Evaluation of a pixelated large format CMOS sensor for x‐ray microbeam radiotherapy

Flynn, Samuel; Price, Tony; Allport, Philip Patrick; Patallo, Ileana Silvestre; Thomas, Russell; Subiel, Anna; Bartzsch, Stefan; Treibel, Franziska; Ahmed, Mabroor; Jacobs-Headspith, Jon; Edwards, Tim; Jones, Isaac; Cathie, Dan; Guerrini, N.; Sedgwick, I.

doi:10.1002/mp.13971

Cited by 7 publications

(6 citation statements)

References 44 publications

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“…Due to their high spatial resolution, the MIMOSA-28 sensors are well suited for precision particle fluence measurements [21], similar to those required for characterizing the fluence profile at the MBC slits. This corroborates previous works on X-ray minibeam therapy [18] and pMBRT [19], which already indicated promising potential of CMOS technology for providing high-resolution dosimetry in minibeam experiments. The CMOS sensor high resolution revealed a shoulder at the base of the slit lateral fluence profiles at small distance to the collimator exit (Figure 4d), stemming from edge scattering effects at the corners of the MBC slits.…”

Section: Discussionsupporting

confidence: 91%

“…Experimental characterization of the brass MBC was performed with clinical carbon ion beams at the Marburg Ion-Beam Therapy Center (MIT), employing a high-resolution CMOS monolithic active pixel sensor, the MIMOSA-28 [17] sensor originally developed for the STAR experiment at RHIC. CMOS sensors have been presented in the literature to be useful tools for X-ray minibeam experiments [18] and recently also for pMBRT [19]. The MIMOSA-28 sensor employed in our study has already been characterized for various incident ion beams [20], demonstrating its capability of discerning secondaries and primaries based on their energy loss in the sensor.…”

Section: Introductionmentioning

confidence: 91%

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Investigating Slit-Collimator-Produced Carbon Ion Minibeams with High-Resolution CMOS Sensors

et al. 2023

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Particle minibeam therapy has demonstrated the potential for better healthy tissue sparing due to spatial fractionation of the delivered dose. Especially for heavy ions, the spatial fractionation could enhance the already favorable differential biological effectiveness at the target and the entrance region. Moreover, spatial fractionation could even be a viable option for bringing ions heavier than carbon back into patient application. To understand the effect of minibeam therapy, however, requires careful conduction of pre-clinical experiments, for which precise knowledge of the minibeam characteristics is crucial. This work introduces the use of high-spatial-resolution CMOS sensors to characterize collimator-produced carbon ion minibeams in terms of lateral fluence distribution, secondary fragments, track-averaged linear energy transfer distribution, and collimator alignment. Additional simulations were performed to further analyze the parameter space of the carbon ion minibeams in terms of beam characteristics, collimator positioning, and collimator manufacturing accuracy. Finally, a new concept for reducing the neutron dose to the patient by means of an additional neutron shield added to the collimator setup is proposed and validated in simulation. The carbon ion minibeam collimator characterized in this work is used in ongoing pre-clinical experiments on heavy ion minibeam therapy at the GSI.

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 91%

Investigating Slit-Collimator-Produced Carbon Ion Minibeams with High-Resolution CMOS Sensors

et al. 2023

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“…Relative Dose (log) manufacturer [43], and the film response would be especially sensitive to any slight miscalibration in this region. This again highlights the versatility of sensitive CMOS detectors for measurement of low dose valleys as previously demonstrated for x-ray microbeams [25].…”

Section: Jinst 18 P03014supporting

confidence: 64%

“…The vM2428 detector, also referred to as Athena or LASSENA [23], is a large-format Complementary Metal-Oxide-Semiconductor (CMOS) sensor designed for scientific and medical x-ray imaging. Although it was not designed for pMBRT, previous investigations at University College Hospitals London NHS Foundation Trust (UCLH) [24] have demonstrated that the detector was a viable candidate for use with proton beams, whilst the precursor to the vM2428 detector, the vM1212 detector, was found to be able to measure static and dynamic x-ray microbeams in a Small Animal Radiation Research Platform (SARRP) [25,26]. The vM2428 detector's specifications are described further in table 1.…”

