Vascular morphometry of KHT and RIF-1 murine sarcomas

IL-17-dependent, IFN-gamma-independent tumor rejection is mediated by cytotoxic T lymphocytes and occurs at extraocular sites, but is excluded from the eye

Although intraocular tumors reside in an immune-privileged site where immune responses are suppressed, some tumors are rejected. An example of this is the rejection of intraocular adenovirus-induced (adenovirus type 5 early region 1 [Ad5E1]) tumors in C57BL/6 mice. We previously identified an Ad5E1 tumor clone in which the rejection is IFN-γ dependent and culminates in the destruction of both the tumor and the eye. Although Ad5E1 tumors are not rejected when transplanted into the eyes of IFN-γ KO mice, they are rejected after s.c. transplantation. Thus, outside of the eye Ad5E1 tumors elicit a form of tumor immunity that is IFN-γ independent. In this article, we demonstrate that IFN-γ-independent s.c. rejection requires both CD4(+) and CD8(+) T cells. Furthermore, s.c. tumor rejection requires IL-17, which is produced by IFN-γ-deficient CD4(+) T cells in response to tumor Ags (TAs). Splenocytes from CD4-depleted IFN-γ KO mice produce significantly less IL-17 compared with splenocytes from isotype-treated IFN-γ KO animals in response to TAs. Furthermore, depletion of IL-17 decreases CTL activity against Ad5E1 tumor cells. In this model we propose that, in the absence of IFN-γ, CD4(+) T cells produce IL-17 in response to TAs, which increases CTL activity that mediates tumor rejection; however, this does not occur in the eye. IL-6 production within the eye is severely reduced, which is consistent with the failure to induce Th17 cells within the intraocular tumors. In contrast, the s.c. environment is replete with IL-6 and supports the induction of Th17 cells. Therefore, IFN-γ-independent tumor rejection is excluded from the eye and may represent a newly recognized form of ocular immune privilege.

Fluence rate as a modulator of PDT mechanisms

BACKGROUND AND OBJECTIVES

Molecular oxygen in the tissue to be treated by photodynamic therapy (PDT) is critical for photodynamic cell killing. The fluence rate of PDT light delivery has been identified as an important modulator of tissue oxygenation and treatment outcome. This article provides supporting evidence for the role of fluence rate in PDT and discusses the underlying mechanisms.

STUDY DESIGN/MATERIALS AND METHODS

Intratumoral pO2 was measured polarographically in murine tumors before and during PDT light treatment using the Eppendorf pO2 Histograph. Tumor response as a function of fluence rate and fluence was also assessed in murine tumor models. Changes in vascular permeability as a function of fluence rate were determined in murine tumors by measuring tumor uptake of fluorescent beads (200 nm diameter).

RESULTS

Severe oxygen depletion is shown to occur within seconds of illumination at a fluence rate of 75 mW/cm2 in radiation-induced fibrosarcoma (RIF) tumors photosensitized with AlPcS2. This effect was reversible and consistent with photochemical oxygen depletion, which has been shown by us and others to be fluence rate dependent. It is demonstrated that fluence rate affects the PDT tumor response in the Colon 26 tumor model, high fluence rate diminishing or even totally inhibiting tumor control, low fluence rate promoting tumor control. The influence of fluence rate is not restricted to cytocidal effects, but can also be seen in sublethal conditions such as vascular permeability.

CONCLUSIONS

Fluence rate of PDT light delivery exerts far-reaching control upon treatment outcome through its oxygenation modulating properties and possibly other mechanisms yet to be identified. This has been shown to be true in the preclinical and clinical setting. Further development of in situ dosimetry will be necessary to take full advantage of these discoveries.

Transvaginal color Doppler sonography for predicting response to concurrent chemoradiotherapy for locally advanced cervical carcinoma

PURPOSE

This study was conducted to evaluate the potential role of transvaginal color Doppler sonography (TVCD) in predicting response to concurrent chemoradiotherapy for locally advanced cervical cancer.

