Evaluation of the truebeam machine performance check ( MPC ):  OBI  X‐ray tube alignment procedure

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Abstract

Alignment of the On‐Board Imager ( OBI) X‐ray tube is important for ensuring imaging to treatment isocenter coincidence, which in turn is important for accurate Image Guided Radiotherapy ( IGRT). Varian introduced a new X‐ray tube alignment procedure for the TrueBeam linac in software version 2.5 MR2 as part of the machine performance check ( MPC) application. This study evaluated the new procedure against conventional methods and examined the clinical significance of X‐ray tube misalignment. Long term stability and short term repeatability of MPC tube alignment was assessed as well as sensitivity of the method to setup error. Standard quality assurance tests expected to be sensitive to tube misalignment were performed before and after tube alignment. These tests included: IsoCal verification; MPC kV imager offset; Winston‐Lutz: kV imaging to treatment/radiation isocenter coincidence; CBCT image QA using the Catphan phantom; and OBI image geometric accuracy and center pixel alignment. Tube alignment measurements were performed with MPC, the two‐plate method, and wire‐on‐faceplate method. The X‐ray tube was then realigned by approximately 1.01 mm in the tangential plane based upon MPC and the tube alignment and standard quality assurance measurements were repeated. The time taken for each tube alignment method was estimated. The MPC method of tube alignment was found to be repeatable, insignificantly sensitive to phantom setup error and quick and simple to perform. The standard QA tests were generally insensitive to the tube alignment change, possibly because of the IsoCal correction. However, reduction in the magnitude of IsoCal correction and MPC kV imager offset was recorded after tube alignment. There was also apparent improvement in CBCT image uniformity. The MPC procedure is recommended for X‐ray tube alignment.

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Most cited references 11

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Quality assurance for image-guided radiation therapy utilizing CT-based technologies: a report of the AAPM TG-179.

Jean-Pierre Bissonnette, Peter Balter, Lei Dong … (2012)

Commercial CT-based image-guided radiotherapy (IGRT) systems allow widespread management of geometric variations in patient setup and internal organ motion. This document provides consensus recommendations for quality assurance protocols that ensure patient safety and patient treatment fidelity for such systems.

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A quality assurance program for the on-board imagers.

Peter M.G. Munro, Gary Luxton, David E. Elder … (2006)

To develop a quality assurance (QA) program for the On-Board Imager (OBI) system and to summarize the results of these QA tests over extended periods from multiple institutions. Both the radiographic and cone-beam computed tomography (CBCT) mode of operation have been evaluated. The QA programs from four institutions have been combined to generate a series of tests for evaluating the performance of the On-Board Imager. The combined QA program consists of three parts: (1) safety and functionality, (2) geometry, and (3) image quality. Safety and functionality tests evaluate the functionality of safety features and the clinical operation of the entire system during the tube warm-up. Geometry QA verifies the geometric accuracy and stability of the OBI/CBCT hardware/software. Image quality QA monitors spatial resolution and contrast sensitivity of the radiographic images. Image quality QA for CBCT includes tests for Hounsfield Unit (HU) linearity, HU uniformity, spatial linearity, and scan slice geometry, in addition. All safety and functionality tests passed on a daily basis. The average accuracy of the OBI isocenter was better than 1.5 mm with a range of variation of less than 1 mm over 8 months. The average accuracy of arm positions in the mechanical geometry QA was better than 1 mm, with a range of variation of less than 1 mm over 8 months. Measurements of other geometry QA tests showed stable results within tolerance throughout the test periods. Radiographic contrast sensitivity ranged between 2.2% and 3.2% and spatial resolution ranged between 1.25 and 1.6 lp/mm. Over four months the CBCT images showed stable spatial linearity, scan slice geometry, contrast resolution (1%; 6 lp/cm). The HU linearity was within +/-40 HU for all measurements. By combining test methods from multiple institutions, we have developed a comprehensive, yet practical, set of QA tests for the OBI system. Use of the tests over extended periods show that the OBI system has reliable mechanical accuracy and stable image quality. Nevertheless, the tests have been useful in detecting performance deficits in the OBI system that needed recalibration. It is important that all tests are performed on a regular basis.

