Calculation Method for Novel Upright CT Scanner Isodose Curves

Overview

Journal J Appl Clin Med Phys

Specialties Biophysics
General Medicine

Date 2024 May 2

PMID 38695845

Authors

Michael W Kissick

Costanza Panaino

Anthony Criscuolo

John Hayes

Carson Hoffman

Rockwell Mackie

Andries N Schreuder

Affiliations

Soon will be listed here.

Abstract

Purpose: A computational method based on Monte-Carlo calculations is presented and used to calculate isodose curves for a new upright and tilting CT scanner useful for radiation protection purposes.

Methods: The TOPAS code platform with imported CAD files for key components was used to construct a calculation space for the scanner. A sphere of water acts as the patient would by creating scatter out of the bore. Maximum intensity dose maps are calculated for various possible tilt angles to make sure radiation protection for site planning uses the maximum possible dose everywhere.

Results: The resulting maximum intensity isodose lines are more rounded than ones for just a single tilt angle and so closer to isotropic. These maximum intensity curves are closer to the isotropic assumption used in CTDI or DLP based methods of site planning and radiation protection. The isodose lines are similar to those of a standard CT scanner, just tilted upwards. There is more metal above the beam that lessens the dose above versus below isocenter.

Conclusion: Aside from the orientation, this upright scanner is very similar to a typical CT scanner, and nothing different for shielding needs to be done for this new upright tilting CT scanner, because an isotropic scatter source is often assumed for any CT scanner.

Citing Articles

Calculation method for novel upright CT scanner isodose curves.

Kissick M, Panaino C, Criscuolo A, Hayes J, Hoffman C, Mackie R J Appl Clin Med Phys. 2024; 25(7):e14377.

PMID: 38695845 PMC: 11244660. DOI: 10.1002/acm2.14377.

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