Copenhagen, Denmark
Onsite/Online

ESTRO 2022

Session Item

Saturday
May 07
09:00 - 10:00
Mini-Oral Theatre 1
01: Dosimetry
Catherine Khamphan, France;
Elise Konradsson, USA
Mini-Oral
Physics
The impact of ion chamber components on kB,Q for reference dosimetry in MRgRT
Julia Navarro Campos, The Netherlands
MO-0052

Abstract

The impact of ion chamber components on kB,Q for reference dosimetry in MRgRT
Authors:

Julia Navarro Campos1, Jacco de Pooter2, Leon de Prez2

1LUMC, Radiotherapy, Leiden, The Netherlands; 2VSL Dutch Metrology Institute, Ionising radiation, Delft, The Netherlands

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Purpose or Objective

For reference dosimetry in MRgRT, kB,Q is used to correct for the impact of the magnetic field on the chamber calibration coefficient. It has been demonstrated that for accurate simulation of kB,Q the dead volume (DV) must be considered. This work goes one step further by analysing the different contribution of all chamber components to kB,Q.

Material and Methods

Based on the blueprints the Farmer-type chamber PTW 30013 geometry was modelled in PENELOPE (2014). Two DVs were modelled; one based on published data (Pojtinger et al, 2019) (DV1) and one determined using FEM simulations (DV2). Radiation fields (10x10 cm2) were based on phase space files of a 60Co source and a 7MV MRI-linac. The model was validated against measurements with a setup using an electromagnet and a 60Co source (0 – 1.5 T) and an MRI-linac (0 and 1.5 T) (de Prez et al, 2019). Simulations were performed with the PENMAIN routine with magnetic field routines implemented for both parallel and perpendicular orientations of the chamber and the magnetic (B) field, and for several B-field strengths between 0 T and ±1.5 T. To study the dose contribution to the sensitive volume (SV = cavity – DV) from the electrons produced in certain components of the chamber (wall, central electrode (CE), guard, stem, phantom), the labelling of the particles was implemented in PENMAIN. A separate model with each solid component of the chamber modelled as liquid water (indicated by PTW 30013 (water)) was used to investigate the impact of material choice on kB,Q.

Results

The simulated kB,Q results agree better with the measured kB,Q when the DV is considered. The difference between measured kB,Q and simulated kB,Q reduces from at maximum 0.6% for DV1 to 0.4% for DV2 at B = 0.75 T in 60Co. This demonstrates the accuracy of the model, and it shows that small changes in the DV may have a small impact in the kB,Q.

 

Figures 1 and 2 show the relative contribution of each component to the effect of kB,Q (i.e., kB,Q-1). The negative value in the figure means an increase in the contribution from that component when the B is present.

 

Figure 1 demonstrates that the contribution to the SV dose from the bodies closer to the SV is higher than without B. For parallel orientation, the guard and the stem have higher impact on the dose to the SV. For the perpendicular orientation the wall contribution is more important. For all orientations the CE has a similar increased contribution


Figure 2 shows that the general behaviour of the contribution to the dose of the different components is similar. Overall, the impact to the dose in SV is reduced when the material of each component is modelled as liquid water.

Conclusion

Small components of the chamber impact kB,Q considerably. Therefore, chamber design and, to a lesser extent, choice of material affects kB,Q, and an accurate model of the chamber components and its further validation are important for correct calculations of kB,Q.