Litcius/Paper detail

Backscattering amplitude in ultrasound localization microscopy

Noémi Renaudin, Sophie Pezet, Nathalie Ialy-Radio, Charlie Demené, Mickaël Tanter

2023Scientific Reports17 citationsDOIOpen Access PDF

Abstract

In the last decade, Ultrafast ultrasound localisation microscopy has taken non-invasive deep vascular imaging down to the microscopic level. By imaging diluted suspensions of circulating microbubbles in the blood stream at kHz frame rate and localizing the center of their individual point spread function with a sub-resolution precision, it enabled to break the unvanquished trade-off between depth of imaging and resolution by microscopically mapping the microbubbles flux and velocities deep into tissue. However, ULM also suffers limitations. Many small vessels are not visible in the ULM images due to the noise level in areas dimly explored by the microbubbles. Moreover, as the vast majority of studies are performed using 2D imaging, quantification is limited to in-plane velocity or flux measurements which hinders the accurate velocity determination and quantification. Here we show that the backscattering amplitude of each individual microbubble can also be exploited to produce backscattering images of the vascularization with a higher sensitivity compared to conventional ULM images. By providing valuable information about the relative distance of the microbubble to the 2D imaging plane in the out-of-plane direction, backscattering ULM images introduces a physically relevant 3D rendering perception in the vascular maps. It also retrieves the missing information about the out-of-plane motion of microbubbles and provides a way to improve 3D flow and velocity quantification using 2D ULM. These results pave the way to improved visualization and quantification for 2D and 3D ULM.

Topics & Concepts

MicrobubblesMicroscopyRendering (computer graphics)UltrasoundVisualizationPoint spread functionAmplitudeImage resolutionFrame rateMaterials scienceOpticsResolution (logic)Biomedical engineeringPhysicsComputer scienceAcousticsComputer visionArtificial intelligenceMedicineUltrasound Imaging and ElastographyPhotoacoustic and Ultrasonic ImagingUltrasound and Hyperthermia Applications