Konrad Pawel Nesteruk scite author profile

Sc and Sc are positron emitter radionuclides that, in conjunction with the β emitter Sc, represent one of the most promising possibilities for theranostics in nuclear medicine. Their availability in suitable quantity and quality for medical applications is an open issue and their production with medical cyclotrons represents a scientific and technological challenge. For this purpose, an accurate knowledge of the production cross sections is mandatory. In this paper, we report on the cross section measurement of the reactionsCa(p,n)Sc, Ca(p,2n)Sc, Ti(p,α)Sc, and Ca(p,n)Sc at the Bern University Hospital cyclotron. A study of the production yield and purity performed by using commercially available enriched target materials is also presented.

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Commissioning of a clinical pencil beam scanning proton therapy unit for ultra‐high dose rates (FLASH)

Nesteruk

Togno

Großmann

et al. 2021

Medical Physics

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The purpose of this work was to provide a flexible platform for FLASH research with protons by adapting a former clinical pencil beam scanning gantry to irradiations with ultra-high dose rates. Methods: PSI Gantry 1 treated patients until December 2018. We optimized the beamline parameters to transport the 250 MeV beam extracted from the PSI COMET accelerator to the treatment room, maximizing the transmission of beam intensity to the sample. We characterized a dose monitor on the gantry to ensure good control of the dose, delivered in spot-scanning mode. We characterized the beam for different dose rates and field sizes for transmission irradiations. We explored scanning possibilities in order to enable conformal irradiations or transmission irradiations of large targets (with transverse scanning). Results: We achieved a transmission of 86% from the cyclotron to the treatment room. We reached a peak dose rate of 9000 Gy/s at 3 mm water equivalent depth, along the central axis of a single pencil beam. Field sizes of up to 5 × 5 mm 2 were achieved for single-spot FLASH irradiations. Fast transverse scanning allowed to cover a field of 16 × 1.2 cm 2 . With the use of a nozzle-mounted range shifter, we are able to span depths in water ranging from 19.6 to 37.9 cm. Various dose levels were delivered with precision within less than 1%. Conclusions: We have realized a proton FLASH irradiation setup able to investigate continuously a wide dose rate spectrum, from 1 to 9000 Gy/s in single-spot irradiation as well as in the pencil beam scanning mode. As such, we have developed a versatile test bench for FLASH research.

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Faraday cup for commissioning and quality assurance for proton pencil beam scanning beams at conventional and ultra-high dose rates

Winterhalter¹,

Togno²,

Nesteruk³

et al. 2021

Phys. Med. Biol.

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Recently, proton therapy treatments delivered with ultra-high dose rates have 19 been of high scientific interest, and the Faraday cup is a promising dosimetry 20 tool for such experiments. Different institutes use different Faraday cup designs, 21 and either a high voltage guard ring, or the combination of an electric and a 22 magnetic field is employed to minimize the effect of secondary electrons. The 23 authors first investigate these different approaches for beam energies of 70 MeV, 24 150 MeV, 230 MeV and 250 MeV, magnetic fields between 0 mT and 24 mT 25and voltages between -1000V to 1000V. When applying a magnetic field, the 26 measured signal is independent of the guard ring voltage, indicating that this 27 setting minimizes the effect of secondary electrons on the reading of the Faraday 28 cup. Without magnetic field, applying the negative voltage however decreases 29 the signal by an energy dependent factor up to 1.3% for the lowest energy tested 30 and 0.4% for the highest energy, showing an energy dependent response. Next, 31 the study demonstrates the application of the Faraday cup up to ultra-high dose 32 rates. Faraday cup measurements with cyclotron currents up to 800nA (dose 33 rates of up to approximately 1000 Gy/s) show that the Faraday cup is indeed 34 dose rate independent. Then, the Faraday cup is applied to commission the 35 primary gantry monitor for high dose rates. Finally, short-term reproducibility 36 of the monitor calibration is quantified within single days, showing a standard 37 deviation of 0.1% (one sigma). In conclusion, the Faraday cup is a promising, 38 dose rate independent tool for dosimetry up to ultra-high dose rates. Caution is 39 however necessary when using a Faraday cup without magnetic field, as a guard 40 ring with high voltage alone can introduce an energy dependent signal offset.

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A detector based on silica fibers for ion beam monitoring in a wide current range

et al. 2016

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A: A detector based on doped silica and optical fibers was developed to monitor the profile of particle accelerator beams of intensity ranging from 1 pA to tens of µA. Scintillation light produced in a fiber moving across the beam is measured, giving information on its position, shape and intensity. The detector was tested with a continuous proton beam at the 18 MeV Bern medical cyclotron used for radioisotope production and multi-disciplinary research. For currents from 1 pA to 20 µA, Ce 3+ and Sb 3+ doped silica fibers were used as sensors. Read-out systems based on photodiodes, photomultipliers and solid state photomultipliers were employed. Profiles down to the pA range were measured with this method for the first time. For currents ranging from 1 pA to 3 µA, the integral of the profile was found to be linear with respect to the beam current, which can be measured by this detector with an accuracy of ∼1%. The profile was determined with a spatial resolution of 0.25 mm. For currents ranging from 5 µA to 20 µA, thermal effects affect light yield and transmission, causing distortions of the profile and limitations in monitoring capabilities. For currents higher than ∼1 µA, non-doped optical fibers for both producing and transporting scintillation light were also successfully employed. K: Beam-line instrumentation (beam position and profile monitors; beam-intensity monitors; bunch length monitors); Instrumentation for particle accelerators and storage rings -low energy (linear accelerators, cyclotrons, electrostatic accelerators); Instrumentation for particle-beam therapy 1Corresponding author.

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Large energy acceptance gantry for proton therapy utilizing superconducting technology

et al. 2019

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When using superconducting (SC) magnets in a gantry for proton therapy, the gantry will benefit from some reduction in size and a large reduction in weight. In this contribution we show an important additional advantage of SC magnets in proton therapy treatments. We present the design of a gantry with a SC bending section and achromatic beam optics with a very large beam momentum acceptance of ±15%. Due to the related very large energy acceptance, approximately 70% of the treatments can be performed without changing the magnetic field for synchronization with energy modulation. In our design this is combined with a 2D lateral scanning system and a fast degrader mounted in the gantry, so that this gantry will be able to perform pencil beam scanning with very rapid energy variations at the patient, allowing a significant reduction of the irradiation time.We describe the iterative process we have applied to design the magnets and the beam transport, for which we have used different codes. COSY Infinity and OPAL have been used to design the beam transport optics and to track the particles in the magnetic fields, which are produced by the magnets designed in Opera. With beam optics calculations we have derived an optimal achromatic beam transport with the large momentum acceptance of the proton pencil beam and we show the agreement with particle tracking calculations in the 3D magnetic field map.A new cyclotron based facility with this gantry will have a significantly smaller footprint, since one can refrain from the degrader and energy selection system behind the cyclotron. In the treatments, this gantry will enable a very fast proton beam delivery sequence, which may be of advantage for treatments in moving tissue.

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