Michael Christensen1, David Olayinka Kamson2, Michael Snyder1, Harold Kim1, Natasha L Robinette3, Sandeep Mittal4, Csaba Juhász5. 1. Department of Radiation Oncology, Barbara Ann, Karmanos Cancer Center, Wayne State University School of Medicine, 540 E. Canfield, Detroit, MI 48201, USA. Barbara Ann Karmanos Cancer Institute, Detroit, MI, USA. 2. Departments of Pediatrics and Neurology, Wayne State University School of Medicine, Detroit, MI, USA. PET Center and Translational Imaging Laboratory, Children's Hospital of Michigan, Detroit, MI, USA. 3. Barbara Ann Karmanos Cancer Institute, Detroit, MI, USA. Department of Radiology, Wayne State University School of Medicine, Detroit, MI, USA. 4. Barbara Ann Karmanos Cancer Institute, Detroit, MI, USA. Department of Neurosurgery, Wayne State University School of Medicine, Detroit, MI, USA. 5. Departments of Pediatrics and Neurology, Wayne State University School of Medicine, Detroit, MI, USA. Barbara Ann Karmanos Cancer Institute, Detroit, MI, USA. PET Center and Translational Imaging Laboratory, Children's Hospital of Michigan, Detroit, MI, USA.
Abstract
OBJECTIVE: Glioblastoma is an infiltrative malignancy that tends to extend beyond the MRI-defined tumor volume. We utilized positron emission tomography (PET) imaging with the radiotracer alpha-[11C]methyl-L -tryptophan (AMT) to develop a reliable high-risk gross tumor volume (HR-GTV) method for delineation of glioblastoma. AMT can detect solid tumor mass and tumoral brain infiltration by increased tumoral tryptophan transport and metabolism via the immunosuppressive kynurenine pathway. METHODS: We reviewed all patients in our database with histologically proven glioblastoma who underwent preoperative AMT-PET scan prior to surgery and chemoradiation. Treated radiotherapy volumes were derived from the simulation CT with MRI fusion. High-GTV with contrast enhanced T1-weighted MRI alone (GTVMRI) was defined as the postoperative cavity plus any residual area of enhancement on postcontrast T1-weighted images. AMT-PET images were retrospectively fused to the simulation CT, and a high-risk GTVs generated by both AMT-PET alone (GTVAMT) was defined using a threshold previously established to distinguish tumor tissue from peritumoral edema. A composite volume of MRI and AMT tumor volume was also created (combination of MRI fused with AMT-PET data; GTVMRI+AMT). In patients with definitive radiographic progression, follow-up MRI demonstrating initial tumor progression was fused with the pretreatment images and a progression volume was contoured. The coverage of the progression volume by GTVMRI, GTVAMT, and GTVMRI+AMT was determined and compared using the Wilcoxon's signed-rank test. RESULTS: Eleven patients completed presurgical AMT-PET scan, seven of whom had progressive disease after initial therapy. GTVMRI (mean, 50.2 cm3) and GTVAMT (mean, 48.9 cm3) were not significantly different. Mean concordance index of the volumes was 39±15 %. Coverage of the initial recurrence volume by HR-GTVMRI (mean, 52 %) was inferior to both GTVAMT (mean, 68 %; p =0.028) and GTVMRI+AMT (mean 73 %; p =0.018). The AMT-PET-exclusive coverage was up to 41 % of the recurrent volume. There was a tendency towards better recurrence coverage with GTVMRI+AMT than with GTVAMT alone (p =0.068). Addition of 5 mm concentric margin around GTVMRI, GTVAMT, and GTVMRI+AMT would have completely covered the initial progression volume in 14, 57, and 71 % of the patients, respectively. CONCLUSION: We found that a GTV defined by AMT-PET produced similar volume, but superior recurrence coverage than the treated standard MRI-determined volume. A prospective study is necessary to fully determine the usefulness of AMT-PET for volume definition in glioblastoma radiotherapy planning.
OBJECTIVE:Glioblastoma is an infiltrative malignancy that tends to extend beyond the MRI-defined tumor volume. We utilized positron emission tomography (PET) imaging with the radiotracer alpha-[11C]methyl-L -tryptophan (AMT) to develop a reliable high-risk gross tumor volume (HR-GTV) method for delineation of glioblastoma. AMT can detect solid tumor mass and tumoral brain infiltration by increased tumoraltryptophan transport and metabolism via the immunosuppressive kynurenine pathway. METHODS: We reviewed all patients in our database with histologically proven glioblastoma who underwent preoperative AMT-PET scan prior to surgery and chemoradiation. Treated radiotherapy volumes were derived from the simulation CT with MRI fusion. High-GTV with contrast enhanced T1-weighted MRI alone (GTVMRI) was defined as the postoperative cavity plus any residual area of enhancement on postcontrast T1-weighted images. AMT-PET images were retrospectively fused to the simulation CT, and a high-risk GTVs generated by both AMT-PET alone (GTVAMT) was defined using a threshold previously established to distinguish tumor tissue from peritumoral edema. A composite volume of MRI and AMT tumor volume was also created (combination of MRI fused with AMT-PET data; GTVMRI+AMT). In patients with definitive radiographic progression, follow-up MRI demonstrating initial tumor progression was fused with the pretreatment images and a progression volume was contoured. The coverage of the progression volume by GTVMRI, GTVAMT, and GTVMRI+AMT was determined and compared using the Wilcoxon's signed-rank test. RESULTS: Eleven patients completed presurgical AMT-PET scan, seven of whom had progressive disease after initial therapy. GTVMRI (mean, 50.2 cm3) and GTVAMT (mean, 48.9 cm3) were not significantly different. Mean concordance index of the volumes was 39±15 %. Coverage of the initial recurrence volume by HR-GTVMRI (mean, 52 %) was inferior to both GTVAMT (mean, 68 %; p =0.028) and GTVMRI+AMT (mean 73 %; p =0.018). The AMT-PET-exclusive coverage was up to 41 % of the recurrent volume. There was a tendency towards better recurrence coverage with GTVMRI+AMT than with GTVAMT alone (p =0.068). Addition of 5 mm concentric margin around GTVMRI, GTVAMT, and GTVMRI+AMT would have completely covered the initial progression volume in 14, 57, and 71 % of the patients, respectively. CONCLUSION: We found that a GTV defined by AMT-PET produced similar volume, but superior recurrence coverage than the treated standard MRI-determined volume. A prospective study is necessary to fully determine the usefulness of AMT-PET for volume definition in glioblastoma radiotherapy planning.
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