AUTHOR=Ozoemelam Ikechi , van der Graaf Emiel , van Goethem Marc-Jan , Kapusta Maciej , Zhang Nan , Brandenburg Sytze , Dendooven Peter 

TITLE=Real-Time PET Imaging for Range Verification of Helium Radiotherapy

JOURNAL=Frontiers in Physics

VOLUME=8

YEAR=2020

URL=https://www.frontiersin.org/journals/physics/articles/10.3389/fphy.2020.565422

DOI=10.3389/fphy.2020.565422

ISSN=2296-424X

ABSTRACT=<p>Real-time range verification of particle beams is important for optimal exploitation of the tissue-sparing advantages of particle therapy. Positron Emission Tomography (PET) of the beam-induced positron emitters such as <sup>15</sup>O (T<sub>1/2</sub> = 122 s) and <sup>11</sup>C (T<sub>1/2</sub> = 1223 s) has been used for monitoring of therapy in both clinical and preclinical studies. However, the half-lives of these nuclides preclude prompt feedback, i.e., on a sub-second timescale, on dose delivery. The <italic>in vivo</italic> verification technique relying on the in-beam PET imaging of very short-lived positron emitters such as <sup>12</sup>N (T<sub>1/2</sub> = 11 ms), recently proposed and investigated in feasibility experiments with a proton beam, provides millimeter precision in range measurement a few tens of milliseconds after the start of an irradiation. With the increasing interest in helium therapy, it becomes relevant to study the feasibility of prompt feedback using PET also for helium beams. A recent study has demonstrated the production of very short-lived nuclides (T<sub>1/2</sub> = 10 ms attributed to <sup>12</sup>N and/or <sup>13</sup>O) during irradiation of water and graphite with helium ions. This work is aimed at investigating the range verification potential of imaging these very short-lived nuclides. PMMA targets were irradiated with a 90 AMeV <sup>4</sup>He pencil beam consisting of a series of pulses of 10 ms beam-on and 90 ms beam-off. Two modules of a modified Siemens Biograph mCT PET scanner (21 × 21 cm<sup>2</sup>), installed 25 cm apart, were used to image the beam-induced PET activity during the beam-off periods. For the irradiation of PMMA, we identify the very short-lived activity earlier observed to be <sup>12</sup>N (T<sub>1/2</sub> = 11.0 ms). The range precision determined from the <sup>12</sup>N activity profile that is measured after just one beam pulse was found to be 9.0 and 4.1 mm (1σ) with 1.3 × 10<sup>7</sup><sup>4</sup>He ions per pulse and 6.6 × 10<sup>7</sup><sup>4</sup>He ions per pulse, respectively. When considering 4.0 × 10<sup>7</sup><sup>4</sup>He ions, which is about the intensity of the most intense distal layer spot in a helium therapy plan, a range verification precision in PMMA of 5.7 mm (1σ) can be realized. The range precision scales approximately with the inverse square root of the number of <sup>4</sup>He ions, i.e., the relative statistical accuracy of the number of coincidence events. Thus, when summing data over about 10 distal layer spots, this study shows good prospects for obtaining 1.8 mm (1σ) precision in range verification, within 50 ms after the start of a helium irradiation by in-beam PET imaging (scanner 29% solid angle) of <sup>12</sup>N.</p>