1. Myoinositol as a Biomarker in Recurrent Glioblastoma Treated with Bevacizumab: A 1H-Magnetic Resonance Spectroscopy Study
- Author
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Ulrich Pilatus, Joachim P. Steinbach, Oliver Bähr, Eike Steidl, Michael W. Ronellenfitsch, Elke Hattingen, Friedhelm E. Zanella, and Isaac Chen, Han-Chiao
- Subjects
Oncology ,Male ,Vascular Endothelial Growth Factor A ,Pathology ,Magnetic Resonance Spectroscopy ,Cell Membranes ,Cancer Treatment ,lcsh:Medicine ,Angiogenesis Inhibitors ,Pathology and Laboratory Medicine ,Biochemistry ,Diagnostic Radiology ,chemistry.chemical_compound ,0302 clinical medicine ,Mathematical and Statistical Techniques ,Lomustine ,Medicine and Health Sciences ,Metabolites ,Tumor Microenvironment ,Blastomas ,Edema ,Membrane Metabolism ,Prospective Studies ,Prospective cohort study ,lcsh:Science ,Neurological Tumors ,Multidisciplinary ,Brain Neoplasms ,Radiology and Imaging ,Middle Aged ,Magnetic Resonance Imaging ,Bevacizumab ,Neurology ,Research Design ,030220 oncology & carcinogenesis ,Physical Sciences ,Biomarker (medicine) ,Female ,Cellular Structures and Organelles ,Statistics (Mathematics) ,medicine.drug ,Research Article ,Adult ,medicine.medical_specialty ,Imaging Techniques ,Clinical Research Design ,Antineoplastic Agents ,Creatine ,Research and Analysis Methods ,03 medical and health sciences ,Signs and Symptoms ,Diagnostic Medicine ,Internal medicine ,medicine ,Biomarkers, Tumor ,Humans ,ddc:610 ,Statistical Methods ,Survival analysis ,Aged ,Teniposide ,Tumor microenvironment ,business.industry ,lcsh:R ,Cancers and Neoplasms ,Biology and Life Sciences ,Cell Biology ,Survival Analysis ,Metabolism ,chemistry ,lcsh:Q ,sense organs ,business ,Glioblastoma ,030217 neurology & neurosurgery ,Glioblastoma Multiforme ,Mathematics ,Inositol ,Hydrogen - Abstract
Background: Antiangiogenic treatment of glioblastomas with Bevacizumab lacks predictive markers. Myoinositol (MI) is an organic osmolyte, with intracellular concentration changes depending on the extracellular osmolality. Since Bevacizumab markedly reduces tumor edema and influences the tumor microenvironment, we investigated whether the MI concentration in the tumor changes during therapy. Methods: We used 1H-magnetic resonance spectroscopy to measure the MI concentrations in the tumor and contralateral control tissue of 39 prospectively recruited patients with recurrent glioblastomas before and 8–12 weeks after starting therapy. 30 patients received Bevacizumab and 9 patients were treated with CCNU/VM26 as control. We performed a survival analysis to evaluate MI as a predictive biomarker for Bevacizumab therapy. Results: MI concentrations increased significantly during Bevacizumab therapy in tumor (p < .001) and control tissue (p = .001), but not during CCNU/VM26 treatment. For the Bevacizumab cohort, higher MI concentrations in the control tissue at baseline (p = .021) and higher differences between control and tumor tissue (delta MI, p = .011) were associated with longer survival. A Kaplan-Meier analysis showed a median OS of 164 days for patients with a deltaMI < 1,817 mmol/l and 275 days for patients with a deltaMI > 1,817 mmol/l. No differences were observed for the relative changes or the post treatment concentrations. Additionally calculated creatine concentrations showed no differences in between subgroups or between pre and post treatment measurements. Conclusion: Our data suggest that recurrent glioblastoma shows a strong metabolic reaction to Bevacizumab. Further, our results support the hypothesis that MI might be a marker for early tumor cell invasion. Pre-therapeutic MI concentrations are predictive of overall survival in patients with recurrent glioblastoma treated with Bevacizumab.
- Published
- 2016