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Vascular dysfunction promotes regional hypoxia after bevacizumab therapy in recurrent glioblastoma patients

Elizabeth R. Gerstner, Kyrre E. Emblem, Yi‐Fen Yen, Jörg Dietrich, Justin T. Jordan, Ciprian Catana, Kevin Lou Wenchin, Jacob M. Hooker, Dan G. Duda, Bruce R. Rosen, Jayashree Kalpathy–Cramer, Rakesh K Jain, Tracy T. Batchelor

2020Neuro-Oncology Advances17 citationsDOIOpen Access PDF

Abstract

BACKGROUND: Hypoxia is a driver of treatment resistance in glioblastoma. Antiangiogenic agents may transiently normalize blood vessels and decrease hypoxia before excessive pruning of vessels increases hypoxia. The time window of normalization is dose and time dependent. We sought to determine how VEGF blockade with bevacizumab modulates tumor vasculature and the impact that those vascular changes have on hypoxia in recurrent glioblastoma patients. METHODS: F]FMISO PET-MRI. We also examined serial changes in plasma biomarkers of angiogenesis and inflammation. RESULTS: Eleven patients were studied. The magnitude of global tumor hypoxia was variable across these 11 patients prior to treatment and it did not significantly change after bevacizumab. The hypoxic regions had an inefficient vasculature characterized by elevated cerebral blood flow/volume and increased vessel caliber. In a subset of patients, there were tumor subregions with decreased mean transit times and a decrease in hypoxia, suggesting heterogeneous improvement in vascular efficiency. Bevacizumab significantly changed known pharmacodynamic biomarkers such as plasma VEGF and PlGF. CONCLUSIONS: The vascular signature in hypoxic tumor regions indicates a disorganized vasculature which, in most tumors, does not significantly change after bevacizumab treatment. While some tumor regions showed improved vascular efficiency following treatment, bevacizumab did not globally alter hypoxia or normalize tumor vasculature in glioblastoma.

Topics & Concepts

BevacizumabHypoxia (environmental)MedicineTumor hypoxiaAngiogenesisVascular endothelial growth factorPathologyVascular permeabilityNeovascularizationCerebral blood flowInternal medicineChemotherapyRadiation therapyVEGF receptorsChemistryOxygenOrganic chemistryCancer, Hypoxia, and MetabolismAngiogenesis and VEGF in CancerGlioma Diagnosis and Treatment
Vascular dysfunction promotes regional hypoxia after bevacizumab therapy in recurrent glioblastoma patients | Litcius