METHODS AND MATERIALS

Tumor vascularity was assessed using TVCD before the start of concurrent chemoradiotherapy in 21 patients (median age, 47 years; range, 31-75 years) with histologically proven locally advanced cervical cancer. The lowest resistance index (RI), lowest pulsatility index (PI), and highest peak systolic velocity (PSV) from central vessels within the tumor were recorded and used for analysis. All patients were clinically evaluated by physical examination and CT scanning after completing the chemoradiotherapy protocol. Complete clinical response (CR) was determined when no residual tumor was found. Partial clinical response (PR) was determined when the tumor volume had decreased more than 50%.

RESULTS

CR was achieved in 11 patients (52%), whereas 10 (48%) had PR. The initial median tumor volume was not statistically different between those with CR (26 cm3) and those with PR (28 cm3) (p = 0.71). RI was higher in those tumors with CR (median, 0.47) than in those with PR (median, 0.29) (p < 0.01). Likewise, PI was higher in tumors with CR (median, 0.81) than in those with PR (median, 0.41) (p < 0.01). No differences were found in PSV. The likelihood ratio for CR for tumors with a lowest RI of 0.35 or more was 2.7 (95% confidence interval, 1.8-3.6) and the likelihood ratio for CR for tumors with a lowest PI of 0.45 or more was 3.3 (95% confidence interval, 2.1-4.5).

CONCLUSIONS

The results suggest that TVCD may be useful in predicting clinical response to concurrent chemoradiation in patients with locally advanced cervical cancer.

Blood flow dynamics after photodynamic therapy with verteporfin in the RIF-1 tumor

In the present study, the effects of photodynamic therapy (PDT) with verteporfin on tumor blood flow and tumor regrowth were compared as verteporfin distributed in different compartments within the RIF-1 tumor. Tissue distribution of verteporfin was examined by fluorescence microscopy, and blood flow measurements were taken with a laser Doppler system. It was found that, at 15 min after drug administration, when verteporfin was mainly confined within the vasculature, PDT induced a complete arrest of blood flow by 6 h after treatment. PDT treatment at a longer drug-light interval (3 h), which allowed the drug to diffuse to the tumor interstitium, caused significantly less flow decrease, only to 50% of the initial flow in 6 h. A histological study and Hoechst 33342 staining of functional tumor vasculature confirmed the primary vascular damage and the decrease in tumor perfusion. The regrowth rate of tumors treated with 15-min interval PDT was 64% of that of the control group. However, when tumors were treated with 3-h interval PDT, the regrowth rate was not significantly different from that of the control, indicating that only the 15-min interval PDT caused serious damage to the tumor vascular bed. These results support the hypothesis that temporal pharmacokinetic changes in the distribution of the photosensitizer between the tumor parenchyma and blood vessels can significantly alter the tumor target of PDT.

Spatial heterogeneity and temporal kinetics of photosensitizer (AlPcS2) concentration in murine tumors RIF-1 and MTG-B

