Effect of VEGF receptor-2 antibody on vascular function and oxygenation in spontaneous and transplanted tumors.

BACKGROUND AND PURPOSE: The primary objectives of this study were to address two major questions. (1) Does VEGF receptor-2 antibody (DC101) produce detrimental effects on tumor vascular function and oxygenation that could compromise adjuvant therapies? (2) Is pathophysiological response to such antiangiogenic strategies different in transplanted versus primary spontaneous tumors? MATERIALS AND METHODS: The effects of early and late initiation DC101 treatment were evaluated using spontaneous murine mammary carcinomas and two markedly different transplanted mammary tumors, MCa-35 and MCa-4. Mice were administered DC101 or saline, tumors were frozen, and immunohistochemical staining was quantified using image analysis of multiply-stained frozen sections. Total blood vessels were identified using antibodies to CD31 or panendothelial antigen, perfused vessels via i.v. injection of fluorescent DiOC7, and tumor hypoxia by hypoxia marker (EF5) uptake. RESULTS: Tumor growth was significantly inhibited following DC101 administration in all tumor models. In general, early initiation DC101 treatment reduced perfused vessel counts and increased tumor hypoxia, while late initiation treatment had no significant impact on either. Results indicate that DC101 slows tumor growth through a decrease in vascular function, leading to increased tumor cell apoptosis and necrosis at sites distant from perfused blood vessels, and suggest that DC101 accelerates the rate at which tumor cells outgrow their functional vascular supply. CONCLUSIONS: Although highly variable among individual spontaneous tumors, the overall effects of DC101 on tumor hypoxia were quite similar between spontaneous and transplanted tumors. Since reductions in tumor oxygenation due to antiangiogenic treatment were transient, initial pathophysiological deficiencies that could compromise conventional therapies over the short-term may be of less relevance when administered over more extended treatment schedules.     

Pathophysiological effects of vascular endothelial growth factor receptor-2-blocking antibody plus fractionated radiotherapy on murine mammary tumors

Although clinical trials of antiangiogenic strategies have been disappointing when administered as single agents, such approaches can play an important role in cancer treatment when combined with conventional therapies. Previous studies have shown that DC101, an antiangiogenic monoclonal antibody against vascular endothelial growth factor receptor-2, can produce significant growth inhibition in spontaneous and transplanted tumors but can also induce substantial hypoxia. Because DC101 appears to potentiate radiotherapy in some tumors, the present studies were undertaken to characterize pathophysiological changes following combined therapy and to determine whether radioresponse is enhanced despite the induction of hypoxia. MCa-4 and MCa-35 mammary carcinomas were treated with: (a) DC101; (b) 5 x 6 Gy radiation fractions; or (c) the combination. Image analysis of frozen tumor sections was used to quantitate: (a) hypoxia; (b) spacing of total and perfused blood vessels; and (c) endothelial and tumor cell apoptosis. For MCa-4, combination treatment schedules produced significant and prolonged delays in tumor growth, whereas single-modality treatments had minor effects. For MCa-35, radiation or the combination led to equivalent growth inhibition. In all tumors, hypoxia increased markedly after either radiation or DC101 alone. Although combination therapy produced no immediate pathophysiological changes, hypoxia ultimately increased after cessation of therapy. Preferential increases in endothelial apoptosis following combination treatment suggest that in addition to blocking tumor angiogenesis, DC101 enhances radiotherapy by specifically sensitizing endothelial cells, leading to degeneration of newly formed blood vessels.     

Intratumoral administration of endostatin plasmid inhibits vascular growth and perfusion in MCa-4 murine mammary carcinomas

