopy ((19)F MRS) in the P22 carcinosarcoma, a tumor with clinically relevant hypoxia levels. EXPERIMENTAL DESIGN: Tumor-bearing female severe combined immunodeficient mice received SR-4554 at 180 mg/kg. Pharmacokinetic studies of parent SR-4554 in plasma and tumors were performed using high-performance liquid chromatography-UV. Total SR-4554 (parent SR-4554 and bioreduction products) was monitored in tumor by (19)F MRS using a 4.7 T spectrometer, with continuous acquisition for up to 5 h. A parameter of total SR-4554 retention, the 3-h (19)F retention index ((19)FRI) was determined. Tumor pO(2), assessed polarographically, was decreased (5 mg/kg hydralazine or 100 mg/kg combretastatin A-4 phosphate) or increased [1 l/min carbogen (5% CO(2), 95% O(2)) plus 500 mg/kg nicotinamide], and the corresponding (19)FRI was measured. RESULTS: Comparative HPLC-UV- and MRS-derived assessments of parent and total SR-4554, respectively, indicated that concentrations of total SR-4554 consistently exceeded parent SR-4554, the differential increasing with time. This indicates formation and retention of SR-4554 bioreduction products in tumor, confirming the presence of hypoxia. The (19)FRI was higher in hydralazine- and combretastatin-treated animals compared with unmodulated animals (P = 0.004 and 0.15, respectively) and animals receiving carbogen and nicotinamide (P = 0.0001 and 0.005, respectively). Significant correlations were demonstrated between mean (19)FRI and polarographic pO(2) parameters (P < 0.002). CONCLUSIONS: Retention of hypoxia-related SR-4554 bioreduction products can be detected in the clinically relevant P22 tumor by (19)F MRS, and the (19)FRI correlates with polarographically measured pO(2). These findings support the use of SR 4554 as a noninvasive hypoxia marker.     

Increase in tumor pO2 by perfluorochemicals and carbogen

The effects of perfluorochemicals (Fluosol-DA) in combination with carbogen (95% O2 and 5% CO2) breathing on the tumor pO2 was investigated. The pO2 in RIF-1 tumors grown in the leg of C3H mice was determined by polarographic method using oxygen microelectrodes with diameters of 50-60 micron. The average and median pO2 in the control RIF-1 tumors was about 13 mm Hg and 6 mm Hg, respectively. Carbogen breathing alone could cause a significant increase in pO2 in some tumors and Fluosol-DA injection (i.v.) alone caused a slight change in tumor pO2. When the animals were treated with both Fluosol-DA injection and carbogen breathing, the pO2 markedly increased in most of the tumors resulting in an average and median tumor pO2 of 80 mm Hg and 60 mm Hg, respectively. Such an increase in tumor pO2 may account for the previous observations by us and others that the response of experimental tumors to radiation could be markedly increased by treating the tumor-bearing animals with carbogen and Fluosol-DA.     

Decreased tumor oxygenation after cyclophosphamide, reoxygenation and therapeutic enhancement with a perflubron emulsion carbogen breathing

Oxygen profiles of the rat mammary 13672 carcinoma were determined using a pO2 histograph prior to treatment and 24 h and 48 h after i.p. administration of a single dose of cyclophosphamide (300 mg/kg). The tumors were severely hypoxic at 24 h post the administration of cyclophosphamide. There was little increase in oxygenation of the tumors at 48 h post therapy compared with 24 h post therapy indicating that reoxygenation after cyclophosphamide was occurring very slowly in this tumor. Carbogen breathing improved the oxygenation of the tumors under each of the conditions studied. Administration of the perflubron emulsion (8 ml/kg) produced little or no change in the oxygenation of the tumors under normal air breathing conditions. However, the addition of carbogen breathing to administration of the perflubron emulsion increased the oxygenation of the tumors to levels equal to or greater than carbogen breathing at the mean/median pO2's. Perhaps most significantly, administration of the perflubron emulsion with carbogen breathing increased the oxygenation of the most hypoxic regions of the tumors but carbogen breathing alone did not. The growth delay of the Lewis lung carcinoma increased with increasing dose.of the perflubron emulsion along with cyclophosphamide (3 x 150 mg/kg) and carbogen breathing (6 h). This combination treatment was most effective when the cyclophosphamide was prepared in the perflubron emulsion. The number of lung metastases decreased in a manner parallel with increased efficacy of the treatment toward the primary tumor.     

