Dosimetry, Optimization and FMEA of Total Skin Electron Irradiation (TSEI)

Maya Shariff; Willi Stillkrieg; Michael Lotter; Daniel Lohmann; Thomas Weissmann; Rainer Fietkau; Christoph Bert

doi:10.1016/j.zemedi.2021.09.004

Dosimetry, Optimization and FMEA of Total Skin Electron Irradiation (TSEI)

Z Med Phys. 2022 May;32(2):228-239. doi: 10.1016/j.zemedi.2021.09.004. Epub 2021 Nov 2.

Authors

Maya Shariff¹, Willi Stillkrieg², Michael Lotter², Daniel Lohmann², Thomas Weissmann², Rainer Fietkau², Christoph Bert²

Affiliations

¹ Department of Radiation Oncology, Universitätsklinikum Erlangen, Friedrich-Alexander-Universität Erlangen-Nürnberg, Universitätsstraße 27, 91054, Erlangen, Germany; Comprehensive Cancer Center Erlangen-EMN (CCC ER-EMN), Erlangen, Germany. Electronic address: maya.shariff@uk-erlangen.de.
² Department of Radiation Oncology, Universitätsklinikum Erlangen, Friedrich-Alexander-Universität Erlangen-Nürnberg, Universitätsstraße 27, 91054, Erlangen, Germany; Comprehensive Cancer Center Erlangen-EMN (CCC ER-EMN), Erlangen, Germany.

Abstract

Purpose: Total Skin Electron Irradiation (TSEI) is a method for treating malignant cutaneous T-cell lymphomas. This work aims to implement and optimize the total skin technique established at Strahlenklinik Erlangen, Germany on two new linear accelerators and to quantify the risks using failure mode and effects (FMEA) analysis.

Material and methods: TSEI is performed at a VersaHD accelerator (Elekta, Stockholm) with 6MeV in the "high dose rate mode" HDRE and a nominal field size of 40×40cm². To reach the entire skin surface, the patients perform 6 different body positions at a distance of 330cm behind an acrylic scatter plate, with two overlapping irradiation fields being radiated at 2 gantry angles per position. The irradiation technique was commissioned according to the recommendation of AAPM report 23. With the help of a reference profile at 270°, 2 gantry angles were calculated, which in total resulted in an optimal dose distribution. This was metrologically verified with ion-chamber measurements in the patient's longitudinal axis. The influence of the shape of the acrylic scatter plate and the distance between the acrylic scatter plate and patient was determined by measurements. The dose homogeneity was verified using an anthropomorphic disc phantom equipped with GafChromic films. The workflows and failure modes of the total skin technique were described in a process map and subsequently quantified with a FMEA analysis.

Results: An optimal dose distribution is achieved at a distance of SSD=330cm, using the gantry angles 289° and 251°. The previously used segmented acrylic scatter plate was replaced by a flat plate (200×120×0.5cm³), which is placed at a distance of 50cm in front of the patient. The densitometric evaluation of the GafChromic films in the anthropomorphic disc phantom revealed an expected dose distribution of 3Gy at a depth of up to 1.5cm below the skin surface, with a homogeneity of ±10% over the phantom's longitudinal axis. By FMEA a maximum risk priority number of 30 was determined.

Conclusion: Based on the calculations and measurements performed on the new accelerators as well as the risk analysis, we concluded that total skin therapy can be implemented clinically.

Keywords: Dosimetry; FMEA; HDRE; Mycosis fungoides; Quality assurance; Total Skin Electron Irradiation (TSEI).

MeSH terms

Electrons*
Humans
Particle Accelerators
Phantoms, Imaging
Radiometry* / methods
Radiotherapy Dosage
Skin / radiation effects
Whole-Body Irradiation