SU‐FF‐T‐366: Radiation Dose Response Curve of Human Cerebral Cortex Measured with [F‐18]‐FDG and [O‐15]‐H2O PET Imaging

Purpose: To study radiotherapy (RT)‐induced dose‐dependent functional changes in the human cerebral cortex region using serial [formula omitted] and [formula omitted] PET imaging before and after RT. Method and Materials: Eleven human subjects were enrolled in an IRB‐approved prospective study to quantitatively measure changes in post‐RT brain function. [formula omitted] and [formula omitted] PET images were taken pre‐RT, and again at 3 weeks and 6 months post‐RT, to quantitatively assess for RT‐induced changes in relative metabolism and relative regional blood flow (RBF). The 3 week and 6 month follow‐up evaluations were available for 7 and 6 patients, respectively. Follow‐up images were registered to their corresponding pre‐RT baseline images, as well as to the treatment planning CT/MRI scans, for quantitative analysis. Relative changes in regional [formula omitted] and [formula omitted] PET activities were related to regional RT dose. Regions of the cerebral cortex receiving <5Gy served as “controls” for imaging normalization. Irradiated regions were binned, based on 5Gy intervals, up to 62Gy. Individual and population dose response curves were then generated in PLUNC (PlanUNC). Results: At both post‐RT time intervals, stable reductions in relative FDG uptake (average 2–6%, range −8 to 13%, generally <8%) were seen in the cerebral cortex, particularly in the regions receiving >40–50Gy. Initially, relative RBF increases (generally <10%) were observed on 15O‐H2O PET imaging (3 week follow‐up), but were much less significant at the 6‐month follow‐up. Conclusion: The response of cerebral cortex tissue to RT can be detected, in a dose‐dependent manner, using [formula omitted] PET. The magnitude of the changes, however, was typically small (<8%). Initially there were increases in relative RBF, but no discernable changes were seen at 6 months followup in [formula omitted] PET. Further studies are needed for more conclusive results. Results from neuropsychological testing will be used to assess the potential clinical impact of the changes measured by PET. © 2005, American Association of Physicists in Medicine. All rights reserved.

Duke Scholars

Author Carol Anne Hahn Radiation Oncology

Author John P. Kirkpatrick Radiation Oncology

Author Timothy Garvey Turkington Radiology

Author Terence Z. Wong Radiology, Nuclear Medicine