Radiosensitization of hypoxic tumor cells by dodecafluoropentane: a gas-phase perfluorochemical emulsion

One method to make hypoxic, radioresistant cells more radiation sensitive has been to increase the oxygen carrying capacity of normal blood using liquid perfluorochemical emulsions combined with breathing high pO2 gases. We investigated the ability of dodecafluoropentane (DDFP) to sensitize the moderately radiation-resistant Morris 7777 hepatoma based on our previous inability to modify the radiation response of this tumor. DDFP is used in very small quantities compared with perfluorchemicals reported previously. Rats under isoflurane anesthesia were administered EF5 3 h before irradiation to monitor the pretreatment level of tissue hypoxia. At -40 min, DDFP was administered i.v. at 3.5 ml/kg over 30 min. At -10 min, the rats were either continued with air (for controls) or switched to carbogen. The tumors were then irradiated and processed for evaluation of radiation response. Tumor-cell survival for DDFP treatment with air-breathing animals was not significantly different from controls treated without DDFP. Carbogen alone provided minimal sensitization. DDFP plus carbogen caused dramatic radiosensitization, and the radiation response of cells from these tumors was the same as a completely aerobic radiation response. DDFP plus carbogen appears to completely reverse the hypoxic cell radioresistance in this tumor model.     

Effect of carbogen on tumor oxygenation: combined fluorine-19 and proton MRI measurements

PURPOSE: Blood oxygen level dependent (BOLD) contrast in magnetic resonance imaging (MRI) has been widely used for noninvasive evaluation of the effects of tumor-oxygenating agents. However, there have been few tests of the validity of this method. The goal of the present work was to use the T(1) of fluorine-19 in perfluorocarbon (PFC) emulsions as a "gold standard" for comparison with BOLD MRI. MATHODS AND MATERIALS: Rats bearing R3230AC tumors implanted in the hind limb were injected with an emulsion of perfluoro-15-crown-5-ether for 2-3 days before experiments, which ensured that the PFC emulsion concentrated in the tumors. We correlated changes in tumor oxygenation caused by carbogen inhalation measured by (1)H BOLD MRI with quantitative (19)F measurements. The (19)F spin-lattice relaxation rate R(1) (= 1/T(1)) was measured to determine initial oxygen tension (pO(2)) in each image pixel containing the PFC, and changes in pO(2) during carbogen (95% O(2), 5% CO(2)) breathing. In a second carbogen breathing period, changes in water signal linewidth were measured using high spectral and spatial resolution imaging. (19)F and (1)H measurements were used to classify pixels as responders to carbogen (pixels where oxygen increased significantly) or nonresponders (no significant change in tumor oxygenation). RESULTS: The (19)F and (1)H measurements agreed in 65% +/- 11% of pixels (n = 14). Agreement was even stronger among pixels where (1)H showed increased oxygenation; (19)F measurements agreed with (1)H measurements in over 79% +/- 11% of these pixels. Similarly, there was strong agreement between the two modalities in pixels where (19)F reported no change in pO(2); (1)H also showed no changes in 76% +/- 18% of these pixels. Quantitative correlation of changes T(2)* (DeltaT(2)*) in (1)H and changes R(1) (DeltaR(1)) in (19)F was weak during carbogen breathing, and averaged over the whole tumor was approximately 0.40 for 14 experiments. However, the spatial patterns of (1)H and (19)F changes were qualitatively very similar. In hypoxic regions that were identified based on long (19)F T(1) (>2.53 s), (19)F and (1)H MRI agreed that carbogen had relatively weak effects. CONCLUSIONS: These results suggest that (1)H BOLD MRI reliably identifies increases in tumor pO(2). In hypoxic regions where increases in pO(2) are most desirable, carbogen was ineffective. The data suggest that (19)F and (1)H MRI can be used individually or in combination to guide the design of improved tumor-oxygenating agents.     

