Blood flow and metabolic microenvironment of brain tumors

How best to interpret measures of levels of oxygen in tissues to make them effective clinical tools for care of patients with cancer and other oxygen-dependent pathologies

It is well understood that the level of molecular oxygen (O2 ) in tissue is a very important factor impacting both physiology and pathological processes as well as responsiveness to some treatments. Data on O2 in tissue could be effectively utilized to enhance precision medicine. However, the nature of the data that can be obtained using existing clinically applicable techniques is often misunderstood, and this can confound the effective use of the information. Attempts to make clinical measurements of O2 in tissues will inevitably provide data that are aggregated over time and space and therefore will not fully represent the inherent heterogeneity of O2 in tissues. Additionally, the nature of existing techniques to measure O2 may result in uneven sampling of the volume of interest and therefore may not provide accurate information on the "average" O2 in the measured volume. By recognizing the potential limitations of the O2 measurements, one can focus on the important and useful information that can be obtained from these techniques. The most valuable clinical characterizations of oxygen are likely to be derived from a series of measurements that provide data about factors that can change levels of O2 , which then can be exploited both diagnostically and therapeutically. The clinical utility of such data ultimately needs to be verified by careful studies of outcomes related to the measured changes in levels of O2 .

Kinomic profiling of glioblastoma cells reveals PLCG1 as a target in restricted glucose

Background

For glioblastoma (GBM) treatments to be effective in vivo, understanding the effects of the tumor microenvironment is imperative. In traditional cell culture conditions, glucose concentrations do not model physiologic levels, nor the diminished concentrations found in tumor niches. We therefore sought to profile the differences in kinase activity in GBM cells cultured in restricted glucose to identify pathways that could be targeted with small molecule inhibitors.

Methods

Using the PamStation12 platform, we examined the ability of GBM lysates from cells cultured in standard or low glucose conditions to phosphorylate 144 tyrosine and 144 serine/threonine peptides that correspond to known protein phosphorylation sites. Potential kinase targets were identified and validated using small molecule kinase inhibitors in GBM spheroid cultures.

Results

Using results from two GBM patient-derived xenografts, we determined common changes to peptides derived from Phospholipase C, Gamma 1 (PLCG1) and Raf-1. Using PLC and Raf inhibitors, we found a significantly stronger growth inhibitory effect of the PLC inhibitor U73122 under restricted glucose conditions. In contrast, Raf inhibitors were significantly growth inhibitory regardless of the nutrient level tested.

Conclusions

Together, our data demonstrate that kinase activity is altered in low glucose conditions and that kinomic profiling can assist with the identification of effective strategies to target GBM growth. Our data further suggest the importance of accurately modeling the tumor microenvironment to reproduce cancer cell signaling and develop drug screens for anti-cancer agents.

Characterizing hypoxia in human glioma: A simultaneous multimodal MRI and PET study

Hypoxia plays an important role for the prognosis and therapy response of cancer. Thus, hypoxia imaging would be a valuable tool for pre-therapeutic assessment of tumor malignancy. However, there is no standard validated technique for clinical application available yet. Therefore, we performed a study in 12 patients with high-grade glioma, where we directly compared the two currently most promising techniques, namely the MR-based relative oxygen extraction fraction (MR-rOEF) and the PET hypoxia marker H-1-(3-[¹⁸ F]-fluoro-2-hydroxypropyl)-2-nitroimidazole ([¹⁸ F]-FMISO). MR-rOEF was determined from separate measurements of T₂ , T₂ * and relative cerebral blood volume (rCBV) employing a multi-parametric approach for quantification of the blood-oxygenation-level-dependent (BOLD) effect. With respect to [¹⁸ F]-FMISO-PET, besides the commonly used late uptake between 120 and 130 min ([¹⁸ F]-FMISO_{120-130 min} ), we also analyzed the hypoxia specific uptake rate [¹⁸ F]-FMISO-k₃ , as obtained by pharmacokinetic modeling of dynamic uptake data. Since pharmacokinetic modeling of partially acquired dynamic [¹⁸ F]-FMISO data was sensitive to a low signal-to-noise-ratio, analysis was restricted to high-uptake tumor regions. Individual spatial analyses of deoxygenation and hypoxia-related parameter maps revealed that high MR-rOEF values clustered in (edematous) peritumoral tissue, while areas with high [¹⁸ F]-FMISO_{120-130 min} concentrated in and around active tumor with disrupted blood-brain barrier, i.e. contrast enhancement in T₁ -weighted MRI. Volume-of-interest-based correlations between MR-rOEF and [¹⁸ F]-FMISO_{120-130 min} as well as [¹⁸ F]-FMISO-k₃ , and voxel-wise analyses in individual patients, yielded limited correlations, supporting the notion that [¹⁸ F]-FMISO uptake, even after 2 h, might still be influenced by perfusion while [¹⁸ F]-FMISO-k₃ was severely hampered by noise. According to these results, vascular deoxygenation, as measured by MR-rOEF, and severe tissue hypoxia, as measured by [¹⁸ F]-FMISO, show a poor spatial correspondence. Overall, the two methods appear to rather provide complementary than redundant information about high-grade glioma biology.