Endostatin, a fragment of the COOH-terminal domain of mouse collagen XVIII is a recently demonstrated endogenous inhibitor of tumor angiogenesis and endothelial cell growth. Antiangiogenic therapy with endostatin in animals requires multiple and prolonged administration of the protein. Gene therapy could provide an alternative approach to continuous local delivery of this antiangiogenic factor in vivo. Established MCa-4 murine mammary carcinomas, grown in immunodeficient mice, were treated with intratumoral injection of endostatin plasmid at 7-day intervals. At the time of sacrifice, 14 days after the first injection, endostatin-treated tumor weights were 51% of controls (P < 0.01). Tumor growth inhibition was accompanied by a marked reduction in total vascular density. Specifically, computerized image analysis showed a 18-21% increase in the median distances between tumor cells and both the nearest anatomical (CD31-stained) vessel [48.1 +/- 3.8 versus 38.3 +/- 1.6 microm (P < 0.05)] and the nearest tumor-specific (CD105-stained) vessel [48.5 +/- 1.5 versus 39.8 +/- 1.5 microm (P < 0.01)]. An increased apoptotic index of tumor cells in endostatin-treated tumors [3.2 +/- 0.5% versus 1.9 +/- 0.3% (P < 0.05)] was observed in conjunction with a significant decrease in tumor perfused vessels (DiOC7 staining), and an increase in tumor cell hypoxia (EF5 staining). Hypoxia resulting from endostatin therapy most likely caused a compensatory increase of in situ vascular endothelial growth factor (VEGF) and VEGF receptor mRNA expression. Increased immunoreactivity of endostatin staining in endostatin-treated tumors was also associated with an increased thrombospondin-1 staining [1.12 +/- 0.16 versus 2.44 +/- 0.35]. Our data suggest that intratumoral delivery of the endostatin gene efficiently suppresses murine mammary carcinoma growth and support the potential utility of the endostatin gene for cancer therapy.     

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.     

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.     

Endostatin improves radioresponse and blocks tumor revascularization after radiation therapy for A431 xenografts in mice

PURPOSE: Clinical trials of antiangiogenic agents used alone for advanced malignancy have been disappointing but preclinical studies suggest that the addition of radiation therapy could improve antitumor efficacy. To test the hypothesis that antiangiogenic therapy combined with radiation therapy can overcome the limitations of antiangiogenic monotherapy, we studied the effects of endostatin combined with radiation on the growth and vascularization of A431 human epidermoid carcinomas growing intramuscularly in the legs of mice. METHODS AND MATERIALS: Mice with established A431 human epidermoid leg tumors were treated with radiation, endostatin, both radiation and endostatin, or vehicle control. The experiment was repeated and mice from each group were killed at 2, 7, and 10 days after irradiation so that tumor tissue could be obtained to further analyze the kinetics of the antitumor, antivascular, and antiangiogenic response to therapy. RESULTS: Endostatin enhanced the antitumor effects of radiation, and prolonged disease-free survival was observed in the combined treatment group. Endothelial cell proliferation was increased in tumors after irradiation but was blocked by the concurrent administration of endostatin, and the combination of endostatin with radiation enhanced endothelial cell apoptosis within 48 h after irradiation. Expression of vascular endothelial growth factor, interleukin-8, and matrix metalloproteinase-2 were increased in tumors after irradiation, and this increase was blocked by concurrent administration of endostatin. CONCLUSION: These data indicate that endostatin can block tumor revascularization after radiation therapy and thereby augment radioresponse.     

Combination of radiation and celebrex (celecoxib) reduce mammary and lung tumor growth

The selective cyclooxygenase (COX)-2 inhibitor, celecoxib, alone and in combination with radiation was investigated in vitro and in vivo. Murine mammary tumor line (MCa-35) and human lung carcinoma line (A549) have high and low basal levels of COX-2 protein, respectively. Treatment of both tumor cells with celecoxib alone resulted in a dose- and time-dependent reduction of cell number (clonogenic cell death) and tumor cell growth rate in vitro; however, inhibition of tumor cell growth by celecoxib was not correlated with the reduction of COX-2 protein in tumor cells. Although both tumor cell types had similar DNA damage after celecoxib treatment, significant induction of tumor cell apoptosis was only observed in MCa-35. Celecoxib-mediated radiation sensitization also occurred in MCa-35 cells determined by clonogenic assay, in part due to a G2/M arrest at 8 to 24 hours after treatment. The tumor growth inhibitory effects of celecoxib were also studied in vivo. It was found that celecoxib inhibited both tumor growth after intragastric administration of celecoxib (5 daily doses of 50 mg/kg). Combined with a single 30-Gy dose of radiation, celecoxib resulted in additive effects on A549 tumors. Celecoxib-treated A549 tumors had marginal reduction of total and perfused blood vessels compared with untreated controls. Reduction of tumor angiogenic cytokine and growth factor mRNA was associated with decreased perfused vessels. Finally, reduction of vascular endothelial growth factor protein after celecoxib was also observed in both tumor lines by Western blot. Our results indicate that the selective inhibition of COX-2 combined with radiation has potential application in radiotherapy, and celecoxib-mediated antitumor effects may act through different mechanisms including direct inhibition of tumor cell proliferation, alteration of tumor cell cycle, and antiangiogenesis.     

