Abstract
BackgroundMega-voltage fan-beam Computed Tomography (MV-FBCT) holds potential in accurate determination of relative electron density (RED) and proton stopping power ratio (SPR) but is not widely available.ObjectiveTo demonstrate the feasibility of MV-FBCT using a medical linear accelerator (LINAC) with a 2.5 MV imaging beam, an electronic portal imaging device (EPID) and multileaf collimators (MLCs).MethodsMLCs were used to collimate MV beam along z direction to enable a 1 cm width fan-beam. Projection data were acquired within one gantry rotation and preprocessed with in-house developed artifact correction algorithms before the reconstruction. MV-FBCT data were acquired at two dose levels: 30 and 60 monitor units (MUs). A Catphan 604 phantom was used to evaluate basic image quality. A head-sized CIRS phantom with three configurations of tissue-mimicking inserts was scanned and MV-FBCT Hounsfield unit (HU) to RED calibration was established for each insert configuration using linear regression. The determination coefficient ({R}^{2}) was used to gauge the accuracy of HU-RED calibration. Results were compared with baseline single-energy kilo-voltage treatment planning CT (TP-CT) HU-RED calibration which represented the current standard clinical practice.ResultsThe in-house artifact correction algorithms effectively suppressed ring artifact, cupping artifact, and CT number bias in MV-FBCT. Compared to TP-CT, MV-FBCT was able to improve the prediction accuracy of the HU-RED calibration curve for all three configurations of insert materials, with {R}^{2} > 0.9994 and {R}^{2} < 0.9990 for MV-FBCT and TP-CT HU-RED calibration curves of soft-tissue inserts, respectively. The measured mean CT numbers of blood-iodine mixture inserts in TP-CT drastically deviated from the fitted values but not in MV-FBCT. Reducing the radiation level from 60 to 30 MU did not decrease the prediction accuracy of the MV-FBCT HU-RED calibration curve.ConclusionWe demonstrated the feasibility of MV-FBCT and its potential in providing more accurate RED estimation.
Highlights
Mega-voltage fan-beam Computed Tomography (MV-Fan-beam CT (FBCT)) holds potential in accurate determination of relative electron density (RED) and proton stopping power ratio (SPR) but is not widely available
Image uniformity was evaluated with the uniformity module of Catphan phantom, comparing the mean CT number measured from one central regionof-interests (ROI) and four peripheral ROIs (Table 3)
The corresponding CT numbers from treatment-planning CT (TP-CT) obviously deviated from the extrapolated values according to the fitted curve (Fig. 5), and additional calibration would be necessary for these materials
Summary
Mega-voltage fan-beam Computed Tomography (MV-FBCT) holds potential in accurate determination of relative electron density (RED) and proton stopping power ratio (SPR) but is not widely available. Relative electron density (RED) or proton stopping power ratio (SPR) is required to calculate photon or proton dose distribution, respectively [7,8,9]. These quantities can be obtained from CT numbers using a calibration curve established during the commissioning. CT number is a measure of linear attenuation coefficient which reflects a combined effect of Compton scattering (∝ RED ), coherent scattering (∝ Z1.86 ) and photoelectric (∝ Z3.62 ) interaction mechanisms [8]. Based on the calibration curve method, these materials are mapped to the same RED or proton SPR, causing errors in RED or proton SPR estimation
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