Modification of photodynamic therapy-induced hypoxia by fluosol-DA (20%) and carbogen breathing in mice

The administration of a perfluorochemical emulsion and carbogen (95% O2, 5% CO2) breathing before photodynamic therapy (PDT) was studied to determine how increased levels of tumor oxygenation may affect PDT-induced tumor destruction. C3H/HeJ mice bearing the RIF tumor were given injections of 5 to 10 mg/kg of dihematoporphyrin ethers 24 h prior to treatment. Animals were given injections of 12 ml/kg of Fluosol-DA (20%) followed by carbogen breathing or 12 ml/kg of saline and air breathing (controls) 1 h before tumors were exposed to 135 J/cm2 of 630-nm light treatment. Changes in the hypoxic fraction of tumors, the time course for decreases in tumor cell clonogenicity, and tumor response were measured immediately and at various times after treatment. The administration of Fluosol-DA (20%) and carbogen breathing was found to delay the onset of PDT-induced hypoxia through the first hour posttreatment. Progressive tumor hypoxia was observed after 4 h posttreatment. The time period in which tumors remained well oxygenated coincided with observations of increased tumor cell survival. Decreases in tumor cell clonogenicity were observed only after tumor cells became hypoxic. These findings were consistent with the 24-h delay in complete tumor response in animals given Fluosol-DA (20%) and carbogen breathing before PDT. There were only minor variations in long-term tumor response and cure observed between the two groups tested. A second series of experiments was done to assess any treatment advantage of the adjuvant use of Fluosol-DA (20%) and carbogen breathing with PDT at high tumor photosensitizer levels. At an injected dose of 50 mg/kg of dihematoporphyrin ethers, no such advantage was observed. The administration of Fluosol-DA (20%) and carbogen breathing did not reduce the extent of PDT-induced microvascular damage, maintain high levels of tumor oxygenation through light treatment, or modify the extent of tumor cell kill following treatment.     

Tumor oxygenation and radiosensitization by pentoxifylline and a perflubron emulsion carbogen breathing

Oxygen tension measurements were made in three tumors: (i) the murine FSaII fibrosarcoma, (ii) the rat 9L gliosarcoma and (iii) the rat 13672 mammary adenocarcinoma using a pO2 histograph. Tumor oxygenation measurements were made while the animals breathed air or breathed carbogen (95% oxygen/5% carbon dioxide). Pentoxifylline or a perflubron emulsion was administered to the animals and tumor oxygen measurements were repeated under both breathing conditions. Both pentoxifylline and the perflubron emulsion improved the oxygenation of the FSaII fibrosarcoma under air breathing conditions but did not alter the oxygen profiles of either rat tumor compared with air breathing alone. Carbogen breathing increased the oxygenation of all tumors. Pentoxifylline administration did not change the oxygen profiles of the tumors under carbogen breathing conditions but administration of the perflubron emulsion increased the oxygenation of all three tumors under carbogen breathing conditions compared with carbogen breathing alone. Co-administration of pentoxifylline and the perflubron emulsion enhanced the radiation response of the Lewis lung tumor to daily fractionated radiation under air breathing conditions with a dose modifying factor of 1.65 and under carbogen breathing conditions with a dose modifying factor of 2.25. Over a range of perflubron emulsion doses, pentoxifylline increased the growth delay of the Lewis lung tumor in a constant manner. These results indicate that pentoxifylline and the perflubron emulsion have the largest impact on the oxygenation of more hypoxic tumors and that administration of the perflubron emulsion/carbogen breathing is the most effective means of increasing tumor oxygenation and radiation response.     

Overexpression of dimethylarginine dimethylaminohydrolase enhances tumor hypoxia: an insight into the relationship of hypoxia and angiogenesis in vivo

The oxygenation status of tumors derived from wild-type C6 glioma cells and clone D27 cells overexpressing dimethylarginine dimethylaminohydrolase (DDAH) was assessed in vivo using a variety of direct and indirect assays of hypoxia. Clone D27 tumors exhibit a more aggressive and better-vascularized phenotype compared to wild-type C6 gliomas. Immunohistochemical analyses using the 2-nitroimidazole hypoxia marker pimonidazole, fiber optic OxyLite measurements of tumor pO2, and localized 31P magnetic resonance spectroscopy measurements of tumor bioenergetic status and pH clearly demonstrated that the D27 tumors were more hypoxic compared to C6 wild type. In the tumor extracts, only glucose concentrations were significantly lower in the D27 tumors. Elevated Glut-1 expression, a reliable functional marker for hypoxia-inducible factor-1-mediated metabolic adaptation, was observed in the D27 tumors. Together, the data show that overexpression of DDAH results in C6 gliomas that are more hypoxic compared to wild-type tumors, and point strongly to an inverse relationship of tumor oxygenation and angiogenesis in vivo--a concept now being supported by the enhanced understanding of oxygen sensing at the molecular level.     

