Quantification of longitudinal tissue pO2 gradients in window chamber tumours: impact on tumour hypoxia

SummaryWe previously reported that the arteriolar input in window chamber tumours is limited in number and is constrained to enter the tumour from one surface, and that the pO2 of tumour arterioles is lower than in comparable arterioles of normal tissues. On average, the vascular pO2 in vessels of the upper surface of these tumours is lower than the pO2 of vessels on the fascial side, suggesting that there may be steep vascular longitudinal gradients (defined as the decline in vascular pO2 along the afferent path of blood flow) that contribute to vascular hypoxia on the upper surface of the tumours. However, we have not previously measured tissue pO2 on both surfaces of these chambers in the same tumour. In this report, we investigated the hypothesis that the anatomical constraint of arteriolar supply from one side of the tumour results in longitudinal gradients in pO2 sufficient in magnitude to create vascular hypoxia in tumours grown in dorsal flap window chambers. Fischer-344 rats had dorsal flap window chambers implanted in the skin fold with simultaneous transplantation of the R3230AC tumour. Tumours were studied at 9–11 days after transplantation, at a diameter of 3–4 mm; the tissue thickness was 200 μm. For magnetic resonance microscopic imaging, gadolinium DTPA bovine serum albumin (BSA-DTPA-Gd) complex was injected i.v., followed by fixation in 10% formalin and removal from the animal. The sample was imaged at 9.4 T, yielding voxel sizes of 40 μm. Intravital microscopy was used to visualize the position and number of arterioles entering window chamber tumour preparations. Phosphorescence life time imaging (PLI) was used to measure vascular pO2. Blue and green light excitations of the upper and lower surfaces of window chambers were made (penetration depth of light ~50 vs >200 μm respectively). Arteriolar input into window chamber tumours was limited to 1 or 2 vessels, and appeared to be constrained to the fascial surface upon which the tumour grows. PLI of the tumour surface indicated greater hypoxia with blue compared with green light excitation (P < 0.03 for 10th and 25th percentiles and for per cent pixels < 10 mmHg). In contrast, illumination of the fascial surface with blue light indicated less hypoxia compared with illumination of the tumour surface (P < 0.05 for 10th and 25th percentiles and for per cent pixels < 10 mmHg). There was no significant difference in pO2 distributions for blue and green light excitation from the fascial surface nor for green light excitation when viewed from either surface. The PLI data demonstrates that the upper surface of the tumour is more hypoxic because blue light excitation yields lower pO2 values than green light excitation. This is further verified in the subset of chambers in which blue light excitation of the fascial surface showed higher pO2 distributions compared with the tumour surface. These results suggest that there are steep longitudinal gradients in vascular pO2 in this tumour model that are created by the limited number and orientation of the arterioles. This contributes to tumour hypoxia. Arteriolar supply is often limited in other tumours as well, suggesting that this may represent another cause for tumour hypoxia. This report is the first direct demonstration that longitudinal oxygen gradients actually lead to hypoxia in tumours.

[1]  P Vaupel,et al.  Intracapillary oxyhemoglobin saturation of malignant tumors in humans. , 1981, International journal of radiation oncology, biology, physics.

[2]  M. Dewhirst,et al.  Perivascular oxygen tensions in a transplantable mammary tumor growing in a dorsal flap window chamber. , 1992, Radiation research.

[3]  A. Lindgren The vascular supply of tumours with special reference to the capillary angioarchitekture. , 2009, Acta pathologica et microbiologica Scandinavica.

[4]  R. Pittman,et al.  Oxygen exchange in the microcirculation of hamster retractor muscle. , 1989, The American journal of physiology.

[5]  G. Johnson,et al.  Magnetic resonance microscopy of mouse embryos. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[6]  S M Evans,et al.  Noninvasive imaging of the distribution in oxygen in tissue in vivo using near-infrared phosphors. , 1996, Biophysical journal.