In this study we compared the photosensitizer concentration in two experimental murine tumors using an in situ fluorescence detection instrument to examine temporal and spatial variations, after intravenous versus intratumor injection. Also, the variations in the estimate as detected by large area sampling and micro-region sampling are compared, in order to determine what the inter-tissue and inter-animal variations are, and how the method of sampling affects this estimate. The latter study was carried out ex vivo in the same tumors, which had been harvested and frozen after in vivo measurements were made. The photosensitizer, disulphonated aluminum phthalocyanine (AlPcS2) was injected either intravenously (IV) or directly into the tumor (ITu), using two murine models, MTG-B (mammary adenocarcinoma) and RIF-1 (radiation-induced fibrosarcoma) grown subcutaneously on the flank. An in situ microsampling fluorescence probe was used to assess photosensitizer concentration, through real-time measurement of the remitted intensity. The photosensitizer concentration was evaluated at 8 time endpoints between 15 min and 48 h post-injection. Inter-tumor and intra-tumor variations were assessed by repeated samples from the tumor tissues. The average photosensitizer level reaches a peak between 3 to 6 h in both tumor and normal tissues using IV administration, but peaks within 1 h following ITu administration. MTG-B tumors demonstrated a factor of 2 higher uptake than RIF-1 tumors. The pharmacokinetic uptake rates of the RIF-1 tumor were 3 times faster than for MTG-B, while there was no statistical difference in their clearance rates. Preferential uptake of AlPcS2 by both tumors compared to contra-lateral flank subcutaneous normal tissue was documented, with ITu injection exceeding IV injection by a factor of 10 in the tumor to normal tissue ratio. Inter-animal standard deviation in the mean fluorescence was near 76% for both routes of administration, but estimates of the variation within tumor were near 16% standard deviation when a large sampling volume was used. In contrast, microscopic intra-tumor standard deviation in the mean estimate was near 76%, with IV injection, indicating that high heterogeneity exists in the photosensitizer concentration on a smaller distance scale. The inter-tumor variation was reduced by ITu injection, but at the expense of increasing intra-tumor variation.

Potentiation of Photodynamic Therapy with Hypericin by Mitomycin C in the Radiation-induced Fibrosarcoma–1 Mouse Tumor Model¶

Hypericin, a polycyclic quinone obtained from plants of the genus Hypericum, has been shown to be a promising photosensitizer. We investigated the combination of hypericin-photodynamic therapy (PDT) and a bioreductive drug mitomycin C (MMC) in the present study. The radiation-induced fibrosarcoma-1 tumors were exposed to laser light (120 J/cm2 at 595 nm) 24 h after an intravenous injection of hypericin (1 mg/kg). Hypericin-PDT alone significantly decreased tumor perfusion and oxygen tension as demonstrated by India ink staining technique and OxyLite pO2 measurement, respectively. The in vivo-in vitro cell-survival assay revealed about 60% direct tumor cell killing immediately after PDT. No significant delayed tumor cell death was observed after PDT, which suggests that vascular damage does not contribute significantly to the overall tumor cell death. Injection of a 2.5 mg/kg dose of MMC 20 min before light application significantly decreased tumor cell survival and delayed tumor growth compared with PDT or MMC alone. No greater skin reaction was observed after the combination of MMC and PDT than after PDT alone. Our study demonstrates that combining hypericin-PDT with MMC can be effective in enhancing tumor response with little side effect.

Oxygenation and Vascular Perfusion in Spontaneous and Transplanted Tumor Models

Since quantitative measurements of tumor vascular function cannot be obtained in human tumors, appropriate animal tumor models must be utilized. The current studies were undertaken to compare transplantable, murine KHT tumors with primary and 1st generation transplants of spontaneous mammary carcinomas. To evaluate changes in tumor vascular structure and function, immunostaining of total and perfused vascular spacing, and cryospectrophotometric measurement of intravascular HbO2 saturations were utilized. KHT tumors demonstrated a distinct pattern of decreasing oxygenation with increasing distance from the tumor surface, while spontaneous tumors exhibited striking intertumor heterogeneities and a reduced dependence of oxygenation on distance from tumor surface. Anatomical/perfused vessel distributions and functional response were similar between the primary and transplanted tumor models, as was tissue histological appearance, but were quite different from KHT tumors. These results indicate that spontaneous tumor vascular configuration and function tend to be preserved in 1st generation trochar transplanted tumors.

