Analytical model of DOI-induced time bias in ultra-fast scintillation detectors for TOF-PET

Toussaint, Maxime; Loignon-Houle, Francis; Dussault, Jean-Pièrre

doi:10.1088/1361-6560/ab038b

Cited by 21 publications

(31 citation statements)

References 54 publications

(51 reference statements)

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“…Two timestamps are used from the n timestamps dataset. The first timestamp t early is chosen among the first detected photons since they typically have the lowest statistical time variability (Gundacker et al 2015, Toussaint et al 2019. The second timestamp t late is chosen so that there is ideally the strongest DOI dependence on the time difference between the two timestamps.…”

Section: Single Time Difference Methodsmentioning

confidence: 99%

“…Simulations were performed using the analytical timing model described in Toussaint et al (2019) which deals separately with the light propagation time profiles as a function of DOI to keep separated the variance-related effects (emission, transport and photodetection) and the bias induced by DOI, then combined in a root mean squared error to describe the global timing error. The influence of DOI bias with detectors affected by a strong DOI impact was shown experimentally in Loignon-Houle et al (2020), validating the model presented in Toussaint et al (2019).…”

Section: Simulation Model and Parametersmentioning

confidence: 99%

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DOI estimation through signal arrival time distribution: a theoretical description including proof of concept measurements

et al. 2021

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The challenge to reach 10 ps coincidence time resolution (CTR) in time-of-flight positron emission tomography (TOF-PET) is triggering major efforts worldwide, but timing improvements of scintillation detectors will remain elusive without depth-of-interaction (DOI) correction in long crystals. Nonetheless, this momentum opportunely brings up the prospect of a fully time-based DOI estimation since fast timing signals intrinsically carry DOI information, even with a traditional singleended readout. Consequently, extracting features of the detected signal time distribution could uncover the spatial origin of the interaction and in return, provide enhancement on the timing precision of detectors. We demonstrate the validity of a time-based DOI estimation concept in two steps. First, experimental measurements were carried out with current LSO:Ce:Ca crystals coupled to FBK NUV-HD SiPMs read out by fast high-frequency electronics to provide new evidence of a distinct DOI effect on CTR not observable before with slower electronics. Using this detector, a DOI discrimination using a double-threshold scheme on the analog timing signal together with the signal intensity information was also developed without any complex readout or detector modification. As a second step, we explored by simulation the anticipated performance requirements of future detectors to efficiently estimate the DOI and we proposed four estimators that exploit either more generic or more precise features of the DOI-dependent timestamp distribution. A simple estimator using the time difference between two timestamps provided enhanced CTR. Additional improvements were achieved with estimators using multiple timestamps (e.g. kernel density estimation and neural network) converging to the Cramér-Rao lower bound developed in this work for a time-based DOI estimation. This two-step study provides insights on current and future possibilities in exploiting the timing signal features for DOI estimation aiming at ultra-fast CTR while maintaining detection efficiency for TOF PET.

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Section: Single Time Difference Methodsmentioning

confidence: 99%

Section: Simulation Model and Parametersmentioning

confidence: 99%

DOI estimation through signal arrival time distribution: a theoretical description including proof of concept measurements

et al. 2021

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“…In essence, three causes of time resolution loss are associated with optical transfer: (1) the dependence of the mean optical path length between the point of interaction  x and the photosensor on  x, which in conventional, high-aspect-ratio crystals introduces a DOI-dependent signal delay; (2) the spread in the optical path lengths of the first detected photons for given  x, which depends on the detector geometry and the properties of the optical interfaces; and (3) the dependence of this spread on  x. Equation (18) offers a measure of the best achievable CRT in the presence of these three effects (Toussaint et al 2019). A simple way to reduce all of them in a conventional TOF-PET detector would be to reduce the crystal length, but this is at odds with the FOM defined in equation (2).…”

Section: Novel Detector Designsmentioning

confidence: 99%

Physics and technology of time-of-flight PET detectors

Schaart

2021

Phys. Med. Biol.

