2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC) 2018
DOI: 10.1109/embc.2018.8513486
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Respiratory Motion Correction Using A Novel Positron Emission Particle Tracking Technique: A Framework Towards Individual Lesion-Based Motion Correction

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Cited by 4 publications
(3 citation statements)
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“…( 4) Data-driven gating techniques -instead of using hardware-driven motion correction strategies (as described in previous sections), new methods are being explored using data-driven software analysis. Some examples include (a) motion characterization directly from a patient's gated scan using the signal to create a single optimal bin, and leading to conformal adaptive imaging [101], and (b) motion information extraction from the reconstructed images [102]. The real-time data-driven motion correction, as opposed to post-processing methods, represents an important innovation in the speed of processing data for clinical practice [103].…”
Section: Respiratory Motion Correctionmentioning
confidence: 99%
“…( 4) Data-driven gating techniques -instead of using hardware-driven motion correction strategies (as described in previous sections), new methods are being explored using data-driven software analysis. Some examples include (a) motion characterization directly from a patient's gated scan using the signal to create a single optimal bin, and leading to conformal adaptive imaging [101], and (b) motion information extraction from the reconstructed images [102]. The real-time data-driven motion correction, as opposed to post-processing methods, represents an important innovation in the speed of processing data for clinical practice [103].…”
Section: Respiratory Motion Correctionmentioning
confidence: 99%
“…When the particles are in the field of view, the positron-emitting traces are tracked, and the trajectories are reconstructed using the gamma rays detected by the gamma cameras and corresponding lines of response (LORs). PEPT particle tracking methods started with the Birmingham method [ 14 , 15 ], and have been expanded to include the line-density method [ 16 ], multiple location-allocation algorithm (MLAA) [ 17 , 18 ], K-Medoids [ 19 ], clustering methods [ 20 ], the feature point identification (FPI) method [ 21 ], Odo triangulation method [ 22 ], Voronoi-based multiple particle tracking (VMPT) [ 23 ], the time-of-flight PEPT (TOF-PEPT) algorithm to do motion correction in medical imaging [ 24 , 25 ] and recently-developed method of PEPT machine learning (PEPT-ML) which tracks multiple particles and does not require frame tracking [ 26 ].…”
Section: Introductionmentioning
confidence: 99%
“…PEPT has been mostly used in industrial applications such as flow patterns 30,31 and velocity measurements. 32 Other than our patent 33 and preliminary early work, [34][35][36] a variant of the PEPT algorithm was presented under the moniker positron emission tracking (PeTrack) for use in radiotherapy as well as cardiac PET studies using external markers. 37,38 PeTrack requires an initial estimate of the marker positions and has several user-defined threshold parameters.…”
Section: Introductionmentioning
confidence: 99%