Analysis of the heterogeneity of pO2 dynamics during photodynamic therapy with verteporfin

Photodynamic therapy (PDT) with verteporfin provides a reliable way to destroy malignant tissues. Changes in the blood flow and oxygen partial pressure (pO2) during verteporfin-PDT were studied here in the tumor tissue of the rat mammary R3230Ac carcinoma model. Oxygen microelectrodes (6-12 microns tip diameter) were used to measure the transients locally within tumors during intravenous injection of 1.0 mg/kg verteporfin followed by irradiation 15 min later with 690 nm light at 200 mW/cm2, for a cumulative dose of 144 J/cm2. The observed changes in pO2 were heterogeneous and there was a difference in the response of low-pO2 regions relative to higher-pO2 regions. The change in pO2 in hypoxic tissue regions (pO2 < 8 mmHg) had acute pO2 loss after treatment, whereas the response in regions of higher pO2 (> 8 mm Hg) was more heterogeneous with some areas maintaining their pO2 value after treatment was completed. Blood flow measurements taken on a subset of the animals indicated a significant loss in flow during the initial light delivery that remained low after treatment, indicating some vascular stasis. The results suggest that hypoxic or poorly perfused vessels may be more susceptible to acute stasis than normoxic vessels in this treatment protocol.

Characterization of the effects of antiangiogenic agents on tumor pathophysiology

A variety of strategies have been proposed to control tumor growth and metastasis by inhibiting tumor angiogenesis. To optimally combine such antiangiogenic approaches with conventional therapy, improved methods are needed to characterize the underlying pathophysiologic changes. The objective of the current work was to demonstrate the utility of a combination of recently developed immunohistochemical and image analysis techniques in quantitating changes in tumor vasculature and hypoxia. Murine MCa-35 mammary carcinomas were frozen after administration of two COX-2 inhibitors: meloxicam and celecoxib (Celebrex). Total blood vessels were visualized using anti-CD31 staining, perfused vessels by intravenous injection of DiOC7, and tumor hypoxia by EF5 uptake. Although both agents produced similar reductions in tumor volume compared with untreated tumors, varied effects on tumor vasculature and hypoxia were noted. Meloxicam reduced total vessel numbers significantly, whereas celecoxib had no effect. Both drugs substantially increased perfused vessel densities. Although mean hypoxic marker uptake was unchanged from matched controls, intratumor EF5 heterogeneities were significantly different between drugs. The results suggest that COX-2 inhibitors can have varying effects on tumor pathophysiology. Successful use of these drugs to enhance radiation response will likely require optimization of drug choice, dose schedule, and direct physiologic monitoring.

Intravascular HBO(2) saturations, perfusion and hypoxia in spontaneous and transplanted tumor models

Clinical trials utilizing strategies to manipulate tumor oxygenation, blood flow and angiogenesis are under way, although limited quantitative information exists regarding basic tumor pathophysiology. The current study utilized murine KHT fibrosarcomas, spontaneous mammary carcinomas and first-generation spontaneous transplants to examine heterogeneity in vascular structure and function, to relate these changes to the distribution of tumor hypoxia and to determine whether fundamental relationships among the different pathophysiological parameters exist. Three methods were included: (i) immunohistochemical staining of anatomical and perfused blood vessels, (ii) cryospectrophotometric measurement of intravascular oxyhemoglobin saturations and (iii) fluorescent detection of the EF5 hypoxic marker. While a distinct pattern of decreasing oxygenation with increasing distance from the tumor surface was observed for KHT tumors, striking intertumor variability was found in both spontaneous and first-generation transplants, with a reduced dependence on tumor volume. EF5 hypoxic marker uptake was also much more heterogeneous among individual spontaneous and first-generation tumors compared to KHT. Although mammary carcinomas demonstrated fewer anatomical blood vessels than fibrosarcomas, the proportion of perfused vessels was substantially reduced in KHT tumors, especially at larger tumor volumes. Vascular morphology, tissue histological appearance and pathophysiological parameters differed substantially between KHT tumors and both spontaneous and first-generation tumors. Such differences in vascular structure and function are also likely to correlate with altered response to therapies targeted to the vascular system. Finally, spontaneous differentiation status, tumor morphology, vascular configuration and function were well preserved in first-generation transplanted tumors, suggesting a close relationship between vascular development and function in early-generation transplants and spontaneous tumor models.