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 DiOC(7) 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.     

The addition of AG-013736 to fractionated radiation improves tumor response without functionally normalizing the tumor vasculature

Although antiangiogenic strategies have proven highly promising in preclinical studies and some recent clinical trials, generally only combinations with cytotoxic therapies have shown clinical effectiveness. An ongoing question has been whether conventional therapies are enhanced or compromised by antiangiogenic agents. The present studies were designed to determine the pathophysiologic consequences of both single and combined treatments using fractionated radiotherapy plus AG-013736, a receptor tyrosine kinase inhibitor that preferentially inhibits vascular endothelial growth factor receptors. DU145 human prostate xenograft tumors were treated with (a) vehicle alone, (b) AG-013736, (c) 5x2 Gy/wk radiotherapy fractions, or (d) the combination. Automated image processing of immunohistochemical images was used to determine total and perfused blood vessel spacing, overall hypoxia, pericyte/collagen coverage, proliferation, and apoptosis. Combination therapy produced an increased tumor response compared with either monotherapy alone. Vascular density progressively declined in concert with slightly increased alpha-smooth muscle actin-positive pericyte coverage and increased overall tumor hypoxia (compared with controls). Although functional vessel endothelial apoptosis was selectively increased, reductions in total and perfused vessels were generally proportionate, suggesting that functional vasculature was not specifically targeted by combination therapy. These results argue against either an AG-013736- or a combination treatment-induced functional normalization of the tumor vasculature. Vascular ablation was mirrored by the increased appearance of dissociated pericytes and empty type IV collagen sleeves. Despite the progressive decrease in tumor oxygenation over 3 weeks of treatment, combination therapy remained effective and tumor progression was minimal.     

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.     

Inverse relationship between epidermal growth factor receptor expression and radiocurability of murine carcinomas.

The study investigated whether a relationship exists between the extent of epidermal growth factor receptor (EGFR) expression and in vivo radiocurability of murine tumors. EGFR expression was determined in nine carcinomas (four mammary carcinomas, designated MCa-4, MCa-29, MCa-35, and MCa-K; two squamous cell carcinomas, designated SCC-IV and SCC-VII; an ovarian adenocarcinoma, OCa-I; a hepatocarcinoma, HCa-I; and an adenosquamous carcinoma, ACa-SG) syngeneic to C3Hf/Kam mice using Western blot analysis. These tumors greatly differed in their radioresponse, assessed by TCD50 assay, and in their susceptibility to radiation-induced apoptosis. Likewise, the expression of EGFR greatly varied, by as much as 21-fold, and the magnitude of the EGFR expression positively correlated with increased tumor radioresistance. The levels of EGFR inversely correlated with radiation-induced apoptosis, suggesting that the lack of sensitivity to apoptosis induction was a major mechanism responsible for radioresistance of tumors with high EGFR. This correlation was highly significant only for wild-type p53 carcinomas. Radiation activated EGFR autophosphorylation and increased the activity of protein tyrosine kinase, but only in tumors with high EGFR expression. Thus, EGFR expression was a major determinant of tumor radioresponse in vivo. The pretreatment assessment of EGFR expression could predict radiotherapy outcome and may assist in selecting an effective treatment modality.     

