Abstract
Monolithic crystals are examined as an alternative to segmented scintillator arrays in positron emission tomography (PET). Monoliths provide good energy, timing and spatial resolution including intrinsic depth of interaction (DOI) encoding. DOI allows reducing parallax errors (radial astigmatism) at off-center positions within a PET ring. We present a novel DOI-estimation approach based on the supervised machine learning algorithm gradient tree boosting (GTB). GTB builds predictive regression models based on sequential binary comparisons (decision trees). GTB models have been shown to be implementable in FPGA if the memory requirement fits the available resources. We propose two optimization scenarios for the best possible positioning performance: One restricting the available memory to enable a future FPGA implementation and one without any restrictions. The positioning performance of the GTB models is compared with a DOI estimation method based on a single DOI observable (SO) comparable to other methods presented in literature. For a 12 mm high monolith, we achieve an averaged spatial resolution of 2.15 mm and 2.12 mm FWHM for SO and GTB models, respectively. In contrast to SO models, GTB models show a nearly uniform positioning performance over the whole crystal depth.
Highlights
P OSITRON emission tomography (PET) is a functional imaging technique with a variety of applications in both preclinical as well as clinical research and practice [1], [2]
For all depth of interaction (DOI) observables, a SR ranging from 1 to 5 mm FWHM is reported while a SR better than 2 mm FWHM is only shown within 2 mm distance to the photosensor
We presented two DOI positioning methods based on a side irradiation conducted with a fan beam collimator
Summary
P OSITRON emission tomography (PET) is a functional imaging technique with a variety of applications in both preclinical as well as clinical research and practice [1], [2]. Two 511 keV gamma particles originating from a positronelectron annihilation are registered by radiation detectors arranged in a ring geometry. State-of-the-art radiation detectors consist of scintillation crystals (e.g., BGO, LSO, and LYSO) converting the gamma particles to optical photons and photosensor arrays with multiple channels detecting the optical photons. Manuscript received August 15, 2018; revised October 6, 2018; accepted November 20, 2018. Date of publication November 30, 2018; date of current version July 1, 2019.
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