Quality assurance of linear accelerator: a comprehensive system using electronic portal imaging device

Niyas, Puzhakal; Abdullah, Kallikuzhiyil Kochunny; Noufal, Manthala Padannayil; Vysakh, R

doi:10.1017/s146039691800050x

Cited by 2 publications

(1 citation statement)

References 28 publications

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“…With the increasing complexity of medical linear accelerators and treatment techniques, implementation of a proper QA program can be time-consuming and cumbersome. Recent emphasis has been placed on improving efficiency; allowing for the reallocation of the medical physicist's time and resources [12][13][14][15][16][17]. A recent American Association of Physicists in Medicine (AAPM) task group report describes how reallocation of QA resources can be achieved while maintaining a high degree of safety and considering the unique environment at each center [18].…”

Section: Introductionmentioning

confidence: 99%

Characterization of an Onboard Transmission Detector for Efficient Linear Accelerator Output Quality Assurance

Kunz,

Sarkar,

Paxton

et al. 2023

Cureus

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Purpose To investigate the potential to perform linear accelerator output quality assurance (QA) with the ScandiDos Delta4 Discover (Discover) onboard transmission detector. Materials and methods Using the ScandiDos Delta4 software (version 8), a conversion factor from raw signal to output was obtained via cross-calibration with an accredited dosimetry calibration laboratory (ADCL) calibrated ionization chamber for each photon energy, including flattening-filter-free (FFF) energies. With the calibration factor for 6 MV (6x) photon energy, output measurements were taken with both the Delta4 Discover and ion chamber and compared for output as a function of gantry angle and dose-rate dependence. Monitor unit (MU) linearity for 6x was measured and compared with ion chamber measurements. Additionally, the Discover was used to take output measurements, for 6x, approximately every hour throughout the course of a treatment day, and compared with ion chamber output measurements at the beginning and end of the treatment day. Results Output measurements for each photon energy were comparable with a maximum difference of -0.57% for flattened beams (6x) and 0.21% for FFF beams (10FFF). Output measurements using the Discover matched ion chamber output measurements at every dose rate within 2%, and within 1% for output as a function of gantry angle. MU linearity test agreed with ion chamber measurements with a maximum difference of 0.41%. Output measurements using the Discover showed a daily drift in output throughout the course of a treatment day of around 2% and correlated very well with ion chamber outputs measured at the beginning and end of the treatment day (within 0.2%). Conclusions The ScandiDos Delta4 Discover onboard transmission detector is able to accurately measure linear accelerator output comparable to ion chamber measurements.

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Section: Introductionmentioning

confidence: 99%

Characterization of an Onboard Transmission Detector for Efficient Linear Accelerator Output Quality Assurance

Kunz,

Sarkar,

Paxton

et al. 2023

Cureus

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Preliminary Study on the Use of Fricke Gel Dosimeter for Verification of IMRT Beam Delivery

Uzorka

Bale

Kibirige

2022

Biophys. Rev. Lett.

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The goal of intensity-modulated radiation therapy (IMRT) is to deliver a uniform dose to the tumor with minimal margins around the target, in order to increase local control of the disease while reducing secondary effects. The research performed in this work has shown the potential usefulness of the Fricke-gel dosimeter as a quality assurance (QA) tool to verify IMRT treatments produced by inverse treatment planning. First, the 3D integrating Fricke-gel dosimeter was successfully compared to an accepted dosimetric tool. It was then used to measure relative 3D dose distributions of simple treatment plans with multiple square or rectangular fields and specific inverse-planned IMRT treatment plans. By combining the CT anatomical information and the plan contours with the gel-measured data, it was possible to display the contours on the measured dose and the measured isodose lines on the CT, in addition to measuring dose-volume histograms (DVH) for the plans. This demonstrated the usefulness of the gel dosimeter as a QA tool for IMRT and inverse planning.

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Quality assurance of linear accelerator: a comprehensive system using electronic portal imaging device

Cited by 2 publications

References 28 publications

Characterization of an Onboard Transmission Detector for Efficient Linear Accelerator Output Quality Assurance

Characterization of an Onboard Transmission Detector for Efficient Linear Accelerator Output Quality Assurance

Preliminary Study on the Use of Fricke Gel Dosimeter for Verification of IMRT Beam Delivery

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