Stress Response Leading to Resistance in Glioblastoma-The Need for Innovative Radiotherapy (iRT) Concepts

Glioblastoma (GBM) is the most common and most aggressive malignant primary brain tumor in adults. In spite of multimodal therapy concepts, consisting of surgery, radiotherapy and chemotherapy, the median survival, merely 15–18 months, is still poor. Mechanisms for resistance of GBM to radio(chemo)therapy are not fully understood yet and due to the genetic heterogeneity within the tumor including radiation-resistant tumor stem cells, there are several factors leading to therapy failure. Recent research revealed that, hypoxia during radiation and miRNAs may adversely affect the therapeutic response to radiotherapy. Further molecular alterations and prognostic markers like the DNA-repair protein O6-methylguanine-DNA methyltransferase (MGMT), anti-apoptotic molecular chaperones, and/or the activity of aldehyde dehydrogenase 1 (ALDH1) have also been identified to play a role in the sensitivity to cytostatic agents. Latest approaches in the field of radiotherapy to use particle irradiation or dose escalation strategies including modern molecular imaging, however, need further evaluation with regard to long-term outcome. In this review we focus on current information about the mechanisms and markers that mediate resistance to radio(chemo)therapy, and discuss the opportunities of Innovative Radiotherapy (iRT) concepts to improve treatment options for GBM patients.

Mixed surfactant modified graphene oxide nanocarriers for DOX delivery to cisplatin-resistant human ovarian carcinoma cells

Mixed surfactant modified graphene oxide nanocarriers based on the nonideal mixed micelle theory of surfactants exhibit great potential in drug delivery.

Critical role of aberrant angiogenesis in the development of tumor hypoxia and associated radioresistance

Newly formed microvessels in most solid tumors show an abnormal morphology and thus do not fulfil the metabolic demands of the growing tumor mass. Due to the chaotic and heterogeneous tumor microcirculation, a hostile tumor microenvironment develops, that is characterized inter alia by local hypoxia, which in turn can stimulate the HIF-system. The latter can lead to tumor progression and may be involved in hypoxia-mediated radioresistance of tumor cells. Herein, cellular and molecular mechanisms in tumor angiogenesis are discussed that, among others, might impact hypoxia-related radioresistance.

Protoporphyrin IX fluorescence and photobleaching during interstitial photodynamic therapy of malignant gliomas for early treatment prognosis

BACKGROUND AND OBJECTIVE

Interstitial photodynamic therapy (iPDT) of non-resectable recurrent glioblastoma using 5-aminolevulinic acid (ALA)-induced protoporphyrin IX (PpIX) has shown a promising outcome. It remained unclear, however, to what extent inter- and intra-tumoural differences of PpIX concentrations influence the efficacy of iPDT. In the current pilot study, we analysed PpIX concentrations quantitatively and assessed PpIX induced fluorescence and photobleaching intraoperatively.

MATERIALS AND METHODS

Five patients harbouring non-resectable glioblastomas were included. ALA (20 or 30 mg/kg body weight) was given 5-8 hours before treatment. Stereotactic biopsies were taken throughout the tumour volume for both histological analysis and determination of PpIX concentrations, which were measured by chemical extraction. Cylindrical light diffusors were stereotactically implanted. Prior to and after irradiation, fluorescence measurements were performed. Outcome measurement was based on clinical and neuro-radiological follow up.

RESULTS

In three patients, a strong PpIX fluorescence was seen before treatment, which was completely photobleached after iPDT. High concentrations of PpIX could be detected in viable tumour parts of these patients (mean PpIX uptake per tumour: 1.4-3.0 µM). In the other two patients, however, no or only low PpIX uptake (0-0.6 µM) could be detected. The patients with strong PpIX uptake showed treatment response and long-term clinical stabilisation (no progression in 29, 30 and 36 months), early treatment failure was seen in the remaining two patients (death after 3 and 9 months).