Section: Cmos Detectormentioning

confidence: 99%

Development of CMOS dosimetry in proton minibeams for enhanced QA and primary standard absorbed dose calorimetry

et al. 2023

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Performing accurate and reliable dosimetry in spatially fractionated beams remains a significant challenge due to the steep dose gradients and microscopic scale of features. This results in many conventional detectors and instrumentation being unsuitable for online dosimetry, necessitating frequent offline validation using radiochromic film. In this study, the use of a Complementary Metal-Oxide-Semiconductor (CMOS) detector for evaluation of relative real-time dosimetry of proton minibeam radiation therapy (pMBRT) was investigated. The linearity of the CMOS detector was investigated by varying the proton beam current, with a comparison to a PTW 34001 Roos ionisation chamber used to carry out an independent check. It was found that the relative peaks and valleys of the pMBRT beam could be measured, with results comparable to EBT3XD film. The high sensitivity of the CMOS detector meant it was able to measure dose profiles from peak to valley regions, something not possible with the EBT3XD. The CMOS detector was compared to the treatment delivery log files, with correlation in beam position seen as the beam is scanned along each slit, but not across; and agreement in beam intensity, with the CMOS detector able to observe beam interruptions. Lastly, the CMOS detector was used in conjunction with the NPL primary-standard proton calorimeter (NPL PSPC) for a preliminary study on combining the NPL PSPC with high resolution temporal information about the incident pMBRT beam. The ultimate aim of this approach is to facilitate detailed thermal modelling to reduce the overall uncertainty in the absolute dose measured from the calorimeter. In these experiments, saturation in the CMOS pixels prevented further thermal modelling of the radiation induced heat flow, however the instantaneous dose rate was observed to be comparable with the predicted NPL PSPC response obtained by masking the CMOS detector.

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“…The generated x-rays traveled through a 0.8 mm beryllium window, aluminum or copper filters of different thickness, and a microbeam collimator (field size

, divergent slits of

[23] , [24] ), which was positioned 50 cm from the focal spot. The absorber thickness of the collimator was adjusted to the maximum photon energy for less than 0.25 % leakage radiation.…”

Section: Methodsmentioning

confidence: 99%

Clinical microbeam radiation therapy with a compact source: specifications of the line-focus X-ray tube

Winter

Galek

Matejcek

et al. 2020

Physics and Imaging in Radiation Oncology

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Background and purpose: Microbeam radiotherapy (MRT) is a preclinical concept in radiation oncology with arrays of alternating micrometer-wide high-dose peaks and low-dose valleys. Experiments demonstrated a superior normal tissue sparing at similar tumor control rates with MRT compared to conventional radiotherapy. Possible clinical applications are currently limited to large third-generation synchrotrons. Here, we investigated the line-focus X-ray tube as an alternative microbeam source. Materials and methods: We developed a concept for a high-voltage supply and an electron source. In Monte Carlo simulations, we assessed the influence of X-ray spectrum, focal spot size, electron incidence angle, and photon emission angle on the microbeam dose distribution. We further assessed the dose distribution of microbeam arc therapy and suggested to interpret this complex dose distribution by equivalent uniform dose. Results: An adapted modular multi-level converter can supply high-voltage powers in the megawatt range for a few seconds. The electron source with a thermionic cathode and a quadrupole can generate an eccentric, highpower electron beam of several 100 keV energy. Highest dose rates and peak-to-valley dose ratios (PVDRs) were achieved for an electron beam impinging perpendicular onto the target surface and a focal spot smaller than the microbeam cross-section. The line-focus X-ray tube simulations demonstrated PVDRs above 20. Conclusion: The line-focus X-ray tube is a suitable compact source for clinical MRT. We demonstrated its technical feasibility based on state-of-the-art high-voltage and electron-beam technology. Microbeam arc therapy is an effective concept to increase the target-to-entrance dose ratio of orthovoltage microbeams.

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Evaluation of a pixelated large format CMOS sensor for x‐ray microbeam radiotherapy

Cited by 7 publications

References 44 publications

Investigating Slit-Collimator-Produced Carbon Ion Minibeams with High-Resolution CMOS Sensors

Investigating Slit-Collimator-Produced Carbon Ion Minibeams with High-Resolution CMOS Sensors

Development of CMOS dosimetry in proton minibeams for enhanced QA and primary standard absorbed dose calorimetry

Clinical microbeam radiation therapy with a compact source: specifications of the line-focus X-ray tube

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