[7]  M. Varia,et al.  Proliferation and hypoxia in human squamous cell carcinoma of the cervix: first report of combined immunohistochemical assays. , 1997, International journal of radiation oncology, biology, physics.

[8]  C. Koch,et al.  Identification of hypoxia in cells and tissues of epigastric 9L rat glioma using EF5 [2-(2-nitro-1H-imidazol-1-yl)-N-(2,2,3,3,3-pentafluoropropyl) acetamide]. , 1995, British Journal of Cancer.

[9]  G. Söderberg,et al.  Vascularization of fibromatous and fibrosarcomatous tumors , 1960 .

[10]  M. Intaglietta,et al.  pO2 measurements in arteriolar networks. , 1996, Microvascular research.

[11]  C G Ellis,et al.  Measurement of hemoglobin oxygen saturation in capillaries. , 1987, The American journal of physiology.

[12]  P. Falk The vascular pattern of the spontaneous C3H mouse mammary carcinoma and its significance in radiation response and in hyperthermia. , 1980, European journal of cancer.

[13]  Rakesh K. Jain,et al.  Interstitial pH and pO2 gradients in solid tumors in vivo: High-resolution measurements reveal a lack of correlation , 1997, Nature Medicine.

[14]  G L Rosner,et al.  Arteriolar oxygenation in tumour and subcutaneous arterioles: effects of inspired air oxygen content. , 1996, The British journal of cancer. Supplement.

[15]  M. Dewhirst,et al.  Microvascular studies on the origins of perfusion-limited hypoxia. , 1996, The British journal of cancer. Supplement.

[16]  J F Gross,et al.  Analysis of oxygen transport to tumor tissue by microvascular networks. , 1993, International journal of radiation oncology, biology, physics.

[17]  Raleigh,et al.  Measuring Tumor Hypoxia. , 1996, Seminars in radiation oncology.

[18]  G. Rosner,et al.  Effects of the calcium channel blocker flunarizine on the hemodynamics and oxygenation of tumor microvasculature. , 1992, Radiation research.

[19]  R. Winslow,et al.  Systemic and subcutaneous microvascular oxygen tension in conscious Syrian golden hamsters. , 1995, The American journal of physiology.

[20]  M. Intaglietta,et al.  pO2Measurements in Arteriolar Networks , 1996 .

[21]  G. Cerniglia,et al.  Localization of tumors and evaluation of their state of oxygenation by phosphorescence imaging. , 1992, Cancer research.

[22]  G. Rosner,et al.  Effects of diethylamine/nitric oxide on blood perfusion and oxygenation in the R3230Ac mammary carcinoma. , 1997, British Journal of Cancer.

[23]  M. Ellsworth,et al.  Arterioles supply oxygen to capillaries by diffusion as well as by convection. , 1990, The American journal of physiology.

[24]  B. Fenton,et al.  Micro-regional mapping of HbO2 saturations and blood flow following nicotinamide administration. , 1994, International journal of radiation oncology, biology, physics.

[25]  J F Gross,et al.  Analysis of the effects of oxygen supply and demand on hypoxic fraction in tumors. , 1995, Acta oncologica.

[26]  J. Gross,et al.  A transparent access chamber for the rat dorsal skin fold. , 1979, Microvascular research.

[27]  L. H. Gray,et al.  The Histological Structure of Some Human Lung Cancers and the Possible Implications for Radiotherapy , 1955, British Journal of Cancer.

[28]  S. Vinogradov,et al.  Intravascular oxygen distribution in subcutaneous 9L tumors and radiation sensitivity. , 1997, Journal of applied physiology.

[29]  D. Thrall,et al.  Immunohistochemical detection of a hypoxia marker in spontaneous canine tumours. , 1990, British Journal of Cancer.

[30]  J F Gross,et al.  Determination of local oxygen consumption rates in tumors. , 1994, Cancer research.

[31]  P. Falk Patterns of vasculature in two pairs of related fibrosarcomas in the rat and their relation to tumour responses to single large doses of radiation. , 1978, European journal of cancer.