For dose delivery, degradation and focusing of the lowest energy clinical beam are achieved by a dedicated beamline consisting of passive (degraders/collimators) and active (permanent magnet quadrupoles) components. For positioning and treatment planning, three solutions of proton imaging at different levels of technology readiness have been investigated. The first two feature spatially resolved detection of individual or integral proton energy deposition in commercial thin pixelated detectors. The last one relies on in-house built gas detectors for single particle tracking with residual range measurement. For range monitoring at isochronous cyclotron/synchrotron-based facilities, a dedicated in-beam positron emission tomography (PET) scanner of high spatial resolution and sensitivity has been developed, while ionoacoustics (i.e. sensing of thermoacoustic emissions) has been investigated for application at intense pulsed beams from synchrocyclotrons. Treatment planning is based on a research system from RaySearch Laboratories AB, tailored to the specificities of the SIRMIO beam and thoroughly validated against Monte Carlo simulations.
In the recently concluded experiments at the Danish Centre for Particle Therapy (DCPT), we could show the ability of the SIRMIO system to degrade and focus the incoming clinical proton beam with the lowest energy of 70 MeV and perform precision, image-guided delivery to homogenous and heterogeneous, mice-mimicking phantoms. For image guidance, proton radiography and tomography was successfully deployed and compared to prior X-ray cone beam computed tomography from an X-ray irradiator, while on-line monitoring of the treatment delivery was achieved with our dedicated in-beam PET scanner.
The objectives of the project could be fulfilled and future work will aim at automation/acceleration of the entire workflow of image-guided planning and delivery. The unique features of the newly developed system will pave the way to a new class of small animal experiments which we are currently planning with biologists. The project contributed to 38 BSc/MSc/PhD thesis (30 already completed) and over 50 contributions of peer reviewed papers and presentations at national and international conferences (with a few publications still in the pipeline). Moreover, we are currently exploring patenting and technology transfer possibilities with commercial key players in small animal radiation research. This has the twofold purpose to make the SIRMIO technologies available to more centres for advancing precision image-guided proton irradiation, as well as to explore possible application of some developments in the broader field of small animal irradiation with different beam qualities. Finally, the SIRMIO in-beam PET scanner will also serve as the key detector for in-vivo investigations with radioactive ion beams in the framework of another ERC project (BARB, grant agreement 883425, PI Prof. Marco Durante from GSI Darmstadt).