S76

ESTRO 36

_______________________________________________________________________________________________

Purpose or Objective

Particle therapy has many advantages over conventional

photon therapy, particularly for treating deep-seated solid

tumors due to its greater conformal energy deposition

achieved in the form of the Bragg peak (BP). Successful

treatment with protons and heavy ions depends largely on

knowledge of the relative biological effectiveness (RBE) of

the radiation produced by primary and secondary charged

particles. Different methods and approaches are used for

calculation of the RBE-weighted absorbed dose in

treatment planning system (TPS) for protons and heavy ion

therapy. The RBE derived based on microdosimetric

approach using the tissue equivalent proportional counter

(TEPC) measurements in

12

C therapy has been reported,

however large size of commercial TEPC is averaging RBE

which dramatically changes close to and in a distal part of

the BP that may have clinical impact. Moreover, the TEPC

cannot be used in current particle therapy technique using

pencil beam scanning (PBS) delivery due to pile up

problems associated with high dose rate in PBS.

Material and Methods

The Centre for Medical Radiation Physics (CMRP),

University of Wollongong, has developed new silicon-on-

insulator (SOI) microdosimeter with 3D sensitive volumes

(SVs) similar to biological cells, known as the “Bridge” and

“Mushroom” microdosimeters, to address the

shortcomings of the TEPC. The silicon microdosimeter

provides extremely high spatial resolution and can be used

for in-field and out-of-field measurements in both passive

scattering and PBS deliveries. The response of the

microdosimeter was studied in passive and scanning

proton and carbon therapy beam at Massachusetts General

Hospital (MGH), USA, Heavy Ion Medical Accelerator in

Chiba (HIMAC) and Gunma University Heavy Ion Medical

Center (GHMC), Japan, respectively.

Results

Fig 1a shows the dose mean lineal energy, and frequency

mean lineal energy, measured using the SOI

microdosimeter irradiated by the 131.08 MeV pencil

proton beam as a function of depth in water. The value

was around 2 keV/µm in the plateau region, then

approximately 3 to 5 keV/µm in the proximal part of the

BP, and increasing dramatically to 9 to 10 keV/µm at the

end of the BP. Fig 1b shows derived RBE along the BP for

2Gy dose delivered in a peak. Fig 2 shows the distribution

with depth for the 290 MeV/u

12

C ion pencil beam at

GHMC. The inset graph in the left corner of Fig. 2 shows a

detailed view of the distribution at the BP measured with

submillimetre spatial resolution. It can be seen that

the distribution at the peak illustrates the effect of ripple

filter used in this facility which is impossible to observe

with any TEPC based microdosimeters. RBE values and

dose equivalent obtained near the target volume are also

derived using the SOI microdosimeters and the results will

be presented in a full paper.

Conclusion

This work presented an application of SOI micodosimeters

for RBE determination in passive and scanning proton and

12

C ion therapy and silicon microdosimetry has

demonstrated a simple and fast method for routine Quality

Assurance in charged particle therapy.

OC-0153 Sensitivity evaluation of prompt γ-ray based

range verification with a slit camera

L. Nenoff

1

, M. Priegnitz

2

, A. Trezza

1

, J. Smeets

3

, G.

Janssens

3

, F. Vander Stappen

3

, L. Hotoiu

3

, D. Prieels

3

, W.

Enghardt

1,4,5,6

, G. Pausch

1,5

, C. Richter

1,4,5,6

1

OncoRay - National Center for Radiation Research in

Oncology, Faculty of Medicine and University Hospital

Carl Gustav Carus- Technische Universität Dresden-

Helmholtz-Zentrum Dresden - Rossendorf, Dresden,

Germany

2

Helmholtz-Zentrum Dresden-Rossendorf, Institute of

Radiation Physics, Dresden, Germany

3

Ion Beam Applications SA, Louvain-la-Neuve, Belgium

4

Faculty of Medicine and University Hospital Carl Gustav

Carus- Technische Universität Dresden, Department of

Radiation Oncology, Dresden, Germany

5

Helmholtz-Zentrum Dresden-Rossendorf, Institute of

Radiooncology, Dresden, Germany

6

German Cancer Consortium DKTK and German Cancer

Research Center DKFZ, Dresden, Germany

Purpose or Objective

The dose distribution and range of proton beams are

exceedingly prone to uncertainties and anatomical

changes, demanding for an in-vivo range verification. A

promising approach is prompt γ-ray imaging (PGI), which

was recently implemented clinically in Dresden using a so-

called PGI slit camera [1,2] in double scattering (DS).

However, the detectability of local range shifts, affecting

only part of the lateral field in DS, is limited. The spot-

wise dose deposition in pencil beam scanning (PBS)

promises a finer spatial resolution of range shifts. The

purpose of this study is to comprehensively investigate the

sensitivity to detect range shifts in DS and PBS using a head

phantom in a clinical setup.

Material and Methods

For a realistic brain tumor treatment, treatment plans in

DS and PBS (2 beams, 60 GyE, 2 GyE/fx), were created.