High grade gliomas (HGGs) are the most frequent and highly invasive type of brain tumors, which arise from glial cells. Among HGGs, glioblastoma multiforme (GBM) is the commonest and deadliest tumor type. Standard HGG therapy that involves tumor resection followed by concomitant treatment with radiation exposure and temozolomide (TMZ) cannot prevent recurrent tumor. The median survival of treated patients after surgery does not exceed 1.5 years. Vaccination with autologous dendritic cells (DCs) pulsed with tumor-specific peptides, antigens, or lysates is considered as a promising option to induce a potent anti-tumor immune response and cytotoxicity against GBM cells. However, since the tumor microenvironment is highly immunosuppressive and immunotolerant, specialized approaches should be applied to protect DC transplants against tumor-induced functional impairment and inhibition. So far, many phase I-III clinical trials utilizing DC vaccines for HGG treatment were completed or are underway. In summary, DC vaccination was safe and well tolerated by patients. DC-induced anti-tumor immune responses correlated with prolonged overall and progression- free survival. Combination of DC therapy with other interventional strategies (i.e., radiotherapy, chemotherapy, antibodies, etc.) and multimodal approaches should improve HGG treatment outcomes. In this review, we consider strategies that provide an option to override the immune inhibitory tumor microenvironment and boost DC vaccine-based antitumor immune response.
Although new passive and active immunotherapy methods are emerging, unconjugated monoclonal antibodies remain the only kind of biological preparations approved for high-grade glioma therapy in clinical practice. In this review, we combine clinical and experimental data discussion. As antiangiogenic therapy is the standard of care for recurrent glioblastoma multiforme (GBM), we analyze major clinical trials and possible therapeutic combinations of bevacizumab, the most common monoclonal antibody to vascular endothelial growth factor (VEGF). Another humanized antibody to gain recognition in GBM is epidermal growth factor (EGFR) antagonist nimotuzumab. Other antigens (VEGF receptor, platelet-derived growth factor receptor, hepatocyte growth factor and c-Met system) showed significance in gliomas and were used to create monoclonal antibodies applied in different malignant tumors. We assess the role of genetic markers (isocitrate dehydrogenase, O6-methylguanine-DNA methyltransnsferase) in GBM treatment outcome prediction. Besides antibodies studied in clinical trials, we focus on perspective targets and briefly list other means of passive immunotherapy.
The aim of the study was to evaluate the relationship between tumor blood flow (TBF) measured by the pseudo-continuous arterial spin labeling (PCASL) method and IDH1 mutation status of gliomas as well as Ki-67 proliferative index. Methods. The study included 116 patients with newly diagnosed gliomas of various grades. They received no chemotherapy or radiotherapy before MRI. IDH1 status assessment was performed after tumor removal in 106 cases—48 patients were diagnosed with wildtype gliomas (Grade 1–2—6 patients, Grade 3–4—42 patients) and 58 patients were diagnosed with mutant forms of gliomas (Grade 1–2—28 patients, Grade 3–4—30 patients). In 64 cases out of 116 Ki-67 index was measured. Absolute and normalized tumor blood flow values were measured on 3D PCASL maps. Results. TBF and normalized TBF (nTBF) in wildtype gliomas were significantly higher than in IDH1-mutant gliomas (p < 0.001). ASL perfusion showed high values of sensitivity and specificity in the differential diagnosis of gliomas with distinct IDH1 status (for TBF: specificity 75%, sensitivity 77.6%, AUC 0.783, cutoff 80.57 mL/100 g/min, for nTBF: specificity 77.1%, sensitivity 79.3%, AUC 0.791, cutoff 4.7). TBF and nTBF in wildtype high-grade gliomas (HGG) were significantly higher than in mutant forms (p < 0.001). ASL perfusion showed the following values of sensitivity and specificity in the diagnosis of mutant HGG and wildtype HGG (for TBF: specificity 83.3%, sensitivity 60%, AUC 0.719, cutoff 84.18 mL/100 g/min, for nTBF: specificity 88.1%, sensitivity 60%, AUC 0.729, cutoff 4.7). There was a significant positive correlation between tumor blood flow and Ki-67 (for TBF Rs = 0.63, for nTBF Rs = 0.61). Conclusion. ASL perfusion may be an informative factor in determining the IDH1 status in brain gliomas preoperative and tumor proliferative activity.
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