CONCLUSIONS

Intra-tumoural PpIX concentrations exhibited pronounced inter- and intra-tumoural variations in glioblastoma, which are directly linked to variable degrees of fluorescence intensity. High intra-tumoural PpIX concentrations with strong fluorescence intensity and complete photobleaching after iPDT seem to be associated with favourable outcome. Real-time monitoring of PpIX fluorescence intensity and photobleaching turned out to be feasible and safe and might be employed for early treatment prognosis of iPDT.

Unfolded protein response activation contributes to chemoresistance in hepatocellular carcinoma

OBJECTIVE

Hepatocellular carcinoma (HCC) has an annual worldwide incidence of 626 000 cases and causes 550 000 deaths per year. Although the mainstay of treatment is surgical resection, for inoperable or metastatic disease, chemotherapy may be offered. The primary agent used is doxorubicin, but response rates are poor (<20%). The unfolded protein response (UPR) is a cytoprotective cellular stress response that enables cells to survive periods of hypoxia and nutrient deprivation. The UPR may confer resistance to anticancer agents and contribute to treatment failure. This study has investigated whether the UPR is activated in HCC and whether this may contribute to doxorubicin resistance.

METHODS

Eighty-six human HCCs were immunohistochemically stained for glucose regulated protein 78, the key marker of UPR activation. An in-vitro model of UPR activation in HepG2 HCC cells was developed by glucose deprived culture. UPR activation was confirmed with western blotting and PCR to show overexpression of glucose regulated protein 78. The relative efficacy of doxorubicin chemotherapy on UPR-activated HepG2 cells was compared with normal HepG2 cells by use of an thiazolyl blue tetrazolium bromide colorimetric assay.

RESULTS

Expression of glucose regulated protein 78 was shown in 100% of the HCC samples with 66% showing strong staining. In-vitro UPR activation was achieved with glucose deprivation. UPR activation induced significant resistance to doxorubicin: 34% survival under standard culture conditions versus 58% and 63% for UPR-activated cells in 0.5 and 1 mmol glucose respectively (P=0.00928).

CONCLUSION

The UPR is activated in HCCs and confers resistance to chemotherapy in vitro. UPR activation may contribute to HCC chemoresistance.

Pathophysiological and vascular characteristics of tumours and their importance for hyperthermia: heterogeneity is the key issue

Tumour blood flow before and during clinically relevant mild hyperthermia exhibits pronounced heterogeneity. Flow changes upon heating are not predictable and are both spatially and temporally highly variable. Flow increases may result in improved heat dissipation to the extent that therapeutically relevant tissue temperatures may not be achieved. This holds especially true for tumours or tumour regions in which flow rates are substantially higher than in the surrounding normal tissues. Changes in tumour oxygenation tend to reflect alterations in blood flow upon hyperthermia. An initial improvement in the oxygenation status, followed by a return to baseline levels (or even a drop to below baseline at high thermal doses) has been reported for some tumours, whereas a predictable and universal occurrence of sustained increases in O(2) tensions upon mild hyperthermia is questionable and still needs to be verified in the clinical setting. Clarification of the pathogenetic mechanisms behind possible sustained increases is mandatory. High-dose hyperthermia leads to a decrease in the extracellular and intracellular pH and a deterioration of the energy status, both of which are known to be parameters capable of acting as direct sensitisers and thus pivotal factors in hyperthermia treatment. The role of the tumour microcirculatory function, hypoxia, acidosis and energy status is complex and is further complicated by a pronounced heterogeneity. These latter aspects require additional critical evaluation in clinically relevant tumour models in order for their impact on the response to heat to be clarified.

