Artificial neural networks for positioning of gamma interactions in monolithic PET detectors

Decuyper, Milan; Stockhoff, Mariele; Vandenberghe, Stefaan; Holen, Roel Van

doi:10.1088/1361-6560/abebfc

Cited by 26 publications

(17 citation statements)

References 29 publications

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“…It has been published that modern readout architectures have implemented this hardware coincidence unit entirely in software due to the constantly increasing performance of computers [36,37,62]. This allows a higher degree of freedom in processing the data, in particular to use varying acceptance angles or more advanced methods from statistics or machine learning [20,29,67].…”

Section: Detector Data Acquisition and Processingmentioning

confidence: 99%

Hybrid total-body pet scanners—current status and future perspectives

Nadig

Herrmann

Mottaghy

et al. 2021

Eur J Nucl Med Mol Imaging

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Purpose Since the 1990s, PET has been successfully combined with MR or CT systems. In the past years, especially PET systems have seen a trend towards an enlarged axial field of view (FOV), up to a factor of ten. Methods Conducting a thorough literature research, we summarize the status quo of contemporary total-body (TB) PET/CT scanners and give an outlook on possible future developments. Results Currently, three human TB PET/CT systems have been developed: The PennPET Explorer, the uExplorer, and the Biograph Vision Quadra realize aFOVs between 1 and 2 m and show a tremendous increase in system sensitivity related to their longer gantries. Conclusion The increased system sensitivity paves the way for short-term, low-dose, and dynamic TB imaging as well as new examination methods in almost all areas of imaging.

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Section: Detector Data Acquisition and Processingmentioning

confidence: 99%

Hybrid total-body pet scanners—current status and future perspectives

Nadig

Herrmann

Mottaghy

et al. 2021

Eur J Nucl Med Mol Imaging

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“…NNs have also been used to estimate the twodimensional interaction position in the monolithic scintillator crystal in PET imagers, or a three-dimensional position when the depth of interaction (DoI) is estimated as well. The investigated NNs have yielded results with better spatial resolution [37,122], higher uniformity across the crystal volume [98] or faster implementation [149] compared to other existing methods (e.g. maximum likelihood [112] or nearest neighbours [141], among many others).…”

Section: Deep Learning In Nuclear Imagingmentioning

confidence: 98%

Artificial Intelligence for Monte Carlo Simulation in Medical Physics

et al. 2021

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Monte Carlo simulation of particle tracking in matter is the reference simulation method in the field of medical physics. It is heavily used in various applications such as 1) patient dose distribution estimation in different therapy modalities (radiotherapy, protontherapy or ion therapy) or for radio-protection investigations of ionizing radiation-based imaging systems (CT, nuclear imaging), 2) development of numerous imaging detectors, in X-ray imaging (conventional CT, dual-energy, multi-spectral, phase contrast … ), nuclear imaging (PET, SPECT, Compton Camera) or even advanced specific imaging methods such as proton/ion imaging, or prompt-gamma emission distribution estimation in hadrontherapy monitoring. Monte Carlo simulation is a key tool both in academic research labs as well as industrial research and development services. Because of the very nature of the Monte Carlo method, involving iterative and stochastic estimation of numerous probability density functions, the computation time is high. Despite the continuous and significant progress on computer hardware and the (relative) easiness of using code parallelisms, the computation time is still an issue for highly demanding and complex simulations. Hence, since decades, Variance Reduction Techniques have been proposed to accelerate the processes in a specific configuration. In this article, we review the recent use of Artificial Intelligence methods for Monte Carlo simulation in medical physics and their main associated challenges. In the first section, the main principles of some neural networks architectures such as Convolutional Neural Networks or Generative Adversarial Network are briefly described together with a literature review of their applications in the domain of medical physics Monte Carlo simulations. In particular, we will focus on dose estimation with convolutional neural networks, dose denoising from low statistics Monte Carlo simulations, detector modelling and event selection with neural networks, generative networks for source and phase space modelling. The expected interests of those approaches are discussed. In the second section, we focus on the current challenges that still arise in this promising field.

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“…The main factors that could cause the performance differences between the two positioning algorithms are discussed in this section. The fraction of Compton scattered events is ~60% and has a large influence on the overall positioning performance (Decuyper et al 2021). The neural network is trained on many individual events while for the MNN database we use the mean of many signals which acts like a filter for PSFs of scattered events.…”

Section: Discussionmentioning

confidence: 99%

“…Most commonly used positioning algorithms are statistical ones, such as maximum likelihood estimation (Pierce et al 2018, Ling et al 2007, España et al 2014), k-nearest neighbour (van Dam et al 2011, Borghi et al 2016a, and more recently other machine learning algorithms like gradient tree boosting (Müller et al 2018) and neural networks (Wang et al 2013, Bruyndonckx et al 2004, Iborra et al 2019, Decuyper et al 2021. Multiple detector designs have been evaluated with respect to spatial resolution.…”

Section: Introductionmentioning

confidence: 99%

High-resolution monolithic LYSO detector with 6-layer depth-of-interaction for clinical PET

et al. 2021

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The system spatial resolution of whole-body positron emission tomography (PET) is limited to around 2 mm due to positron physics and the large diameter of the bore. To stay below this 'physics'limit a scintillation detector with an intrinsic spatial resolution of around 1.3 mm is needed. Currently used detector technology consists of arrays of 2.6-5 mm segmented scintillator pixels which are the dominant factor contributing to the system resolution. Pixelated detectors using smaller pixels exist but face major drawbacks in sensitivity, timing, energy resolution and cost. Monolithic continuous detectors, where the spatial resolution is determined by the shape of the light distribution on the photo detector array, are a promising alternative. Without having the drawbacks of pixelated detectors, monolithic ones can also provide depth-of-interaction (DOI) information. In this work we present a monolithic detector design aiming to serve high-resolution clinical PET systems while maintaining high sensitivity. A 50 x 50 x 16 mm 3 Lutetium-Yttrium oxyorthosilicate (LYSO) scintillation crystal with silicon photomultiplier (SiPM) back side readout is calibrated in singles mode by a collimated beam obtaining a reference dataset for the event positioning. A mean nearest neighbour (MNN) algorithm and an artificial neural network for positioning are compared. The targeted intrinsic detector resolution of 1.3 mm needed to reach a 2 mm resolution on system level was accomplished with both algorithms. The neural network achieved a mean spatial resolution of 1.14 mm FWHM for the whole detector and 1.02 mm in the centre (30 x 30 mm 2 ). The MNN algorithm performed slightly worse with 1.17 mm for the whole detector and 1.13 mm in the centre. The intrinsic DOI information will also result in uniform system spatial resolution over the full field of view.

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Artificial neural networks for positioning of gamma interactions in monolithic PET detectors

Cited by 26 publications

References 29 publications

Hybrid total-body pet scanners—current status and future perspectives

Hybrid total-body pet scanners—current status and future perspectives

Artificial Intelligence for Monte Carlo Simulation in Medical Physics

High-resolution monolithic LYSO detector with 6-layer depth-of-interaction for clinical PET

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