Intravital microscopy reveals novel antivascular and antitumor effects of endostatin delivered locally by alginate-encapsulated cells

The current study describes new, antivascular, and antitumor effects of human endostatin. A novel system for continuous, localized delivery of antiangiogenic compounds to brain tumors was used. The delivery system was composed of endostatin-producing 293 cells encapsulated into immuno-isolating sodium alginate. Intravital multifluorescence microscopy was used to assess vascular and antitumor effects of endostatin in C6 glioma spheroids implanted into an ectopic as well as an orthotopic setting. Analysis of total and functional vascular density, microvascular diameters, vessel perfusion, tumor growth, and tumor cell migration were performed repetitively. Tumor growth was reduced by 35% in treated animals. It was of interest that tumor cell invasion into the surrounding tissue was also inhibited. The total vascular density was reduced by 67.6%, perfusion by 67%, and vessel diameters by 37%. This resulted in a significant reduction in tumor perfusion, although the vessel permeability was not influenced. We have demonstrated that human endostatin not only reduces total vascular density, as shown previously, but also greatly reduces the functionality and the diameters of the vessels. Furthermore, we show that this therapeutic approach also inhibits tumor cell invasion, thus supporting the hypothesis that tumor angiogenesis and invasion represent two interrelated processes. Finally, this work further confirms the new therapeutic concept using alginate cell-encapsulation technology for the localized delivery of therapeutic compounds to central nervous system malignancies.     

Cancer vascularization: implications in radiotherapy?

PURPOSE: Although hypoxia is considered a major cause of failure of radiotherapy, the mechanisms of tumor hypoxia are unclear, and effective ways for its correction or targeting are missing. Tumoral vasculature is the vehicle for the hemoglobin to reach the tumoral stroma. Although anemia has long been focused on as an important parameter related to tumor hypoxia, differences in vascular density may also affect the intratumoral access of hemoglobin. METHODS AND MATERIALS: In the present study, we examined the vascular density in 1459 human carcinomas. The distribution of the vascular density within tumors was studied in 436 non-small-cell lung carcinomas and 298 breast carcinomas. RESULTS: The vascular density was found to vary up to 22-fold even among tumors of the same histology. Overall, the vascular density was significantly higher in the tumor periphery as compared to inner areas. Three different patterns of vascularization were identified in both lung and breast cancer specimens; (1) tumors with low or (2) tumors with high vessel density throughout the tissue section, and (3) tumors with high vessel density in the tumor periphery and low in inner areas. The death rate following surgery showed a direct association with the vascular density in lung, breast, colon, and endometrial cancer. In inoperable gastric cancer patients treated with chemotherapy, and in head and neck cancer patients treated with radical chemoradiotherapy there was a 'U-like' association of the death rate with the vascular density suggesting that very low (poor oxygen and drug availability) and very high (intensified angiogenic pathways) vascularization are both linked to poor outcome. CONCLUSION: The present study stresses the importance of the vascular density as a putative variable that may have affected the results of large clinical trials that investigated the role of anemia, hyperbaric oxygen, hypoxic sensitizers, or even of combined chemoradiotherapy in the outcome of radiation treatment.     

Molecular fingerprinting and autocrine growth regulation of endothelial cells in a murine model of hepatocellular carcinoma

In a mouse model of hepatocellular carcinogenesis, highly vascularized tumors develop through two distinct morphologic phases of neovascularization. We show that increased vascular caliber occurs first, followed by extensive vessel sprouting in late-stage carcinomas. To define molecular pathways in tumor neovascularization, endothelial cells were directly purified from normal liver and advanced tumors. Gene expression profiling experiments were then designed to identify genes enriched in the vascular compartment. We report that Cathepsin S is the major protease specifically overexpressed during vessel sprouting. We also show that the CC chemokines CCL2 and CCL3 are secreted by neovessels and stimulate proliferation through their cognate receptors in an autocrine fashion. This suggests that chemokine signaling represents the most prominent signaling pathway in tumor-associated endothelial cells and directly regulates vessel remodeling. Furthermore, high angiogenic activity is associated with attenuated lymphocyte extravasation and correlates with expression of the immunomodulatory cytokine interleukin 10. This is the first comprehensive study addressing liver-specific vascular changes in a murine autochthonous tumor model. These novel insights into liver angiogenesis infer an environmental control of neovascularization and have important implications for the design of antiangiogenic therapies.     

Tissue gradients of energy metabolites mirror oxygen tension gradients in a rat mammary carcinoma model.