Recent progress towards development of effective systemic chemotherapy for the treatment of malignant brain tumors

Systemic chemotherapy has been relatively ineffective in the treatment of malignant brain tumors even though systemic chemotherapy drugs are small molecules that can readily extravasate across the porous blood-brain tumor barrier of malignant brain tumor microvasculature. Small molecule systemic chemotherapy drugs maintain peak blood concentrations for only minutes, and therefore, do not accumulate to therapeutic concentrations within individual brain tumor cells. The physiologic upper limit of pore size in the blood-brain tumor barrier of malignant brain tumor microvasculature is approximately 12 nanometers. Spherical nanoparticles ranging between 7 nm and 10 nm in diameter maintain peak blood concentrations for several hours and are sufficiently smaller than the 12 nm physiologic upper limit of pore size in the blood-brain tumor barrier to accumulate to therapeutic concentrations within individual brain tumor cells. Therefore, nanoparticles bearing chemotherapy that are within the 7 to 10 nm size range can be used to deliver therapeutic concentrations of small molecule chemotherapy drugs across the blood-brain tumor barrier into individual brain tumor cells. The initial therapeutic efficacy of the Gd-G5-doxorubicin dendrimer, an imageable nanoparticle bearing chemotherapy within the 7 to 10 nm size range, has been demonstrated in the orthotopic RG-2 rodent malignant glioma model. Herein I discuss this novel strategy to improve the effectiveness of systemic chemotherapy for the treatment of malignant brain tumors and the therapeutic implications thereof.

Detection and characterization of tumor hypoxia using pO2 histography

Data from 125 studies describing the pretreatment oxygenation status as measured in the clinical setting using the computerized Eppendorf pO2 histography system have been compiled in this article. Tumor oxygenation is heterogeneous and severely compromised as compared to normal tissue. Hypoxia results from inadequate perfusion and diffusion within tumors and from a reduced O2 transport capacity in anemic patients. The development of tumor hypoxia is independent of a series of relevant tumor characteristics (e.g., clinical size, stage, histology, and grade) and various patient demographics. Overall median pO2 in cancers of the uterine cervix, head and neck, and breast is 10 mm Hg with the overall hypoxic fraction (pO2 <or= 2.5 mm Hg) being approx. 25%. Metastatic lesions do not substantially deviate from the oxygenation status of (their) primary tumors. Whereas normal tissue oxygenation is independent of the hemoglobin level over the range of 8-15 g/dL, hypoxia is more pronounced in anemic patients and above this range in some cancers. Identification of tumor hypoxia may allow an assessment of a tumor's potential to develop an aggressive phenotype or acquired treatment resistance, both of which lead to poor prognosis. Detection of hypoxia in the clinical setting may therefore be helpful in selecting high-risk patients for individual and/or more intensive treatment schedules.

[Perfusion measurement using the T2* contrast media dynamics in neuro-oncology. Physical basics and clinical applications]

Perfusion imaging in the central nervous system (CNS) is mostly performed using the first-pass dynamic susceptibility-weighted contrast-enhanced (DSC) MRI. The first-pass of a contrast bolus in brain tissue is monitored by a series of T2*-weighted MR images. The susceptibility effect of the paramagnetic contrast agent leads to a signal loss that can be converted, using the principles of the indicator dilution theory, into an increase of the contrast agent concentration. From these data, parameter maps of cerebral blood volume (CBV) and flow (CBF) can be derived. Regional CBF and CBV values can be obtained by region-of-interest analysis. This review article describes physical basics of DSC MRI and summarizes the literature of DSC MRI in neurooncological issues.Studies, all with relatively limited patient numbers, report that DSC MRI is useful in the preoperative diagnosis of gliomas, CNS-lymphomas, and solitary metastases, as well as in the differentiation of these neoplastic lesions from infections and tumor-like manifestations of demyelinating disease. Additionally, DSC MRI is suitable for determining glioma grade and regions of active tumor growth which should be the target of stereotactic biopsy. After therapy, DSC MRI helps better assessing the tumor response to therapy, residual tumor after therapy, and possible treatment failure and therapy-related complications, such as radiation necrosis. The preliminary results show that DSC MRI is a diagnostic tool depicting regional variations in microvasculature of normal and diseased brains.

