A Tracking Prior to Localization Workflow for Ultrasound Localization Microscopy

Alexis Leconte,Jonathan Poree,Brice Rauby,Alice Wu,Nin Ghigo,Paul Xing, Stephen Lee,Chloe Bourquin,Gerardo Ramos-Palacios,Abbas F Sadikot,Jean Provost

IEEE TRANSACTIONS ON MEDICAL IMAGING（2025）

Polytechnique Montréal Engineering Physics Department | McGill University Montreal Neurological Institute | Montreal Heart Institute Engineering Physics Department

Cited 1|Views23

Abstract

Ultrasound Localization Microscopy (ULM) has proven effective in resolving microvascular structures and local mean velocities at sub-diffraction-limited scales, offering high-resolution imaging capabilities. Dynamic ULM (DULM) enables the creation of angiography or velocity movies throughout cardiac cycles. Currently, these techniques rely on a Localization-and-Tracking (LAT) workflow consisting in detecting microbubbles (MB) in the frames before pairing them to generate tracks. While conventional LAT methods perform well at low concentrations, they suffer from longer acquisition times and degraded localization and tracking accuracy at higher concentrations, leading to biased angiogram reconstruction and velocity estimation. In this study, we propose a novel approach to address these challenges by reversing the current workflow. The proposed method, Tracking-and-Localization (TAL), relies on first tracking the MB and then performing localization. Through comprehensive benchmarking using both in silico and in vivo experiments and employing various metrics to quantify ULM angiography and velocity maps, we demonstrate that the TAL method consistently outperforms the reference LAT workflow. Moreover, when applied to DULM, TAL successfully extracts velocity variations along the cardiac cycle with improved repeatability. The findings of this work highlight the effectiveness of the TAL approach in overcoming the limitations of conventional LAT methods, providing enhanced ULM angiography and velocity imaging.

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Key words

Location awareness,Trajectory,Spatiotemporal phenomena,Standards,Ultrasonic imaging,Smoothing methods,Microscopy,Contrast ultrasound,ultrasound localization microscopy (ULM),super-resolution tracking

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