A method to establish the relationship between CT number and effective density for therapeutic radiations is proposed. We approximated body tissues to mixtures of muscle, air, fat, and bone. Consequently, the relationship can be calibrated only with a CT scan of their substitutes, for which we chose water, air, ethanol, and potassium phosphate solution, respectively. With simple and specific corrections for non-equivalencies of the substitutes, the calibration accuracy of 1% will be achieved. We tested the calibration method with some biological materials to verify that the proposed method would offer accuracy, simplicity, and specificity required for a standard in radiotherapy treatment planning, in particular, with heavy charged particles
Despite extensive research in dual-energy computed tomography (CT), single-energy CT (SECT) is still...
A calibration method for CT-number to stopping-power-ratio conversion was recently proposed as a rev...
Purpose: In treatment planning of charged-particle radiotherapy, patient heterogeneity is convention...
A method to establish the relationship between CT number and effective density for therapeutic radia...
In the conventional procedure for accurate Monte Carlo simulation of radiotherapy, a CT number given...
For accurate Monte Carlo simulation of radiotherapy, CT number of patient image is converted to mass...
Even though range calculation in treatment planning is crucial for charged particle therapy, the ava...
A computed tomography number to relative electron density (CT-RED) calibration is performed when com...
A guideline for quality assurance of CT systems for radiotherapy treatment planning is proposed. Qua...
Dual-energy computed tomography enables the determination of relative electron density and effective...
In treatment planning for hadron therapy, information about the relative stopping power in a patient...
In charged-particle therapy treatment planning, the volumetric distribution of stopping power ratios...
In charged-particle therapy treatment planning, the volumetric distribution of stopping power ratios...
To compute the dose distribution, treatment planning systems require the exact anatomical location o...
Despite extensive research in dual-energy computed tomography (CT), single-energy CT (SECT) is still...
Despite extensive research in dual-energy computed tomography (CT), single-energy CT (SECT) is still...
A calibration method for CT-number to stopping-power-ratio conversion was recently proposed as a rev...
Purpose: In treatment planning of charged-particle radiotherapy, patient heterogeneity is convention...
A method to establish the relationship between CT number and effective density for therapeutic radia...
In the conventional procedure for accurate Monte Carlo simulation of radiotherapy, a CT number given...
For accurate Monte Carlo simulation of radiotherapy, CT number of patient image is converted to mass...
Even though range calculation in treatment planning is crucial for charged particle therapy, the ava...
A computed tomography number to relative electron density (CT-RED) calibration is performed when com...
A guideline for quality assurance of CT systems for radiotherapy treatment planning is proposed. Qua...
Dual-energy computed tomography enables the determination of relative electron density and effective...
In treatment planning for hadron therapy, information about the relative stopping power in a patient...
In charged-particle therapy treatment planning, the volumetric distribution of stopping power ratios...
In charged-particle therapy treatment planning, the volumetric distribution of stopping power ratios...
To compute the dose distribution, treatment planning systems require the exact anatomical location o...
Despite extensive research in dual-energy computed tomography (CT), single-energy CT (SECT) is still...
Despite extensive research in dual-energy computed tomography (CT), single-energy CT (SECT) is still...
A calibration method for CT-number to stopping-power-ratio conversion was recently proposed as a rev...
Purpose: In treatment planning of charged-particle radiotherapy, patient heterogeneity is convention...