Importance of hypoxia in the biology and treatment of brain tumors

The resistance of gliomas to treatment with radiation and antineoplastic drugs may result in part from the effects of the extensive, severe hypoxia that is present in these tumors. It is clear that brain tumors contain extensive regions in which the tumor cells are subjected to unphysiological levels of hypoxia. Hypoxic cells are resistant to radiation. Hypoxia and the perfusion deficits and metabolic changes that accompany hypoxia in vivo also produce resistance to many commonly used anticancer drugs. The resistance of cells that are hypoxic at the time of therapy may influence the efficacy of the treatment of these tumors with radiation, chemotherapy, and combined modality regimens. Moreover, it is becoming increasingly evident from laboratory studies that exposure of cells to adverse microenvironments produces transient changes in gene expression, induces mutations, and selects for cells with altered genotypes, thus driving the evolution of the cell population toward increasing malignancy and increasingly aggressive phenotypes. Hypoxia may therefore be involved in the evolution of cells in low-grade malignancies to the resistant, aggressive phenotype characteristic of glioblastomas. During the past 50 years, many attempts have been made to circumvent the therapeutic resistance induced by hypoxia, by improving tumor oxygenation, by using oxygen-mimetic radiosensitizers, by adjuvant therapy with drugs that are preferentially toxic to hypoxic cells, by using hyperthermia, or by devising radiation sources and regimens that are less affected by hypoxia. Past clinical trials have provided tantalizing suggestions that the outcome of therapy can be improved by many of these approaches, but none has yet produced a significant, reproducible improvement in the therapeutic ratio, which would be needed for any of these approaches to become the standard therapy for these diseases. Several ongoing clinical trials are addressing other, hopefully better regimens; it will be interesting to see the results of these studies.

Quantitative analysis of varying profiles of hypoxia in relation to functional vessels in different human glioma xenograft lines

Tissue oxygenation influences the radiation response of tumors. To further investigate the underlying mechanisms of tumor hypoxia, the spatial distribution of hypoxic cells in relation to the vasculature was studied. In a panel of three human glioma xenograft lines (E2, E102, E106) with different growth characteristics, tumor line-specific patterns of hypoxia (pimonidazole) and (functional) vasculature (Hoechst 33342) were observed. Two of the three glioma lines showed a more homogeneous distribution of perfused vessels (E102 and E106) than the third glioma line (E2). Although all tumors showed hypoxia, the distance at which the steepest part of the gradient of the hypoxia marker was found varied significantly among the different glioma lines. The faster-growing E102 tumors had the longest distance (>300 microm). These results indicate that tumor line-specific factors, rather than vascular geometry alone, may determine the oxygenation status of a tumor. As a consequence, vascular density cannot be used as a surrogate parameter for tumor hypoxia when comparing different tumors. Additional hypoxia and perfusion markers will further improve our understanding of changes in tumor physiology at the microregional level explaining the relationship between the low oxygen levels and the response of tumors to treatment.

Hypoxia in a human intracerebral glioma model

OBJECT

The development of hypoxia in human gliomas is closely related to functional vasculature and the presence of hypoxia has important biological and therapeutic consequences. Assessment of hypoxia is necessary to understand its role in treatment response and to evaluate treatment strategies to improve tumor oxygenation. In this study, the authors report findings of their analysis of the degree of hypoxia in relation to other vascular parameters in a human intracerebral glioma xenograft.

METHODS

In sections of tumor, hypoxic regions were identified immunohistochemically by using the hypoxic marker pimonidazole. The S-phase marker bromodeoxyuridine was used to detect cell proliferation, and the perfusion marker Hoechst 33342 was used to delineate perfused vessels. Vascular structures were stained with an endothelial marker. Hypoxic tumor regions were clearly present in this human intracerebral glioma model. Hypoxic areas were usually found in nonperfused regions, whereas tumor cell proliferation was especially marked in perfused tumor areas. Furthermore, by using in situ hybridization the authors identified infiltrating tumor cells in the normal brain. This feature is often observed in gliomas in patients.

CONCLUSIONS

This model is a representative human glioma model that provides the researcher with the opportunity to analyze the relationship between the degree of hypoxia and vascular parameters, as well as to examine the effects of treatments aimed at modification of the oxygenation status of a tumor.

Antiangiogenic therapy in brain tumor models

The prognosis of patients with malignant brain tumors remains poor despite new developments in neurosurgery, chemotherapy and radiotherapy. Malignant gliomas are highly vascularized, and there is ample evidence that their growth is angiogenesis-dependent. Therefore, new therapeutic approaches often include the inhibition of angiogenesis. In this review, experimental studies of antiangiogenic agents in brain tumor models are summarized. The results of these experiments as well as potential pitfalls in extrapolation to the clinic are discussed.

