Range shifter contribution to neutron exposure of patients undergoing proton pencil beam scanning

Maite Romero-Expósito; Malgorzata Liszka; Athanasia Christou; Iuliana Toma-Dasu; Alexandru Dasu

doi:10.1002/mp.16897

Range shifter contribution to neutron exposure of patients undergoing proton pencil beam scanning

Med Phys. 2023 Dec 19. doi: 10.1002/mp.16897. Online ahead of print.

Authors

Maite Romero-Expósito^{1

2}, Malgorzata Liszka¹, Athanasia Christou¹, Iuliana Toma-Dasu^{2

3}, Alexandru Dasu^{1

4}

Affiliations

¹ The Skandion Clinic, Uppsala, Sweden.
² Oncology Pathology Department, Karolinska Institutet, Solna, Sweden.
³ Medical Radiation Physics, Stockholm University, Stockholm, Sweden.
⁴ Medical Radiation Sciences, Department of Immunology, Genetics and Pathology, Uppsala University, Uppsala, Sweden.

PMID: 38112191
DOI: 10.1002/mp.16897

Abstract

Background: Superficial targets require the use of the lowest energies within the available energy range in proton pencil-beam scanning (PBS) technique. However, the lower efficiency of the energy selection system at these energies and the requirement of a greater number of layers may represent disadvantages for this approach. The alternative is to use a range shifter (RS) at nozzle exit. However, one of the concerns of using this beamline element is that it becomes an additional source of neutrons that could irradiate organs situated far from the target.

Purpose: The purpose of this study is to assess the increase in neutron dose due to the RS in proton PBS technique. Additionally, an analytical model for the neutron production is tested.

Methods: Two clinical plans, designed to achieve identical target coverage, were created for an anthropomorphic phantom. These plans consisted of a lateral field delivering an absorbed dose of 60 Gy (RBE) to the target. One of the plans employed the RS. The MCNP code was used to simulate the plans, evaluating the distribution of neutron dose equivalent (H_n ) and the equivalent dose in organ. In the plan with the RS plan, neutron production from both the patient and the RS were assessed separately. H_n values were also fitted versus the distance to field edge using a Gaussian function.

Results: H_n per prescription dose, in the plan using the RS, ranged between 1.4 and 3.7 mSv/Gy at the field edge, whereas doses at 40 cm from the edge ranged from 9.9 to 32 μSv/Gy. These values are 1.2 to 10 times higher compared to those obtained without the RS. Both this factor and the contribution of neutrons originating from the RS increases with the distance from field edge. A triple-Gaussian function was able to reproduce the equivalent dose in organs within a factor of 2, although underestimating the values.

Conclusions: The dose deposited in the patient by the neutrons originating from the RS predominantly affects areas away from the target (beyond approximately 25 cm from field edge), resulting in a neutron dose equivalent of the order of mSv. This indicates an overall low neutron contribution from the use of RS in PBS.

Keywords: analytical modelling; neutron dose equivalent; out-of-field dose; proton therapy.

Grants and funding

945196/Euratom's research and innovation programme 2019-2020