TU-F-CAMPUS-J-02: Developing a Phenomenological Model of the Proton Trajectory Within a Heterogeneous Medium Required for Proton Imaging

Collins-Fekete, C; Doolan, Paul; Dias, M; Beaulieu, Luc; Seco, Joao

doi:10.1118/1.4925822

Cited by 3 publications

(3 citation statements)

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“…Recently, Collins-Fekete et al [9] revisited and extended the Bayesian approach to work for the estimation of heavier ions trajectories. Additionally, the complex, time-consuming MLP algorithm was linked to the recent, more efficient phenomenological approach [8]. The algorithm uses cubic splines and includes the information of the Water Equivalent Path Length (WEPL) and the Water Equivalent Thickness (WET) to derive an accurate path estimate.…”

Section: The Most Likely Path Algorithmmentioning

confidence: 99%

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Stopping power accuracy and achievable spatial resolution of helium ion imaging using a prototype particle CT detector system

Volz

Collins-Fekete

Piersimoni

et al. 2017

Current Directions in Biomedical Engineering

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A precise relative stopping power map of the patient is crucial for accurate particle therapy. Charged particle imaging determines the stopping power either tomographically -particle computed tomography (pCT) -or by combining prior knowledge from particle radiography (pRad) and x-ray CT. Generally, multiple Coulomb scattering limits the spatial resolution. Compared to protons, heavier particles scatter less due to their lower charge/mass ratio. A theoretical framework to predict the most likely trajectory of particles in matter was developed for light ions up to carbon and was found to be the most accurate for helium comparing for fixed initial velocity. To further investigate the potential of helium in particle imaging, helium computed tomography (HeCT) and radiography (HeRad) were studied at the Heidelberg Ion-Beam Therapy Centre (HIT) using a prototype pCT detector system registering individual particles, originally developed by the U.S. pCT collaboration. Several phantoms were investigated: modules of the Catphan QA phantom for analysis of spatial resolution and achievable stopping power accuracy, a paediatric head phantom (CIRS) and a custommade phantom comprised of animal meat enclosed in a 2 % agarose mixture representing human tissue. The pCT images were reconstructed applying the CARP iterative reconstruction algorithm. The MTF 10% was investigated using a sharp edge gradient technique. HeRad provides a spatial resolution above that of protons (MTF10 10% =6.07 lp/cm for HeRad versus MTF 10% =3.35 lp/cm for proton radiography). For HeCT, the spatial resolution was limited by the number of projections acquired (90 projections for a full scan). The RSP accuracy for all inserts of the Catphan CTP404 module was found to be 2.5% or better and is subject to further optimisation. In conclusion, helium imaging appears to offer higher spatial resolution compared to proton imaging. In future studies, the advantage of helium imaging compared to other imaging modalities in clinical applications will be further explored.

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Section: The Most Likely Path Algorithmmentioning

confidence: 99%

“…To overcome the problem of MCS, various path estimation algorithms have been proposed for protons, of which the most likely path (MLP) algorithm is the most widely used [4][5][6][7][8]. Compared to protons, heavier ions suffer less from MCS, due to on average smaller deflection angles per scattering.…”

Section: Introductionmentioning

confidence: 99%

Stopping power accuracy and achievable spatial resolution of helium ion imaging using a prototype particle CT detector system

Volz

Collins-Fekete

Piersimoni

et al. 2017

Current Directions in Biomedical Engineering

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show abstract

“…These systems measure residual energies of individual proton particles along with determining their location and angular direction using position sensitive detectors placed before and after the patients (Pemler et al 1999, Sipala et al 2011, Esposito et al 2018. This information, when complemented with a suitable path estimation model, can correct for proton scattering, leading to better prediction of proton trajectories within the tissues (Williams 2004, Collins-Fekete et al 2015. These systems are known to provide good quantitative and imaging resolution but can also be expensive because they require high-speed single-event detectors and have complex instrumentation (Schneider et al 2004, Amaldi et al 2011, Biegun et al 2016, Johnson et al 2017.…”

Section: Introductionmentioning

confidence: 99%

A proton imaging system using a volumetric liquid scintillator: a preliminary study

Darne

Alsanea

Robertson

et al. 2019

Biomed. Phys. Eng. Express

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With the expansion of proton radiotherapy for cancer treatments, it has become important to explore proton-based imaging technologies to increase the accuracy of proton treatment planning, alignment, and verification. The purpose of this study is to demonstrate the feasibility of using a volumetric liquid scintillator to generate proton radiographs at a clinically relevant energy (180 MeV) using an integrating detector approach. The volumetric scintillator detector is capable of capturing a wide distribution of residual proton beam energies from a single beam irradiation. It has the potential to reduce acquisition time and imaging dose compared to other proton radiography methods. The imaging system design is comprised of a volumetric (20 × 20 × 20 cm 3 ) organic liquid scintillator working as a residual-range detector and a charge-coupled device (CCD) placed along the beams'-eye-view for capturing radiographic projections. The scintillation light produced within the scintillator volume in response to a 3-dimensional distribution of residual proton beam energies is captured by the CCD as a 2-dimensional grayscale image. A light intensity-to-water equivalent thickness (WET) curve provided WET values based on measured light intensities. The imaging properties of the system, including its contrast, signal-to-noise ratio, and spatial resolution (0.19 line-pairs/mm) were determined. WET values for selected Gammex phantom inserts including solid water, acrylic, and cortical bone were calculated from the radiographs with a relative accuracy of −0.82%, 0.91%, and −2.43%, respectively. Image blurring introduced by system optics was accounted for, resulting in sharper image features. Finally, the system's ability to reconstruct proton CT images from radiographic projections was demonstrated

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A novel proton-integrating radiography system design using a monolithic scintillator detector: Experimental studies

Darne

Robertson

Alsanea

et al. 2022

Nuclear Instruments and Methods in Physics Research Section A:

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TU-F-CAMPUS-J-02: Developing a Phenomenological Model of the Proton Trajectory Within a Heterogeneous Medium Required for Proton Imaging

Cited by 3 publications

References 0 publications

Stopping power accuracy and achievable spatial resolution of helium ion imaging using a prototype particle CT detector system

Stopping power accuracy and achievable spatial resolution of helium ion imaging using a prototype particle CT detector system

A proton imaging system using a volumetric liquid scintillator: a preliminary study

A novel proton-integrating radiography system design using a monolithic scintillator detector: Experimental studies

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