Positron emission tomography in patients with primary CNS lymphomas

This article reviews possible clinical applications of positron emission tomography (PET) in patients with CNS lymphomas. PET allows quantitative assessment of brain tumor pathophysiology and biochemistry in vivo. Therefore, it provides different information about tumors when compared to histological or neuroradiological methods. In a diagnostic setting, PET cannot differentiate between primary lymphomas of the CNS, brain secondaries, or malignant gliomas, since various brain tumors share biochemical alterations. In HIV patients with contrast-enhancing brain tumors, however, data from the literature suggest that PET with the tracer F-18 fluoro-deoxyglucose may help to discriminate neoplastic (CNS lymphoma) from inflammatory (e.g. toxoplasmosis) lesions. Assuming that tumor biochemistry is highly abnormal in the most malignant parts of tumors, PET may also assist in defining targets for stereotactic biopsy. With regard to treatment evaluation, the prediction of individual treatment response is among the most challenging clinical applications of PET. On the one hand, this could be achieved on the basis of measures like tumor perfusion, oxygen consumption, or hypoxia. On the other hand, PET tracer methods may allow to quantify the expression of gene products following gene therapy. However, in CNS lymphoma patients these topics have yet not been addressed with PET.

Vasculature and microenvironmental gradients: the missing links in novel approaches to cancer therapy?

This paper illustrates how the concept of the malignant cell per se as the prime and only target in cancer therapy may be erroneous. The micro-vasculature evoked to satisfy nutritional requirements of solid tumors, and the inadequacy of this nutrition for all tumor cells, provide novel targeting concepts. The vascular architecture and the microenvironmental gradients (VAMP) will differ from one tumor to another and may determine whether current therapies succeed or fail. Many agents have a different toxicity or mode of action at the pathophysiological oxygen tensions that prevail in solid tumors. This warrants more attention. The hypoxic cell or the immature proliferating endothelial cell may provide tumor specificity that is more general than, and greater than, that conferred by the process of malignant transformation. The poor vasculature of solid tumors is often regarded as a problem by the oncologist. It limits the access of cytotoxic drugs, monoclonal antibodies, cytokines, etc. It also leads to hypoxic radioresistance because of diffusion limited chronic hypoxia and perfusion limited intermittent hypoxia, resulting from transient vessel closure. However, it can also be seen as a potential target, since prolonged vessel occlusion can lead to an avalanche of cell death. Strategies to prevent further expansion of the vascular network (anti-angiogenesis) should stabilize tumors and prevent further growth. Vascular targeting, aiming to damage the microvascular function and cause occlusion, can lead to extensive cell death. The target may relate to the excessive proliferation of endothelial cells in tumors or to abnormal functional aspects, such as altered cell shape (influencing permeability) adhesiveness to leukocytes or steps in the coagulation cascade. These microvascular features and microenvironmental gradients, and the phenotypic consequences of them, have been relatively neglected. The altered milieu and inadequate neovasculature is a common feature of all types of solid tumor, whereas the genetic changes that can give rise to a malignancy are very variable, from tumor site to site and even within a site from individual to individual. It seems, therefore, that therapies that could be of widespread general applicability might more easily be found from the micro-environmental or anti-vascular approaches than from gene therapy targeted at specific oncogenes. This approach will require cross fertilisation between scientists from quite disparate backgrounds, whose paths seldom cross, and who may not read, or even scan, each other's literature. If the endothelium or the low oxygen tension in subsets of tumor cells are the key to successful cancer treatment in mice, there are considerable implications for screening methods in vitro and for predictive and prognostic tests made on homogenized tumor samples.

Delayed vascular changes after antiangiogenic therapy with antivascular endothelial growth factor antibodies in human glioma xenografts in nude mice

OBJECTIVE

The purpose of this study was to examine the delayed effects of antivascular endothelial growth factor treatment on tumor growth and vascularity in a subcutaneous mouse tumor model of human glioblastoma.

METHODS

Antivascular endothelial growth factor antibody treatment was administered for a period of 6 weeks, to suppress tumor growth. To detect late vascular effects, tumor vascular parameters for treated tumors and control tumors were analyzed 4 weeks thereafter. By that time, tumors had grown to adequate sizes (diameter, 8-10 mm) for comparison with untreated control tumors. Vascular parameters were quantified by using an image-analysis system.

RESULTS

Vascular density was significantly lower in antivascular endothelial growth factor antibody-treated tumors, compared with control tumors of similar size. The vascular architecture of treated tumors was also distinctly different, compared with control tumors, showing larger but sparser vessel structures.

CONCLUSION

These findings suggest that antiangiogenic therapy may have a prolonged effect on the vascular architecture of certain tumors, resulting in enduring changes in the tumor vessels. Because tumor vasculature plays an important role in the sensitivity to various treatment modalities, these changes are likely to influence the responses of these tumors to further therapy.