Abstract
High-grade gliomas are often characterized by hypoxia, which is associated with both poor long-term prognosis and therapy resistance. The adverse role hypoxia plays in treatment resistance and disease progression has led to the development of hypoxia imaging methods and hypoxia-targeted treatments. Here, we determined the tumor hypoxia and vascular perfusion characteristics of 2 rat orthotopic glioma models using 18-fluoromisonidozole positron emission tomography. In addition, we determined tumor response to the hypoxia-activated prodrug evofosfamide (TH-302) in these rat glioma models. C6 tumors exhibited more hypoxia and were less perfused than 9L tumors. On the basis of these differences in their tumor hypoxic burden, treatment with evofosfamide resulted in 4- and 2-fold decreases in tumor growth rates of C6 and 9L tumors, respectively. This work shows that imaging methods sensitive to tumor hypoxia and perfusion are able to predict response to hypoxia-targeted agents. This has implications for improved patient selection, particularly in clinical trials, for treatment with hypoxia-activated cytotoxic prodrugs, such as evofosfamide.
Highlights
Glioblastoma is the most common type of primary malignant brain tumor
As hypoxia levels in C6 tumors are expected to be proportional to the tumor size [27], we further investigated the role of tumor size on both perfusion and hypoxia in cohort 1 and on treatment efficacy in cohort 2
Acute hypoxia is associated with abnormal tissue microvasculature and is highly unpredictable
Summary
Despite advances in detection and treatment, the prognosis remains poor for patients with glioma with median survival time of only 12–15 months [1]. But viable, cells can be noninvasively probed with 18-fluoromisonidozole positron emission tomography (18F-FMISO-PET; chemical structure in Figure 1A) [6,7,8], and the uptake of 18F-FMISO has been found to inversely correlate with overall survival in patients with glioblastoma [7, 9]. Using a separate marker for perfusion, Bruehlmeier showed that hypoxia occurs in regions of both hypo- and hyperperfusion [6], suggesting that an independent process leads to a hypoxic phenotype. 18F-FMISO-PET imaging can provide a relative measure of perfusion (tracer delivery) using a dynamic scan [6, 10, 11]
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