@Article{Oliver_etal2013,
author="Oliver, J. F.
and Fuster-Garcia, E.
and Cabello, J.
and Tortajada, S.
and Rafecas, M.",
title="Application of Artificial Neural Network for Reducing Random Coincidences in PET",
journal="IEEE Transactions on Nuclear Science",
year="2013",
volume="60",
number="5",
pages="3399--3409",
abstract="Positron Emission Tomography (PET) is based on the detection in coincidence of the two photons created in a positron annihilation. In conventional PET, this coincidence identification is usually carried out through a coincidence electronic unit. An accidental coincidence occurs when two photons arising from different annihilations are classified as a coincidence. Accidental coincidences are one of the main sources of image degradation in PET. Some novel systems allow coincidences to be selected post-acquisition in software, or in real time through a digital coincidence engine in an FPGA. These approaches provide the user with extra flexibility in the sorting process and allow the application of alternative coincidence sorting procedures. In this work a novel sorting procedure based on Artificial Neural Network (ANN) techniques has been developed. It has been compared to a conventional coincidence sorting algorithm based on a time coincidence window. The data have been obtained from Monte-Carlo simulations. A small animal PET scanner has been implemented to this end. The efficiency (the ratio of correct identifications) can be selected for both methods. In one case by changing the actual value of the coincidence window used, and in the other by changing a threshold at the output of the neural network. At matched efficiencies, the ANN-based method always produces a sorted output with a smaller random fraction. In addition, two differential trends are found: the conventional method presents a maximum achievable efficiency, while the ANN-based method is able to increase the efficiency up to unity, the ideal value, at the cost of increasing the random fraction. Images reconstructed using ANN sorted data (no compensation for randoms) present better contrast, and those image features which are more affected by randoms are enhanced. For the image quality phantom used in the paper, the ANN method decreases the spill-over ratio by a factor of 18{\%}.",
optnote="WOS:000325827200027",
optnote="exported from refbase (https://references.ific.uv.es/refbase/show.php?record=1611), last updated on Fri, 08 Nov 2013 09:50:57 +0000",
issn="0018-9499",
doi="10.1109/TNS.2013.2274702",
opturl="https://doi.org/10.1109/TNS.2013.2274702"
}