TY - JOUR
T1 - Vessel recovery using ultrasound localisation microscopy: An in silico comparative study between minimum variance and delay-and-sum beamformers
AU - Voulgaridou, Vasiliki
AU - Nicolas, Barbara
AU - McDougall, Steven
AU - Arthur, Lachlan
AU - Papageorgiou, Georgios
AU - Butler, Mairead
AU - Kanoulas, Evangelos
AU - Diamantis, Konstantinos
AU - Lu, Weiping
AU - Sboros, Vassilis
N1 - Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.
PY - 2024/8/30
Y1 - 2024/8/30
N2 - The use of particle localisation and tracking algorithms on Contrast Enhanced Ultrasound (CEUS) or other ultrasound mode image data containing sparse microbubble (MB) populations, can produce super-resolved vascularization maps. Typically such data stem from conventional delay and sum (DAS) beamforming that is used widely in ultrasound imaging modes. Recently, adaptive beamforming has shown significant improvement in spatial resolution, but its value to super-resolution image analysis approaches is not fully understood. The in silico study here evaluates the performance of combining minimum variance beamformers (MV BF), established to provide improved lateral resolution, compared to DAS BFs with single particle detection. The isolated effect of a range of simplified image-affecting factors such as flow profile, pulse length, noise, vessel separations and data availability is considered. The study aims to assess the vessel recovery performance using the different beamformers and investigate the link with MB detection and localisation. The MV BF was shown to provide improved microvessel position accuracy compared to conventional DAS BFs. In particular, vessel separations between 0.3-4 λ provided superior localisation uncertainty with the MV. In addition, for a separation of 0.36λ, vessel recovery was achieved with both methods but the use of MV eliminated artifacts that appear as additional vessels. These results were found to be linked to improved MB detection and localisation for the MV BF, which is proposed as suitable for testing in Ultrasound Localisation Microscopy (ULM) imaging using patient data.
AB - The use of particle localisation and tracking algorithms on Contrast Enhanced Ultrasound (CEUS) or other ultrasound mode image data containing sparse microbubble (MB) populations, can produce super-resolved vascularization maps. Typically such data stem from conventional delay and sum (DAS) beamforming that is used widely in ultrasound imaging modes. Recently, adaptive beamforming has shown significant improvement in spatial resolution, but its value to super-resolution image analysis approaches is not fully understood. The in silico study here evaluates the performance of combining minimum variance beamformers (MV BF), established to provide improved lateral resolution, compared to DAS BFs with single particle detection. The isolated effect of a range of simplified image-affecting factors such as flow profile, pulse length, noise, vessel separations and data availability is considered. The study aims to assess the vessel recovery performance using the different beamformers and investigate the link with MB detection and localisation. The MV BF was shown to provide improved microvessel position accuracy compared to conventional DAS BFs. In particular, vessel separations between 0.3-4 λ provided superior localisation uncertainty with the MV. In addition, for a separation of 0.36λ, vessel recovery was achieved with both methods but the use of MV eliminated artifacts that appear as additional vessels. These results were found to be linked to improved MB detection and localisation for the MV BF, which is proposed as suitable for testing in Ultrasound Localisation Microscopy (ULM) imaging using patient data.
KW - Microbubble-tracking
KW - Minimum variance
KW - Super-resolution ultrasound
KW - Ultrasound beamforming
KW - Ultrasound contrast imaging
KW - Ultrasound localisation microscopy
UR - http://www.scopus.com/inward/record.url?scp=85203664683&partnerID=8YFLogxK
U2 - 10.1016/j.ultras.2024.107451
DO - 10.1016/j.ultras.2024.107451
M3 - Article
C2 - 39276632
SN - 0041-624X
VL - 145
JO - Ultrasonics
JF - Ultrasonics
M1 - 107451
ER -