PURPOSE: It has been shown that oxygen gradients exist in R3230AC tumors grown in window chambers. The fascial surface is better oxygenated than the tumor surface. The purpose of the present study was to determine whether gradients exist for energy metabolites and other end points related to oxygen transport. METHODS AND MATERIALS: Imaging bioluminescence was used to measure ATP, glucose, and lactate in cryosections of R3230AC tumors. Mean vessel density and hypoxic tissue fraction were assessed using immunohistochemistry. Tumor redox ratio was assessed by redox ratio scanning. RESULTS: Lactate content and hypoxic fraction increased, whereas ATP, glucose, redox ratio, and vessel density decreased from the fascial to the tumor surface. CONCLUSIONS: The data support a switch from aerobic to anaerobic metabolism concomitant with the PO2 gradient. The vascular hypoxia that exists in perfused vessels at the tumor surface leads to macroscopic tissue regions with restricted oxygen availability and altered metabolic status. Methods to reduce tumor hypoxia may have to take this into account if such gradients exist in human tumors. The results also have implications for hypoxia imaging, because macroscopic changes in PO2 (or related parameters) will be easier to see than PO2 gradients limited to the diffusion distance of oxygen.     

重组内皮抑素对肿瘤血管结构和乏氧改善作用的实验观察

目的 观察重组内皮抑素作用下小鼠Lewis肺癌移植瘤在血管退化前是否存在血管正常化时间窗,在此时间窗内肿瘤乏氧是否改善.方法 激光共聚焦显微镜动态观察重组内皮抑素作用下肿瘤血管的形态学变化,免疫组化染色检测不同时间段肿瘤乏氧细胞比例,观测肿瘤生长情况并绘制肿瘤生长曲线.结果 重组内皮抑素处理后肿瘤血管密度逐渐下降,连续治疗9 d较对照组下降最为明显.重组内皮抑素处理后周细胞覆盖内皮细胞比例逐渐增加,第3天开始明显增加,第5天增加最明显,第7天后明显下降.对照组基底膜与内皮细胞连接松散,厚度增加,而重组内皮抑素处理后,基底膜与内皮细胞连接紧密,厚度下降.在重组内皮抑素处理后第5天肿瘤乏氧细胞比例下降最明显,连续5 d用重组内皮抑素,肿瘤生长未见加快.结论 重组内皮抑素能使肿瘤血管正常化,其时间窗为治疗后3～7 d;此时肿瘤氧供明显改善,为临床联合应用放疗和重组内皮抑素提供了实验依据.

Abstract：

Objective To investigate whether recombinant human endostatin can create a time window of vascular normalization prior to vascular pruning to alleviate hypoxia in Lewis lung carcinoma in mice. Methods Kinetic changes in morphology of tumor vasculature in response to recombinant human endostatin were detected under a confocal microscope with immunofluorescent staining in Lewis lung carcinomas in mice. The hypoxic cell fraction of different time was assessed with immunohistochemical staining . Effects on tumor growth were monitored as indicated in the growth curve of tumors . Results Compared with the control group vascularity of the tumors was reduced over time by recombinant human endostatin treatment and significantly regressed for 9 days. During the treatment, pericyte coverage increased at day 3, increased markedly at day 5, and fell again at day 7. The vascular basement membrane was thin and closely associated with endothelial cells after recombinant human endostatin treatment, but appeared thickened, loosely associated with endothelial cells in control tumors. The decrease in hypoxic cell fraction at day 5 after treatment was also found. Tumor growth was not accelerated 5 days after recombinant human endostatin treatment. Conclusions Recombinant human endostatin can normalize tumor vasculature within day 3 to 7, leading to improved tumor oxygenation. The results provide important experimental basis for combining recombinant human endostatin with radiation therapy in human tumors.     

