Program Information
Comprehensive Machine Isocenter Evaluation with Separation of Gantry, Collimator, and Table Variables
S Hancock1*, C Clements2 , D Hyer3 , E Nixon3 , E Martin4 , B Wang4 , S Jani5 , M Gossman6 , (1) Southeast Missouri Hospital, Cape Girardeau, MO, (2) Radiological Imaging Technology, Colorado Springs, CO, (3) University Of Iowa, Iowa City, IA, (4) University of Louisville, Louisville, KY, (5) Sharp Memorial Hospital, San Diego, CA, (6) Tri-State Regional Cancer Center, Ashland, KY
Presentations
SU-G-TeP2-4 (Sunday, July 31, 2016) 4:30 PM - 5:00 PM Room: ePoster Theater
Purpose:
To develop and demonstrate application of a method that characterizes deviation of linac x-ray beams from the centroid of the volumetric radiation isocenter as a function of gantry, collimator, and table variables.
Methods:
A set of Winston-Lutz ball-bearing images was used to determine the gantry radiation isocenter as the midrange of deviation values resulting from gantry and collimator rotation. Also determined were displacement of table axis from gantry isocenter and recommended table axis adjustment. The method, previously reported, has been extended to include the effect of collimator walkout by obtaining measurements with 0 and 180 degree collimator rotation for each gantry angle. Twelve images were used to characterize the volumetric isocenter for the full range of available gantry, collimator, and table rotations.
Results:
Three Varian True Beam, two Elekta Infinity and four Versa HD linacs at five institutions were tested using identical methodology. Varian linacs exhibited substantially less deviation due to head sag than Elekta linacs (0.4 mm vs. 1.2 mm on average). One linac from each manufacturer had additional isocenter deviation of 0.3 to 0.4 mm due to jaw instability with gantry and collimator rotation. For all linacs, the achievable isocenter tolerance was dependent on adjustment of collimator position offset, transverse position steering, and alignment of the table axis with gantry isocenter, facilitated by these test results. The pattern and magnitude of table axis wobble vs. table angle was reproducible and unique to each machine.
Conclusion:
This new method provides a comprehensive set of isocenter deviation values including all variables. It effectively facilitates minimization of deviation between beam center and target (ball-bearing) position. This method was used to quantify the effect of jaw instability on isocenter deviation and to identify the offending jaw. The test is suitable for incorporation into a routine machine QA program.
Funding Support, Disclosures, and Conflict of Interest: Software development was performed by Radiological Imaging Technology, Inc.
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