Purpose: Dysfunctional tumor vessels can be a significant barrier to effective cancer therapy.However, increasing evidence suggests that vascular endothelial growth factor (VEGF) inhibition can effect transient ''normalization''of the tumor vasculature, thereby improving tumor perfusion and, consequently, delivery of systemic chemotherapy. We sought to examine temporal changes in tumor vascular function in response to the anti-VEGF antibody, bevacizumab. Experimental Design: Established orthotopic neuroblastoma xenografts treated with bevacizumab were evaluated at serial time points for treatment-associated changes in intratumoral vascular physiology, penetration of systemically administered chemotherapy, and efficacy of combination therapy. Results: After a single bevacizumab dose, a progressive decrease in tumor microvessel density to <30% of control was observed within 7 days. Assessment of the tumor microenvironment revealed a rapid, sustained decrease in both tumor vessel permeability and tumor interstitial fluid pressure, whereas intratumoral perfusion, as assessed by contrast-enhanced ultrasonography, was improved, although this latter change abated by 1week. Intratumoral drug delivery mirrored these changes; penetration of chemotherapy was improved by as much as 81% when given 1to 3 days after bevacizumab, compared with when both drugs were given concomitantly, or 7 days apart. Finally, administering topotecan to tumor-bearing mice 3 days after bevacizumab resulted in greater tumor growth inhibition (36% of control size) than with monotherapy (88% bevacizumab, 54% topotecan) or concomitant administration of the two drugs (44%). Conclusions: Bevacizumab-mediated VEGF blockade effects alterations in tumor vessel physiology that allow improved delivery and efficacy of chemotherapy, although careful consideration of drug scheduling is required to optimize antitumor activity.
Purpose
Ionizing radiation, an important component of glioma therapy, is critically dependent on tumor oxygenation. However, gliomas are notable for areas of necrosis and hypoxia, which foster radioresistance. We hypothesized that pharmacologic manipulation of the typically dysfunctional tumor vasculature would improve intratumoral oxygenation and, therefore, the anti-glioma efficacy of ionizing radiation.
Methods and Materials
Orthotopic U87 xenografts were treated with either continuous interferon-beta (IFN-β) or bevacizumab, alone, or in combination with cranial irradiation (RT). Tumor growth was assessed by quantitative bioluminescence imaging; tumor vasculature, with immunohistochemical staining; and tumor oxygenation, with hypoxyprobe staining.
Results
Both IFN-β and bevaziumab profoundly affected the tumor vasculature, albeit with different cellular phenotypes. IFN-β caused a doubling in the percent area of perivascular cell staining while bevacizumab caused a rapid decrease in the percent area of endothelial cell staining. However, both agents increased intratumoral oxygenation, although with bevacizumab the effect was transient, being lost by five days. Administration of IFN-β or bevacizumab prior to RT was significantly more effective than any of the three modalities as monotherapy or when RT was administered concomitantly with IFN-β or bevacizumab, or five days after bevacizumab.
Conclusions
Bevacizumab and continuous delivery of IFN-β each induced significant changes in glioma vascular physiology, improving intratumoral oxygenation and enhancing the anti-tumor activity of ionizing radiation. Further investigation into the use and timing of these and other agents that modify vascular phenotype, in combination with radiation, is warranted in order to optimize cytotoxic activity.
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