Microvessel density and vascular endothelial growth factor expression in human tumors of different localization

In order to study the angiogenic activity of individual human tumors, microvessel density and vascular endothelial growth factor (VEGF) expression were determined in 152 human tumors of different localization (lung, ovary, breast, colon/rectum, kidney) using immunohistochemistry. Considerable variability in vascular density has been noted between different tumors with the same histology as well as between tumors of different localization. Kidney and breast carcinomas exhibited significantly higher vessel counts than carcinomas of other localization (p<0.001). In most tumor types (lung, breast, ovarian, nephroblastoma) about two-thirds of the tumors expressed VEGF. In contrast, only 7 out of 20 colorectal carcinomas (35%) and 9 out of 20 kidney carcinomas (45%) and all small cell lung carcinomas (13/13) were positive for VEGF, despite a relatively low vascularity. These results indicate that each single tumor has its own pattern of vascularity and its variable expression of VEGF and that the individual determination of the degree of vascularization together with the assessment of one or more angiogenic peptides may provide valid information on the angiogenic activity of a tumor. This may lead to identification of those patients who are more likely to have benefit from antiangiogenic therapies.     

Microvascular architecture in a mammary carcinoma: branching patterns and vessel dimensions

The objective of this work was to introduce a tumor vessel classification scheme and to provide the first quantitative measurements of vessel branching patterns and the related vascular dimensions in a mammary carcinoma. Mammary adenocarcinoma R3230AC tumors, grown in the rat ovarian tissue-isolated tumor preparation, were infused with Batson's No. 17 polymer and maintained at an intravascular pressure of 50 mm Hg during polymerization. Maceration of the tumor in KOH allowed visualization of the vasculature. The vessel branching patterns, lengths, and diameters were measured in four tumors (4-5 g). A centrifugal ordering scheme was devised specifically to account for the unique features of tumor microvascular network topology. The arterial networks revealed two types of branching patterns. One type of arteriolar network exhibited decreasing vessel diameters and lengths with increasing branch order. In a second type of network, the diameter and length of the vessels displayed fluctuations in both variables at higher generations. Avascular and poorly vascularized regions with sparse capillary supply were present in the tumors, but analysis of several capillary networks in vascularized regions revealed a nonplanar meshwork of interconnected vessels. The meshworks were composed of vessels with a mean segment length of 67 microns, a mean diameter of 10 microns, and a mean intercapillary distance of 49 microns. Capillary path lengths ranged from 0.5 to 1.5 mm. Thus, tumor capillary diameter was greater than that in most normal tissues and, in the regions where capillary networks existed, intercapillary spacing was in the normal range. In the venous network, diameters decreased from 650 to 20 microns for the first to ninth order venules. Venule length decreased from 5 to 0.5 mm for first to fourth order but was fairly uniform (less than 500 microns) for higher orders. In conclusion, solid tumor vascular architecture, while exhibiting several features that are similar to those observed in normal tissues, has others that are not commonly seen in normal tissues. These features of the tumor microcirculation may lead to heterogeneous local hematocrits, oxygen tensions, and drug concentrations, thus reducing the efficacy of present day cancer therapies.     

Suramin Treatment of Human Glioma Xenografts; Effects on Tumor Vasculature and Oxygenation Status

In this study the effect of suramin on tumor growth, vascularity and oxygenation of a human glioma xenografted in the nude mouse was examined. Vascular parameters and oxygenation status of the xenografts were determined immunohistochemically in frozen sections of the tumors, using the hypoxia marker pimonidazole-hydrochloride to detect hypoxic areas. Tumor vessels in these sections were stained by an endothelial cell marker and perfusion of vessels was visualized by administration of the perfusion marker Hoechst 333342 before harvesting the tumors. The vascular parameters were quantified with an image analysis system. The results show that tumor growth was reduced considerably after suramin treatment. This growth suppression was accompanied by marked changes in vascular architecture. Although the total vascular area and perfused fraction of tumor vessels remained unchanged after suramin treatment, vascular density increased, indicating that more but smaller vessel structures had developed during therapy. These vessel structures were also more homogeneously spread over the tumor area. Control tumors showed extensive areas of hypoxia while in treated tumors hypoxic areas had mostly disappeared. This effect was probably due to the higher density of homogeneously distributed perfused vessel structures in the treated tumors, contributing to an increased oxygenation of the tumor. These observations suggest that suramin therapy can result in marked changes not only in tumor vascularity but also in tumor oxygenation status which may have important consequences for sensitivity of these tumors to other therapies such as radiation treatment.