Carbogen breathing with nicotinamide improves the oxygen status of tumours in patients.

Nicotinamide and carbogen breathing are both effective radiosensitisers in experimental tumour models and are even more effective in combination. This study was to investigate the feasibility of using the agents in combination in patients and to measure their effect on tumour oxygenation. Twelve patients with advanced malignant disease were treated with 4-6 g of oral nicotinamide (NCT) in tablet formulation. Ten of these 12 patients breathed carbogen (95% oxygen, 5% carbon dioxide) for up to 20 min at presumed peak plasma NCT concentration (Cpeak) and had tumour oxygen partial pressure (pO2) measured using the Eppendorf pO2) histograph. The mean Cpeak values were 82, 115 and 150 micrograms ml-1 for NCT doses of 4, 5 and 6 g respectively and were dose dependent. The time of Cpeak was independent of dose with an overall mean of 2.4 h (range 0.7-4 h). NCT toxicity occurred in 9 out of 12 patients and was mild in all but one; carbogen was well tolerated in all patients. Following NCT only two patients had significant rises (P < 0.05) in tumour median pO2. During carbogen breathing, eight out of ten patients had early highly significant rises in pO2 (P < 0.0001), of which six continued to rise or remained in plateau until completion of gas breathing. Six patients had hypoxic pretreatment values less than 5 mmHg, which were completely abolished in three and reduced in two during carbogen breathing. In conclusion, the combination of NCT and carbogen breathing was generally well tolerated and gave rise to substantial rises in tumour pO2 which were maintained throughout gas breathing. These results should encourage further study of this potentially useful combination of agents as radiosensitisers in the clinic.     

Clinical outcome and tumour microenvironmental effects of accelerated radiotherapy with carbogen and nicotinamide

Experimental studies have shown an almost 2-fold increase in effectiveness if accelerated radiotherapy combined with carbogen and nicotinamide (ARCON) was compared with standard radiotherapy. This combination was chosen in order to overcome repopulation of clonogens during radiotherapy and to minimize tumour hypoxia. Analysis of microenvironmental parameters is required to identify tumours that can benefit from these new treatment approaches. In this study 124 patients with stage III or IV head and neck squamous cell carcinomas received ARCON treatment. Vascular architecture, perfusion, proliferation and oxygenation were studied in two human laryngeal squamous cell carcinoma xenograft lines and the effects of carbogen and nicotinamide were analysed. Loco-regional control for stage III-IV larynx carcinomas was 85%, for hypopharynx carcinomas 50% and for oral cavity and oropharynx carcinomas 65%. In the experimental studies, carbogen treatment resulted in one tumour line in a decrease of blood perfusion, which was reversed if nicotinamide was added. The other tumour line showed no perfusion changes after carbogen or nicotinamide treatment. Both tumour lines showed a drastic reduction of hypoxia after carbogen breathing only or carbogen breathing plus nicotinamide. The ARCON schedule results in high loco-regional tumour control rates. Analysis of tumour microenvironmental parameters showed differences in response to carbogen and nicotinamide between different tumour lines of similar histology and site of origin. This indicates that it may be advantageous to base the selection of patients for oxygenation modifying treatment on microenvironmental tumour characteristics.     

