ESTRO 2020 Abstract book
S1077 ESTRO 2020
short CT scan was assessed by 4 RTTs with different expertise (CT, mouldroom, IGRT). After this initial training phase the short CT scans of the remaining 20 patients were judged by 2 CT RTTs. Prior to the daily treatment for each patient an online CBCT scan was made and registered to the planning-CT scan. At the end of treatment all CBCT scans were analyzed and checked whether the position of the bite block was equal to the planning-CT scan. Results In 7 out of 30 planning-CT scans (23%) the bite block was repositioned due to the short CT scan. For these planning- CT scans with problems , in 83 out of 161 CBCTs (51%), the bite block was incorrectly positioned. For the 23 planning- CT scans without problems in only 7 out of 642 CBCTs (1%) the bite block was incorrectly positioned. We conclude that, when the RTTs had to reposition the bite block at the planning-CT scan, the RTTs had to reposition the bite block at the linac many times, leading to additional CBCTs. A frequently found problem was that due to the lack of teeth, patients had no grip on the bite block and the bite block could be positioned in various ways. Also it was found that if the bite block was difficult to place at the planning-CT scan, it appeared that during treatment it was not possible anymore due to toxicity. Conclusion By introducing the short CT scan for head-and-neck cancer patients, the RTTs at the planning-CT became more aware and critical with regard to placing and checking the position of the bite block.Also adjustment of the bite block at the planning-CT gave a better reproducibility at the linac. This caused less differences between planning-CT and CBCT scans. The position of the bite block became more representative for the whole treatment. In addition we have gained better insight and understanding when to expect difficulties with the bite block at the linac. These patients are closely monitored by the RTTs.
Material and Methods A prospective study was conducted with 2 groups of patients. The control group received information on bladder and rectum filling the conventional way at the intake consultation prior to simulation. The test group was monitored and followed by home nurses of the white- yellow cross. Patients were treated with 20, 25 or 35 fractions depending on their risk profile. All treatments were delivered on Varian TrueBeam and Clinac-iX systems using 6MV VMAT technique. EPIDs (aS1200 and aS1000 flat panel detectors) were used to acquire MV integrated exit dose images, on the first 3 days of treatment and weekly thereafter or more if there were failed fractions (FF). PerFRACTION TM 2D provided automatic detection of irregularities. Results were analyzed using a global gamma analysis with a threshold of 20%, a dose difference tolerance of 5%, a distance tolerance 5mm and a passing tolerance level of 95%. Results The data of 452 prostate patients were extracted from the database: 29 of the test group and 423 of the control group. The amount of exit dose images taken in both groups were comparable: 3219 fractions in total, 226 in the test group (mean of 7.8 per patient in 1 treatment course, σ=5.1) and 2993 in the control group (mean of 7.1, σ=4.5). 14% of fractions in the control group and 20% in the test group failed due to various causes. Of these FF, 40% and 31% were related to variations in bladder and rectum filling for the test and control group respectively. Patients were divided into 3 groups, related to the number of FF due to variations in bladder and rectum filling: group A with at most 1 FF is considered well prepared. Group B with 2 to 4 FF is considered being medium prepared and performed better after receiving extra information. Group C with more than 4 FF is considered having issues with preparation. Results are shown in Table 1 and Fig 1. Differences between groups were not statistically significant due to the small number of patients in the test group. Corrective actions related to the deviations of bladder and rectum filling for the test and control groups were also performed and represented 11% and 8% of the FF respectively. Conclusion We hypothesized that better monitoring would improve patients’ preparation and therefore quality of treatment. However, this was not confirmed by dosimetric analysis. The authors acknowledge possible bias due to the large difference in the number of patients in both arms of the trial. PO‐1837 Reproducibility of the bite block during radiotherapy of head‐and‐neck cancer patients V. Leijser 1 , M. Heldens-van Rooy 1 , M. Wendling 1 1 UMC St Radboud Nijmegen, Radiation Oncology, Nijmegen, The Netherlands Purpose or Objective For radiation treatment of some head-and-neck cancer patients bite blocks are necessary. The function of the bite block is to stabilize the position of the jaw, tongue and/or lip. A suboptimal positioned bite block at the planning-CT scan degrades treatment quality and causes extra workload at the linac, because the bite block position cannot accurately be reproduced. The purpose of this study was to estimate the reproducibility of the bite block in an early stage of the treatment using CBCT scans. Material and Methods Before the planning-CT scan a short CT scan was performed. In sagittal and transverse views it was examined if the bite block was properly positioned. If the bite block was not positioned correctly, it was repositioned, and the short scan was performed again. When the RTTs were not satisfied, a radiation oncologist was consulted for adjustment of the bite block. 30 patients were included in this study. For the first 10 patients the Thi abstract has been withdrawn
PO‐1838 Multiple Brain Mets: impact of patient positioning errors on optimal PTV margin strategy L. Capone 1 , B. Nardiello 1 , R. El Gawhary 2 , G. Raza 2 , C. Scaringi 1 , F. Bianciardi 2 , P. Gentile 2 , S. Paolini 3 , G. Minniti 1 1 UPMC San Pietro FBF, Radiotherapy, Rome, Italy ; 2 Ospedale San Pietro FBF, Radiotherapy, Rome, Italy ; 3 IRCCS Neuromed, Radiation Oncology Unit, Pozzilli, Italy Purpose or Objective To assess the impact of set-up residual errors on target positioning accuracy and intrafraction motion of frameless linear accelerator (LINAC) dynamic conformal arc (DCA) single-isocenter stereotactic radiosurgery (SRS) for multiple brain metastases. Material and Methods Between September 2016 and February 2018, twenty six consecutive patients ≥18 years old with 181 metastases < 2.5 cm in maximum size who received single-isocenter
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