Influence of hydralazine administration on oxygenation in spontaneous and transplanted tumor models

PURPOSE

To examine the effects of hydralazine on vascular perfusion and hypoxia in spontaneous vs. first generation and long-term transplanted murine tumor models.

METHODS AND MATERIALS

Total anatomic blood vessels were quantified using image analysis of CD31 stained frozen sections, perfused vessels by i.v. injection of fluorescent DiOC(7), and tumor hypoxia was measured using the EF5 hypoxia marker. KHT sarcomas, spontaneous mammary carcinomas, and first generation transplants of the spontaneous tumors were evaluated before and after i.p. administration of 5 mg/kg hydralazine.

RESULTS

Although anatomic and perfused vessel spacings were similar among untreated tumors, response to hydralazine varied widely among the three tumor models. In KHT tumors, perfused vessel numbers decreased significantly at 30 min post-hydralazine, then recovered somewhat by 60 min. First-generation transplants showed a less substantial decrease in perfused vessels following hydralazine, which tapered off slightly by 60 min. Finally, spontaneous tumors had only a modest decrease in perfused vessel numbers, with complete recovery at 60 min. Although response of individual tumors varied widely, overall hypoxic marker uptake was significantly increased in both KHT and first generation tumors, and slightly reduced in the spontaneous tumors.

CONCLUSION

Response to hydralazine varies substantially between transplanted and spontaneous tumor models. Results suggest that increased tumor pressure may be a critical factor in tumor response to hydralazine, possibly explaining tumor volume dependent variations.

Effects of radiation on tumor intravascular oxygenation, vascular configuration, development of hypoxia, and clonogenic survival

The underlying physiological mechanisms leading to tumor reoxygenation after irradiation have elicited considerable interest, but they remain somewhat unclear. The current study was undertaken to determine the effects of a single dose of 10 Gy gamma radiation on both tumor pathophysiology and radiobiologically hypoxic fraction. Immunohistochemical staining and perfusion markers were used to quantify tumor vasculature, uptake of the hypoxia marker EF5 to assess the distribution of hypoxia, and intravascular HbO(2) measurements to determine oxygen availability. Tumor radiosensitivity was measured by a clonogenic assay. At 24 h postirradiation, oxygen availability increased, perfused vessel numbers decreased, EF5 uptake decreased, and the radiobiologically hypoxic fraction was unchanged. Together, these results demonstrate that tumor hypoxia develops at an increased distance from perfused blood vessels after irradiation, suggesting a decrease in oxygen consumption at 24 h. By 72 h postirradiation, all physiological parameters had returned to the levels in volume-matched, nonirradiated controls. These studies clearly show that single measures of either tumor oxygenation or vascular structure are inadequate for assessing the effects of radiation on tumor clonogenicity. Although such direct measurements have previously proven valuable in predicting tumor response to therapy or oxygen manipulation, a combination of parameters is required to adequately describe the mechanisms underlying these changes after irradiation.

Enhancement of tumor perfusion and oxygenation by carbogen and nicotinamide during single- and multifraction irradiation

Numerous experimental and clinical studies have been completed regarding the effects of carbogen and nicotinamide on tumor oxygenation and radiosensitivity. The current study incorporates three physiological measurement techniques to further define spatial variations in oxygen availability and development of hypoxia after single- and multifraction irradiation in KHT murine fibrosarcomas. Distances to anatomical and perfused blood vessels were measured using immunohistochemical and fluorescent staining, intravascular oxygen levels were determined cryospectrophotometrically, and tumor hypoxia was quantified using uptake of EF5, a marker of hypoxia. Carbogen, nicotinamide, and the combination of both all increased intravascular oxygen availability compared to controls. While nicotinamide had no effect on the number of perfused blood vessels in nonirradiated tumors, carbogen produced a substantial closing of vessels. After a single dose of 4 Gy, only the combination of nicotinamide and carbogen produced significant improvements in oxygen availability, while numbers of perfused vessels were significantly increased for nicotinamide, unchanged for the combination of nicotinamide and carbogen, and significantly decreased for carbogen. After 4 x 4-Gy fractions, oxygen availability was increased substantially with the combination of nicotinamide and carbogen, somewhat with carbogen, and not at all with nicotinamide. Tumor oxygenation changes were estimated by EF5/Cy3 intensity distributions, which demonstrated that manipulative agents could produce disparate effects on tumor hypoxia when combined with either single- or multifraction irradiation.