Potentiation of radiation-induced regrowth delay by isosorbide dinitrate in FSaII murine tumors

Oxygen deficiency in tumors reduces the efficacy of nonsurgical treatment modalities such as conventional radiotherapy and chemotherapy. Since tumor perfusion is directly affected by the vascular resistance to flow of vessels feeding the tumor, vasodilator drugs might be a way to increase tumor blood flow and oxygenation. The effects of nitric oxide (NO) donor administration on tumor oxygenation, perfusion and radiation sensitivity were studied in the FSaII tumor model. Local tumor oxygenation was measured using electron paramagnetic resonance oximetry and a fiberoptic probe, OxyLite. We concomitantly measured the modulation of tumor blood flow by laser Doppler flowmetry. We determined FSaII tumor regrowth delay after isosorbide dinitrate administration and irradiation compared to carbogen breathing before irradiation and with X-rays alone. Administration of the NO donor improved the FSaII tumor pO(2) concomitant with an increase in tumor blood flow. We also demonstrated an increase in FSaII tumor radiation sensitivity after isosorbide dinitrate administration, which was similar to the effect of carbogen breathing in the same tumor model. Administration of isosorbide dinitrate could be considered in terms of improvement in tumor blood flow and a possible concomitant increase in accessibility of chemosensitizing agents to the tumor, particularly in terms of modification of the tumor response to irradiation.     

Potential role of hypoxia imaging using 18F-FAZA PET to guide hypoxia-driven interventions (carbogen breathing or dose escalation) in radiation therapy

Background and purposeHypoxia-driven intervention (oxygen manipulation or dose escalation) could overcome radiation resistance linked to tumor hypoxia. Here, we evaluated the value of hypoxia imaging using ¹⁸F-FAZA PET to predict the outcome and guide hypoxia-driven interventions.Material and methodsTwo hypoxic rat tumor models were used: rhabdomyosarcoma and 9L-glioma. For the irradiated groups, the animals were divided into two subgroups: breathing either room air or carbogen. ¹⁸F-FAZA PET images were obtained just before the irradiation to monitor the hypoxic level of each tumor. Absolute pO₂ were also measured using EPR oximetry. Dose escalation was used in Rhabdomyosarcomas.ResultsFor 9L-gliomas, a significant correlation between ¹⁸F-FAZA T/B ratio and tumor growth delay was found; additionally, carbogen breathing dramatically improved the tumor response to irradiation. On the contrary, Rhabdomyosarcomas were less responsive to hyperoxic challenge. For that model, an increase in growth delay was observed using dose escalation, but not when combining irradiation with carbogen.Conclusions¹⁸F-FAZA uptake may be prognostic of outcome following radiotherapy and could assess the response of tumor to carbogen breathing. ¹⁸F-FAZA PET may help to guide the hypoxia-driven intervention with irradiation: carbogen breathing in responsive tumors or dose escalation in tumors non-responsive to carbogen.     

Oxygen tension measurements of tumors growing in mice.

PURPOSE: Clinical studies using the Eppendorf histograph have shown that patients whose tumors have a low pO2 have worse local control after radiotherapy, and have higher metastatic rates. Because preclinical studies of methods of overcoming, or exploiting, hypoxia generally use transplanted tumors in mice, we have compared the oxygenation of mouse tumors with human tumors to determine the appropriateness of the transplanted mouse model for such preclinical studies. METHODS AND MATERIALS: We evaluated the oxygenation status of subcutaneous (s.c.) tissue and of 12 intradermally (i.d.)- and 7 s.c.-growing mouse or human transplanted tumors in mice using the Eppendorf histograph, and compared the values obtained with measurements of human head and neck nodes. RESULTS: The normal tissue pO2 profile of air-breathing mice showed a nearly Gaussian distribution (38.2+/-14.9 mmHg). Breathing 10% O2 or carbogen resulted in dramatic changes in normal tissue oxygenation. Tumors growing intradermally in the back of air-breathing mice were extremely hypoxic and resistant to expected changes in oxygenation (carbogen breathing, size, and use of anesthetics). Tumors growing s.c. in the foot showed higher oxygen profiles with marked changes in oxygenation when exposing the animals to different levels of oxygen. However, the oxygenation of the mouse tumors transplanted in either site was only a fraction of that of the majority of human tumors. CONCLUSION: Experimental mouse tumors are markedly hypoxic, with median values of 10-20% of those of human tumors. Hence, mouse tumors are probably good models for the most hypoxic human tumors that respond poorly to radiotherapy; however, caution has to be exercised in extrapolating data from mouse to man.