Conversion of CT Numbers into Tissue Parameters for Monte Carlo Dose Calculations: a Multi-centre Study

Overview

Journal Phys Med Biol

Publisher IOP Publishing

Specialties Biophysics
Nuclear Medicine
Radiology

Date 2007 Jan 18

PMID 17228104

Citations 26

Authors

Barbara Vanderstraeten

Pik Wai Chin

Michael Fix

Antonio Leal

Grisel Mora

Nick Reynaert

Joao Seco

Martin Soukup

Emiliano Spezi

Wilfried De Neve

Hubert Thierens

Affiliations

Soon will be listed here.

Abstract

The conversion of computed tomography (CT) numbers into material composition and mass density data influences the accuracy of patient dose calculations in Monte Carlo treatment planning (MCTP). The aim of our work was to develop a CT conversion scheme by performing a stoichiometric CT calibration. Fourteen dosimetrically equivalent tissue subsets (bins), of which ten bone bins, were created. After validating the proposed CT conversion scheme on phantoms, it was compared to a conventional five bin scheme with only one bone bin. This resulted in dose distributions D(14) and D(5) for nine clinical patient cases in a European multi-centre study. The observed local relative differences in dose to medium were mostly smaller than 5%. The dose-volume histograms of both targets and organs at risk were comparable, although within bony structures D(14) was found to be slightly but systematically higher than D(5). Converting dose to medium to dose to water (D(14) to D(14wat) and D(5) to D(5wat)) resulted in larger local differences as D(5wat) became up to 10% higher than D(14wat). In conclusion, multiple bone bins need to be introduced when Monte Carlo (MC) calculations of patient dose distributions are converted to dose to water.

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