Transvaginal color Doppler for predicting pathological response to preoperative chemoradiation in locally advanced cervical carcinoma: a preliminary study

To evaluate the role of transvaginal color Doppler ultrasonography (TCD) in predicting pathological response to preoperative chemoradiation in patients with locally advanced cervical cancer, 10 patients (mean age: 45.2 y, range: 31 to 75 y) with histologically proven locally advanced cervical cancer who were scheduled for preoperative chemoradiation were evaluated by TCD prior to beginning the treatment protocol. Tumor volume, number of vessels within the tumor, lowest resistance index (RI), maximum peak systolic velocity (PSV), and the ratio between the number of vessels and tumor volume (tumor vascular density, TVD) were calculated. All patients underwent preoperative chemoradiation and radical surgery. Complete pathological response (pathCR) was considered when no residual tumor was found on surgical specimens. Partial pathological response (pathPR) was considered when residual tumor was found. PathCR was achieved in three patients (30%), whereas 7 (70%) had pathPR. Mean tumoral volume was not statistically different between those with pathCR (33.2 cm3) and those with pathPR (20.3 cm3) (p = 0.305). Those tumors with pathCR had lower mean number of vessels (3.3 vs. 5.3, p = 0.01), lower TVD (0.1 vs. 1.1, p = 0.05) and higher RI (0.41 vs. 0.29, p = 0.03). No differences were found in PSV. Although these data are preliminary, our results suggest that TCD may be used to predict pathological response to preoperative chemoradiation in patients with locally advanced cervical cancer.

Quantification of tumour vasculature and hypoxia by immunohistochemical staining and HbO2 saturation measurements

Despite the possibility that tumour hypoxia may limit radiotherapeutic response, the underlying mechanisms remain poorly understood. A new methodology has been developed in which information from several sophisticated techniques is combined and analysed at a microregional level. First, tumour oxygen availability is spatially defined by measuring intravascular blood oxygen saturations (HbO2) cryospectrophotometrically in frozen tumour blocks. Second, hypoxic development is quantified in adjacent sections using immunohistochemical detection of a fluorescently conjugated monoclonal antibody (ELK3-51) to a nitroheterocyclic hypoxia marker (EF5), thereby providing information relating to both the oxygen consumption rates and the effective oxygen diffusion distances. Third, a combination of fluorescent (Hoechst 33342 or DiOC7(3)) and immunohistological (PECAM-1/CD31) stains is used to define the anatomical vascular densities and the fraction of blood vessels containing flow. Using a computer-interfaced microscope stage, image analysis software and a 3-CCD colour video camera, multiple images are digitized, combined to form a photo-montage and revisited after each of the three staining protocols. By applying image registration techniques, the spatial distribution of HbO2 saturations is matched to corresponding hypoxic marker intensities in adjacent sections. This permits vascular configuration to be related to oxygen availability and allows the hypoxic marker intensities to be quantitated in situ.