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The stability of mechanical calibration for a kV cone beam computed tomography system integrated with linear accelerator.

David Jaffray, Mohammad Faizul Islam, Thomas Purdie … (2006)

The geometric accuracy and precision of an image-guided treatment system were assessed. Image guidance is performed using an x-ray volume imaging (XVI) system integrated with a linear accelerator and treatment planning system. Using an amorphous silicon detector and x-ray tube, volumetric computed tomography images are reconstructed from kilovoltage radiographs by filtered backprojection. Image fusion and assessment of geometric targeting are supported by the treatment planning system. To assess the limiting accuracy and precision of image-guided treatment delivery, a rigid spherical target embedded in an opaque phantom was subjected to 21 treatment sessions over a three-month period. For each session, a volumetric data set was acquired and loaded directly into an active treatment planning session. Image fusion was used to ascertain the couch correction required to position the target at the prescribed iso-center. Corrections were validated independently using megavoltage electronic portal imaging to record the target position with respect to symmetric treatment beam apertures. An initial calibration cycle followed by repeated image-guidance sessions demonstrated the XVI system could be used to relocate an unambiguous object to within less than 1 mm of the prescribed location. Treatment could then proceed within the mechanical accuracy and precision of the delivery system. The calibration procedure maintained excellent spatial resolution and delivery precision over the duration of this study, while the linear accelerator was in routine clinical use. Based on these results, the mechanical accuracy and precision of the system are ideal for supporting high-precision localization and treatment of soft-tissue targets.

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Author and article information

Contributors

Michael P. Barnes: michael.barnes@calvarymater.org.au

Journal

Journal ID (nlm-ta): J Appl Clin Med Phys

Journal ID (iso-abbrev): J Appl Clin Med Phys

Journal ID (doi): 10.1002/(ISSN)1526-9914

Journal ID (publisher-id): ACM2

Title: Journal of Applied Clinical Medical Physics

Publisher: John Wiley and Sons Inc. (Hoboken )

ISSN (Electronic): 1526-9914

Publication date (Electronic): 03 September 2018

Publication date Collection: November 2018

Volume: 19

Issue: 6 ( doiID: 10.1002/acm2.2018.19.issue-6 )

Pages: 68-78

Affiliations

[ ¹ ] Department of Radiation Oncology Calvary Mater Hospital Newcastle Newcastle NSW Australia

[ ² ] School of Medical Radiation Sciences University of Newcastle Newcastle NSW Australia

[ ³ ] School of Mathematical and Physical Sciences University of Newcastle Newcastle NSW Australia

[ ⁴ ] Varian Medical Systems Palo Alto CA USA

Author notes

[*] [* ] Author to whom correspondence should be addressed. Michael P Barnes

E‐mail: michael.barnes@ 123456calvarymater.org.au ; Telephone: (+612) 401 43636; Fax: (+612) 401 43 169.

Article

Publisher ID: ACM212445

DOI: 10.1002/acm2.12445

PMC ID: 6236821

PubMed ID: 30178521

SO-VID: b7c89d16-5adc-417d-bdc8-ff2ad0b235be

License:

This is an open access article under the terms of the http://creativecommons.org/licenses/by/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

History

Date received : 23 April 2018

Date revision received : 26 July 2018

Date accepted : 04 August 2018

Page count

Figures: 5, Tables: 5, Pages: 11, Words: 7215

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component-id acm212445

cover-date November 2018

details-of-publishers-convertor Converter:WILEY_ML3GV2_TO_NLMPMC version:version=5.5.1 mode:remove_FC converted:15.11.2018

Evaluation of the truebeam machine performance check (MPC): OBI X‐ray tube alignment procedure

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Abstract

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International Journal of Applied Technology in Medical Sciences

Most cited references 11

Quality assurance for image-guided radiation therapy utilizing CT-based technologies: a report of the AAPM TG-179.

A quality assurance program for the on-board imagers.

The stability of mechanical calibration for a kV cone beam computed tomography system integrated with linear accelerator.

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