Implementation and experimental evaluation of Mega-voltage fan-beam CT using a linear accelerator

Hao Gong; Shengzhen Tao; Justin D Gagneur; Wei Liu; Jiajian Shen; Cynthia H McCollough; Yanle Hu; Shuai Leng

doi:10.1186/s13014-021-01862-x

Implementation and experimental evaluation of Mega-voltage fan-beam CT using a linear accelerator

Radiat Oncol. 2021 Jul 28;16(1):139. doi: 10.1186/s13014-021-01862-x.

Authors

Hao Gong¹, Shengzhen Tao¹, Justin D Gagneur², Wei Liu², Jiajian Shen², Cynthia H McCollough¹, Yanle Hu³, Shuai Leng⁴

Affiliations

¹ Department of Radiology, Mayo Clinic, 200 First Street SW, Rochester, MN, 55905, USA.
² Department of Radiology, Mayo Clinic Arizona, 5881 East Mayo Blvd, Phoenix, AZ, 85258, USA.
³ Department of Radiology, Mayo Clinic Arizona, 5881 East Mayo Blvd, Phoenix, AZ, 85258, USA. Hu.Yanle@mayo.edu.
⁴ Department of Radiology, Mayo Clinic, 200 First Street SW, Rochester, MN, 55905, USA. Leng.Shuai@mayo.edu.

Abstract

Background: 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.

Objective: To 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).

Methods: MLCs 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 ([Formula: see text]) 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.

Results: The 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 [Formula: see text] > 0.9994 and [Formula: see text] < 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.

Conclusion: We demonstrated the feasibility of MV-FBCT and its potential in providing more accurate RED estimation.

Keywords: Dose calculation; Electron density; Mega-voltage CT; Radiation therapy.

MeSH terms

Algorithms*
Artifacts
Calibration
Humans
Image Processing, Computer-Assisted / methods
Neoplasms / radiotherapy*
Particle Accelerators / instrumentation*
Phantoms, Imaging*
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted / methods*
Radiotherapy, Intensity-Modulated / methods*
Tomography, X-Ray Computed / methods*