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Improving depth-of-interaction resolution in pixellated PET detectors using neural networks

Artem Zatcepin, M. Pizzichemi, Andrea Polesel, M. Paganoni, E. Auffray, Sibylle Ziegler, Negar Omidvari

2020Physics in Medicine and Biology22 citationsDOIOpen Access PDF

Abstract

Abstract Parallax error is a common issue in high-resolution preclinical positron emission tomography (PET) scanners as well as in clinical scanners that have a long axial field of view (FOV), which increases estimation uncertainty of the annihilation position and therefore degrades the spatial resolution. A way to address this issue is depth-of-interaction (DOI) estimation. In this work we propose two machine learning-based algorithms, a dense and a convolutional neural network (NN), as well as a multiple linear regression (MLR)-based method to estimate DOI in depolished PET detector arrays with single-sided readout. The algorithms were tested on an 8× 8 array of 1.53× 1.53× 15 mm 3 crystals and a 4× 4 array of 3.1× 3.1× 15 mm 3 crystals, both made of Ce:LYSO scintillators and coupled to a 4× 4 array of 3× 3 mm 3 silicon photomultipliers (SiPMs). Using the conventional linear DOI estimation method resulted in an average DOI resolution of 3.76 mm and 3.51 mm FWHM for the 8× 8 and the 4× 4 arrays, respectively. Application of MLR outperformed the conventional method with average DOI resolutions of 3.25 mm and 3.33 mm FWHM, respectively. Using the machine learning approaches further improved the DOI resolution, to an average DOI resolution of 2.99 mm and 3.14 mm FWHM, respectively, and additionally improved the uniformity of the DOI resolution in both arrays. Lastly, preliminary results obtained by using only a section of the crystal array for training showed that the NN-based methods could be used to reduce the number of calibration steps required for each detector array.

Topics & Concepts

Lyso-Silicon photomultiplierFull width at half maximumDetectorResolution (logic)Image resolutionParallaxConvolutional neural networkOpticsScintillatorPhysicsArtificial intelligenceComputer scienceArtificial neural networkMaterials scienceRadiation Detection and Scintillator TechnologiesMedical Imaging Techniques and ApplicationsAtomic and Subatomic Physics Research