Tumor Vascular Perfusion Research Articles

Disparate effects of endostatin on tumor vascular perfusion and hypoxia in two murine mammary carcinomas

Purpose Recent results in the literature have demonstrated that the antiangiogenic agent endostatin can enhance antitumor effects when administered before or during radiotherapy. To better understand the underlying pathophysiologic basis for this radiosensitization, the current study investigated whether short-term endostatin administration is linked to alterations in tumor vascular perfusion and oxygen delivery. Methods and materials Three daily doses of recombinant endostatin (20 mg/kg) were administered to two murine mammary carcinomas, the highly vascularized MCa-35 and the less vascularized MCa-4. Image analysis techniques were used to quantify ( 1) total and perfused vascular spacing, and ( 2) changes in tumor hypoxia as a function of distance from the nearest blood vessel. Results In MCa-35 tumors, endostatin had no effect on vessel spacing, tumor hypoxia, or tumor growth. In MCa-4 tumors, total and perfused vessel spacings were also unchanged, but tumor growth was inhibited, and tumor hypoxia significantly decreased. These tumors demonstrated an increased vascular functionality suggestive of an increase in the number of intermittently perfused vessels, without corresponding alterations in tumor oxygen consumption rate. Conclusions Poorly vascularized, hypoxic mammary carcinomas were much more responsive to short-term endostatin treatment than well-vascularized, more homogeneously oxygenated tumors. Oxygen levels in the responsive tumors were transiently improved after treatment, which could have substantial implications with respect to the therapeutic effectiveness of combining antiangiogenic agents with conventional therapies.

Zonal image analysis of tumour vascular perfusion, hypoxia, and necrosis.

A number of laboratories are utilising both hypoxia and perfusion markers to spatially quantify tumour oxygenation and vascular distributions, and scientists are increasingly turning to automated image analysis methods to quantify such interrelationships. In these studies, the presence of regions of necrosis in the immunohistochemical sections remains a potentially significant source of error. In the present work, frozen MCa-4 mammary tumour sections were used to obtain a series of corresponding image montages. Total vessels were identified using CD31 staining, perfused vessels by DiOC7 staining, hypoxia by EF5/Cy3 uptake, and necrosis by haematoxylin and eosin staining. Our goal was to utilise image analysis techniques to spatially quantitate hypoxic marker binding as a function of distance from the nearest blood vessel. Several refinements to previous imaging methods are described: (1) hypoxia marker images are quantified in terms of their intensity levels, thus providing an analysis of the gradients in hypoxia with increasing distances from blood vessels, (2) zonal imaging masks are derived, which permit spatial sampling of images at precisely defined distances from blood vessels, as well as the omission of necrotic artifacts, (3) thresholding techniques are applied to omit holes in the tissue sections, and (4) distance mapping is utilised to define vascular spacing.British Journal of Cancer (2002) 86, 1831–1836. doi:10.1038/sj.bjc.6600343 www.bjcancer.com© 2002 Cancer Research UK

Noninvasive investigation of blood oxygenation dynamics of tumors by near-infrared spectroscopy

The measurement of dynamic changes in the blood oxygenation of tumor vasculature could be valuable for tumor prognosis and optimizing tumor treatment plans. In this study we employed near-infrared spectroscopy (NIRS) to measure changes in the total hemoglobin concentration together with the degree of hemoglobin oxygenation in the vascular bed of breast and prostate tumors implanted in rats. Measurements were made while inhaled gas was alternated between 33% oxygen and carbogen (95% O(2), 5% CO(2)). Significant dynamic changes in tumor oxygenation were observed to accompany respiratory challenge, and these changes could be modeled with two exponential components, yielding two time constants. Following the Fick principle, we derived a simplified model to relate the time constants to tumor blood-perfusion rates. This study demonstrates that the NIRS technology can provide an efficient, real-time, noninvasive means of monitoring the vascular oxygenation dynamics of tumors and facilitate investigations of tumor vascular perfusion. This may have prognostic value and promises insight into tumor vascular development.

Measurement of tumor vascular damage in mice with 99mTc-MIBI following photodynamic therapy.

The clinical perfusion agent 99mTc-MIBI was used to monitor changes in tumor vascular perfusion (TVP) induced by Photofrin (PII)-mediated photodynamic therapy (PDT). BALB/c mice bearing an EMT-6 tumor on each hind thigh were given an intravenous injection of 1, 2 or 5 mg kg-1 PII. Twenty-four hours later, one tumor was illuminated (600-650 nm, 200 mW cm-2, 400 J cm-2) while the other served as a control. At various time intervals after PDT (0, 2 and 24 h) mice received an intravenous injection of 99mTc-hexakismethoxyisobutylisonitrile (MIBI) (0.18 MBq g-1) and were sacrificed 2 min later. The light-treated and the untreated tumors were then dissected, the radioactivity was counted and the percentage of the injected dose per gram of tumor (%ID g-1) was calculated as a measure of TVP. We observed that TVP is drug dose dependent, develops progressively with time post-PDT and is inversely related to PDT efficacy. Our data show that early tumor retention of 99mTc-MIBI is a simple method to assess TVP and vascular damage induced by PDT.

TUMOR VASCULAR SHUTDOWN FOLLOWING PHOTODYNAMIC THERAPY BASED ON POLYHEMATOPORPHYRIN OR 5-AMINOLEVULINIC ACID

The effects of photodynamic therapy (PDT) based on polyhaematoporphyrin (PHP) or 5-aminolaevulinic acid (ALA) on the tumour vascular perfusion (TVP) of a rat fibrosarcoma were examined using an (RbCl)-Rb-86 extraction technique. Both forms of therapy induced large and highly significant reductions in TVP, countering the previous suggestion that ALA-PDT has no vascular effects. Ultrasensitive digital imaging fluorescence microscopy indicated that ALA-induced PpIX was distributed relatively evenly throughout the tumour. Use of Hoechst 33342 as a vascular marker revealed that PpIX was also present in cells lining the tumour microvascular spaces, contrary to previous findings.

The energy metabolism of RIF-1 tumours following hydralazine

Phosphorus-31 Magnetic Resonance Spectroscopy (MRS) was used to observe the effect of two doses of the vasodilator hydralazine on the energy status of RIF-1 tumours. An intravenous dose of 5 mg/kg hydralazine reduced the high energy phosphate metabolites PCr and ATP, lowered pH MRs and raised the levels of inorganic phosphate of tumours within 20 min of administering the drug. The levels of high energy metabolites continued to decrease for at least 24 h. Normal muscle spectra obtained up to 1 h after drug administration remained unchanged. An intravenous dose of 0.5 mg/kg hydralazine also reduced NTP/Pi and PCr/Pi levels of tumours up to at least 5 h after drug administration, but the effect was smaller than for the higher dose. Blood flow measurements and measurements of systemic blood pressure demonstrated that 5 mg/kg of hydralazine produced a reduction in both systemic blood pressure and tumour blood flow relative to most normal tissues investigated. It is concluded that the changes in the P-31 MRS spectra of tumours were due to a reduction in tumour vascular perfusion following administration of hydralazine.