Copenhagen, Denmark
Onsite/Online

ESTRO 2022

Session Item

Dosimetry
6034
Poster (digital)
Physics
HyperArcTM dosimetric validation for multiple targets using ionization chamber and polymer gel
lucia zirone, Italy
PO-1587

Abstract

HyperArcTM dosimetric validation for multiple targets using ionization chamber and polymer gel
Authors:

lucia zirone1, Elisa Bonanno2, Giuseppina Borzì2, Nina Cavalli2, Martina Pace1, Giuseppe Stella2,1, Andrea Girlando3, Anna Maria Gueli4, Carmelo Marino2,1

1University of Catania, School of Medical Physics, Catania, Italy; 2Humanitas - Istituto Clinico Catanese, Medical Physics, Catania, Italy; 3Huminitas - Istituto Clinico Catanese, Radiotherapy, Catania, Italy; 4University of Catania, Medical Physics, Catania, Italy

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Purpose or Objective

Multiple brain metastases stereotactic radiosurgery (SRS) treatments with single isocenter approach are increasingly used in many radiotherapy departments. Because of the complexity of such techniques, it is recommended to perform end-to-end tests, before their introduction into the clinical routine, to evaluate the overall dosimetric and geometric uncertainties on the treatment planning and delivery system. In this work, we report the results of end-to-end tests for five HyperArcTM treatment plans using an ionization chamber (IC) and polymer gel.

Material and Methods

Five SRS treatments with single and multiple brain metastases were planned using HyperArcTM technique with a prescription dose of 15-22 Gy and 6-9 Gy respectively for IC and polymer gel. The SRS plans were calculated using AcurosXB 15.6.06 algorithm on Eclipse v.15.6 Treatment Planning System (Varian Medical Systems), 6 MV Flattening Filter Free (FFF) mode, maximum dose-rate of 1400 UM/min, mono-isocenter technique and 3-4 non-coplanar arcs on a TrueBeam machine (Varian Medical Systems) with High Definition 120 MLC at Humanitas Istituto Clinico Catanese.

The end-to-end tests were performed using a 3D-printed anthropomorphic head phantom. Point dose measurements were performed placing a CC04 ion chamber (IBA dosimetry) in the center of each target volume; a total of 15 plans was delivered.

2D and 3D dose distributions were evaluated for each target using polymer gel (RTsafe). 24h after irradiation, the phantom filled of gels was read by Philips dStream 1,5T Magnetic Resonance Imaging (MRI). The dose distributions measured by the polymer gels were compared to the dose distribution calculated by the treatment planning system using gamma evaluation by different criteria (5%2mm, 3%2mm).

Results

A mean point dose difference of 0.23% [min 0.01% - max 2.81%] was found using IC.

For each target volume the results obtained in terms of ɣ index passing rate show an agreement > 95% with 5%2mm and 3%2mm criteria for both 2D and 3D distributions.

Conclusion

The HyperArcTM dosimetric validation has allowed the introduction of this technique in the clinical routine of Humanitas Istituto Clinico Catanese. Further investigations will regard the use of a 3D printer for customized anthropomorphic phantoms.