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The imaging performance of clinical positron emission tomography (PET) systems has evolved impressively during the last ∼15 years. A main driver of these improvements has been the introduction of time-of-flight (TOF) detectors with high spatial resolution and detection efficiency, initially based on photomultiplier tubes, later silicon photomultipliers. This review aims to offer insight into the challenges encountered, solutions developed, and lessons learned during this period. Detectors based on fast, bright, inorganic scintillators form the scope of this work, as these are used in essentially all clinical TOF-PET systems today. The improvement of the coincidence resolving time (CRT) requires the optimization of the entire detection chain and a sound understanding of the physics involved facilitates this effort greatly. Therefore, the theory of scintillation detector timing is reviewed first. Once the fundamentals have been set forth, the principal detector components are discussed: the scintillator and the photosensor. The parameters that influence the CRT are examined and the history, state-of-the-art, and ongoing developments are reviewed. Finally, the interplay between these components and the optimization of the overall detector design are considered. Based on the knowledge gained to date, it appears feasible to improve the CRT from the values of 200-400 ps achieved by current state-of-the-art TOF-PET systems to about 100 ps or less, even though this may require the implementation of advanced methods such as time resolution recovery. At the same time, it appears unlikely that a system-level CRT in the order of ∼10 ps can be reached with conventional scintillation detectors. Such a CRT could eliminate the need for conventional tomographic image reconstruction and a search for new approaches to timestamp annihilation photons with ultra-high precision is therefore warranted. While the focus of this review is on timing performance, it attempts to approach the topic from a clinically driven perspective, i.e. bearing in mind that the ultimate goal is to optimize the value of PET in research and (personalized) medicine. Selected abbreviations and symbols BSR Backside readout C d Diode capacitance CFD Constant-fraction discriminator CRLB Cramér-Rao lower bound CRT Coincidence resolving time C q Parallel capacitance of quench resistor DCR Dark count rate DOI Depth of interaction dSiPM Digital silicon photomultiplier DSR Dual-sided readout

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“…Another factor not to be overlooked is the reduction in optical transfer time spread that has become possible due to the introduction of SiPMs. Section II.A discussed the three causes of time resolution loss that occur in non-infinitesimal scintillation crystals [28,36]. Each of these effects are minimized when as many of the scintillation photons as possible are transferred to the photosensor as quickly as possible.…”

Section: Optimization Of Scintillation Detector Designmentioning

confidence: 99%

Time of Flight in Perspective: Instrumental and Computational Aspects of Time Resolution in Positron Emission Tomography

Schaart

Schramm

Surti

2021

IEEE Trans. Radiat. Plasma Med. Sci.

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The first time-of-flight positron emission tomography (TOF-PET) scanners were developed as early as in the 1980s. However, the poor light output and low detection efficiency of TOF-capable detectors available at the time limited any gain in image quality achieved with these TOF-PET scanners over the traditional non-TOF PET scanners. The discovery of LSO and other Lu-based scintillators revived interest in TOF-PET and led to the development of a second generation of scanners with high sensitivity and spatial resolution in the mid-2000s. The introduction of the silicon photomultiplier (SiPM) has recently yielded a third generation of TOF-PET systems with unprecedented imaging performance. Parallel to these instrumentation developments, much progress has been made in the development of image reconstruction algorithms that better utilize the additional information provided by TOF. Overall, the benefits range from a reduction in image variance (SNR increase), through allowing joint estimation of activity and attenuation, to better reconstructing data from limited angle systems. In this work, we review these developments, focusing on three broad areas: (1) timing theory and factors affecting the time resolution of a TOF-PET system, (2) utilization of TOF information for improved image reconstruction, and (3) quantification of the benefits of TOF compared to non-TOF PET. Finally, we offer a brief outlook on the TOF-PET developments anticipated in the short and longer term. Throughout this work, we aim to maintain a clinically-driven perspective, treating TOF as one of multiple (and sometimes competitive) factors that can aid in the optimization of PET imaging performance.

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Analytical model of DOI-induced time bias in ultra-fast scintillation detectors for TOF-PET

Cited by 21 publications

References 54 publications

DOI estimation through signal arrival time distribution: a theoretical description including proof of concept measurements

DOI estimation through signal arrival time distribution: a theoretical description including proof of concept measurements

Physics and technology of time-of-flight PET detectors

Time of Flight in Perspective: Instrumental and Computational Aspects of Time Resolution in Positron Emission Tomography

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