Tests of a Compton imaging prototype in a monoenergetic 4.44 MeV photon field—a benchmark setup for prompt gamma-ray imaging devices

The finite range of a proton beam in tissue opens new vistas for the delivery of a highly conformal dose distribution in radiotherapy. However, the actual particle range, and therefore the accurate dose deposition, is sensitive to the tissue composition in the proton path. Range uncertainties, resulting from limited knowledge of this tissue composition or positioning errors, are accounted for in the form of safety margins. Thus, the unverified particle range constrains the principle benefit of proton therapy. Detecting prompt γ-rays, a side product of proton-tissue interaction, aims at an on-line and non-invasive monitoring of the particle range, and therefore towards exploiting the potential of proton therapy. Compton imaging of the spatial prompt γ-ray emission is a promising measurement approach. Prompt γ-rays exhibit emission energies of several MeV. Hence, common radioactive sources cannot provide the energy range a prompt γ-ray imaging device must be designed for. In this work a benchmark measurement-setup for the production of a localized, monoenergetic 4.44 MeV γ-ray source is introduced. At the Tandetron accelerator at the HZDR, the proton-capture resonance reaction 15N(p,α γ4.439)12C is utilized. This reaction provides the same nuclear de-excitation (and γ-ray emission) occurrent as an intense prompt γ-ray line in proton therapy. The emission yield is quantitatively described. A two-stage Compton imaging device, dedicated for prompt γ-ray imaging, is tested at the setup exemplarily. Besides successful imaging tests, the detection efficiency of the prototype at 4.44 MeV is derived from the measured data. Combining this efficiency with the emission yield for prompt γ-rays, the number of valid Compton events, induced by γ-rays in the energy region around 4.44 MeV, is estimated for the prototype being implemented in a therapeutic treatment scenario. As a consequence, the detection efficiency turns out to be a key parameter for prompt γ-rays Compton imaging limiting the applicability of the prototype in its current realization.

[1]  R. Nutt,et al.  A Multicrystal Two Dimensional BGO Detector System for Positron Emission Tomography , 1986, IEEE Transactions on Nuclear Science.

[2]  Katia Parodi,et al.  Time-of-flight neutron rejection to improve prompt gamma imaging for proton range verification: a simulation study , 2012, Physics in medicine and biology.

[3]  Wolfgang Enghardt,et al.  Range assessment in particle therapy based on prompt γ-ray timing measurements , 2014, Physics in medicine and biology.

[4]  G Janssens,et al.  Prompt gamma imaging of proton pencil beams at clinical dose rate , 2014, Physics in medicine and biology.

[5]  Christian Iliadis,et al.  Nuclear physics of stars , 2007 .

[6]  A. Celler,et al.  Fast image reconstruction for Compton camera using stochastic origin ensemble approach. , 2010, Medical physics.

[7]  D Dauvergne,et al.  Assessment and improvements of Geant4 hadronic models in the context of prompt-gamma hadrontherapy monitoring , 2014, Physics in medicine and biology.

[8]  Antony Lomax,et al.  In vivo proton range verification: a review , 2013, Physics in medicine and biology.

[9]  Sam Beddar,et al.  Imaging of prompt gamma rays emitted during delivery of clinical proton beams with a Compton camera: feasibility studies for range verification. , 2015, Physics in medicine and biology.

[10]  Magdalena Rafecas,et al.  First Compton telescope prototype based on continuous LaBr3-SiPM detectors , 2013 .

[11]  D. Schardt,et al.  Magnetic scanning system for heavy ion therapy , 1993 .

[12]  Joao Seco,et al.  Proton range verification through prompt gamma-ray spectroscopy , 2014, Physics in medicine and biology.

[13]  Chan Hyeong Kim,et al.  Development of array-type prompt gamma measurement system for in vivo range verification in proton therapy. , 2012, Medical physics.

[14]  Denis Dauvergne,et al.  Development of a Compton camera for medical applications based on silicon strip and scintillation detectors , 2015 .

[15]  D Dauvergne,et al.  Design Guidelines for a Double Scattering Compton Camera for Prompt-$\gamma$ Imaging During Ion Beam Therapy: A Monte Carlo Simulation Study , 2011, IEEE Transactions on Nuclear Science.

[16]  Eric B. Norman,et al.  Cross sections relevant to gamma-ray astronomy: Proton induced reactions , 1981 .

[17]  Joao Seco,et al.  Simulation of prompt gamma-ray emission during proton radiotherapy , 2012, Physics in medicine and biology.

[18]  E. Grosse,et al.  Resonance strengths in the 14 N(p,) 15 O and 15 N(p,) 12 C reactions , 2010, 1005.1873.

[19]  D. R. Tilley,et al.  Energy Levels of Light Nuclei A =1 6 , 1993 .

[20]  Chan Hyeong Kim,et al.  Prompt gamma measurements for locating the dose falloff region in the proton therapy , 2006 .

[21]  Reuven Ramaty,et al.  Nuclear Deexcitation Gamma-Ray Lines from Accelerated Particle Interactions , 2001 .

[22]  F. Fiedler,et al.  Characterization of scintillator crystals for usage as prompt gamma monitors in particle therapy , 2015 .

[23]  H. Paganetti Range uncertainties in proton therapy and the role of Monte Carlo simulations , 2012, Physics in medicine and biology.

[24]  R. Wilson Radiological use of fast protons. , 1946, Radiology.

[25]  Wolfgang Enghardt,et al.  Test of Compton camera components for prompt gamma imaging at the ELBE bremsstrahlung beam , 2014 .

[26]  Sam Beddar,et al.  Evaluation of a stochastic reconstruction algorithm for use in Compton camera imaging and beam range verification from secondary gamma emission during proton therapy , 2012, Physics in medicine and biology.

[27]  Antti Saastamoinen,et al.  Measurement of characteristic prompt gamma rays emitted from oxygen and carbon in tissue-equivalent samples during proton beam irradiation , 2013, Physics in medicine and biology.

[28]  A. P. French,et al.  Angular distribution of gamma-rays and short-range alpha-particles from N15(p,αγ)C12 , 1953 .

[29]  Joao Seco,et al.  Energy- and time-resolved detection of prompt gamma-rays for proton range verification , 2013, Physics in medicine and biology.

[30]  Katia Parodi,et al.  Charged hadron tumour therapy monitoring by means of PET , 2004 .

[31]  Freek Beekman,et al.  Real-time prompt gamma monitoring in spot-scanning proton therapy using imaging through a knife-edge-shaped slit , 2012, Physics in medicine and biology.

[32]  Wolfgang Enghardt,et al.  Comparison of LSO and BGO block detectors for prompt gamma imaging in ion beam therapy , 2015 .

[33]  P. Busca,et al.  Prompt gamma imaging with a slit camera for real-time range control in proton therapy , 2012, 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record (NSS/MIC).

[34]  G Janssens,et al.  Real-time proton beam range monitoring by means of prompt-gamma detection with a collimated camera , 2014, Physics in medicine and biology.

[35]  T. Kormoll A Compton Camera for In-vivo Dosimetry in Ion-beam Radiotherapy , 2012 .