Reduction of tumour oxygenation during and after photodynamic therapy in vivo: effects of fluence rate

It has been proposed that the generation of O2 during photodynamic therapy (PDT) may lead to photochemical depletion of ambient tumour oxygen, thus causing acute hypoxia and limiting treatment effectiveness. We have studied the effects of fluence rate on pO2, in the murine RIF tumour during and after PDT using 5 mg kg(-1) Photofrin and fluence rates of 30, 75 or 150 mW cm(-2). Median pO2 before PDT ranged from 2.9 to 5.2 mmHg in three treatment groups. Within the first minute of illumination, median tumour pO2 decreased with all fluence rates to values between 0.7 and 1.1 mmHg. These effects were rapidly and completely reversible if illumination was interrupted. During prolonged illumination (20-50 J cm(-2)) pO2 recovered at the 30 mW cm(-2) fluence rate to a median value of 7.4 mmHg, but remained low at the 150 mW cm(-2) fluence rate (median pO2 1.7 mmHg). Fluence rate effects were not found after PDT, and at both 30 and 150 mW cm(-2) median tumour pO2 fell from control levels to 1.0-1.8 mmHg within 1-3 h after treatment conclusion. PDT with 100 J cm(-2) at 30 mW cm(-2) caused significantly (P = 0.0004) longer median tumour regrowth times than PDT at 150 mW cm(-2), indicating that lower fluence rate can improve PDT response. Vascular perfusion studies uncovered significant fluence rate-dependent differences in the responses of the normal and tumour vasculature. These data establish a direct relationship between tumour pO2, the fluence rate applied during PDT and treatment outcome. The findings are of immediate clinical relevance.

In situ 19F MRS measurement of RIF-1 tumor blood volume: corroboration by radioisotope-labeled [125I]-albumin and correlation to tumor size

Tumor blood volume (TBV) is an important factor in the metabolism of a tumor and in its response to therapy. Until recently, the only methods to determine TBV were highly invasive and many involved radioisotopes. In this study, a perfluorocarbon (PFC) emulsion, Oxypherol, was monitored by 19F magnetic resonance spectroscopy (MRS). TBVs as determined by 19F MRS of in situ and excised radiation-induced fibrosarcoma (RIF-1) tumors (n = 9), were strongly correlated with the TBV measured by a radioisotope labeled albumin method (slopes of 1.1 and 0.8 with R = 0.86 and 0.91, respectively, by linear regression). In general, the TBV as calculated from the in situ MRS measurements (n = 24) decreased from 28 to 5 ml/100 g tumor mass for tumors ranging in mass from 0.15 to 2 g. However, there was an indication of an initial increase of TBV in tumors smaller than 0.5 g.

Inherent cellular differences may explain the dissimilar survival of RIF-1 and KHT tumour cells under aerobic and hypoxic conditions

Although previous work has shown striking differences in radiobiological hypoxic fraction between KHT and RIF-1 murine sarcomas, intravascular oxyhaemoglobin (HbO2 saturations have revealed less substantial variations. Using quantitative histological techniques, we have also found minor differences in the distributions of distances between tumour cells and the nearest bloods vessel for KHT versus RIF-1 sarcomas. We report here, the results of an investigation of the inherent ability of these tumour cells to withstand conditions of hypoxia by in vitro culturing under aerobic and anoxic conditions. Tumours were dissociated, seeded into culture dishes, and placed in air-tight aluminium chambers. These chambers were repeatedly evacuated and refilled with a mixture of 95% N2 and 5% CO2 over a 2.5-h period. Following anoxic exposure, cells were removed and replated, and the in vitro plating efficiency (PE) was determined using a colony survival assay. After normalizing to aerobic controls, KHT tumour cells had a significantly lower PE, following a 16-hour exposure to anoxic conditions (0.4), than RIF-1 (0.6). Increasing the hypoxic exposure to 40 h resulted in normalized PEs of 0.07 for KHT versus 0.4 for RIF-1. Although these results support the hypothesis that the two tumour lines have different inherent abilities to withstand hypoxia, they do not explain the failure of direct measures of tumour oxygenation to correlate with the radiobiological hypoxic fraction. Additional factors such as differences in oxygen diffusivity or oxygen consumption rates between tumour lines may also be involved.