TY - JOUR
T1 - Super-resolution Ultrasound Localization Microscopy through Deep Learning
AU - van Sloun, Ruud J.G.
AU - Solomon, Oren
AU - Bruce, Matthew
AU - Khaing, Zin Z.
AU - Wijkstra, Hessel
AU - Eldar, Yonina C
AU - Mischi, Massimo
PY - 2021/3
Y1 - 2021/3
N2 - Ultrasound localization microscopy has enabled super-resolution vascular imaging through precise localization of individual ultrasound contrast agents (microbubbles) across numerous imaging frames. However, analysis of high-density regions with significant overlaps among the microbubble point spread responses yields high localization errors, constraining the technique to low-concentration conditions. As such, long acquisition times are required to sufficiently cover the vascular bed. In this work, we present a fast and precise method for obtaining super-resolution vascular images from high-density contrast-enhanced ultrasound imaging data. This method, which we term Deep Ultrasound Localization Microscopy (Deep-ULM), exploits modern deep learning strategies and employs a convolutional neural network to perform localization microscopy in dense scenarios, learning the nonlinear image-domain implications of overlapping RF signals originating from such sets of closely spaced microbubbles. Deep-ULM is trained effectively using realistic on-line synthesized data, enabling robust inference in-vivo under a wide variety of imaging conditions. We show that deep learning attains super-resolution with challenging contrast-agent densities, both in-silico as well as in-vivo. Deep-ULM is suitable for real-time applications, resolving about 70 high-resolution patches (128×128 pixels) per second on a standard PC. Exploiting GPU computation, this number increases to 1250 patches per second.
AB - Ultrasound localization microscopy has enabled super-resolution vascular imaging through precise localization of individual ultrasound contrast agents (microbubbles) across numerous imaging frames. However, analysis of high-density regions with significant overlaps among the microbubble point spread responses yields high localization errors, constraining the technique to low-concentration conditions. As such, long acquisition times are required to sufficiently cover the vascular bed. In this work, we present a fast and precise method for obtaining super-resolution vascular images from high-density contrast-enhanced ultrasound imaging data. This method, which we term Deep Ultrasound Localization Microscopy (Deep-ULM), exploits modern deep learning strategies and employs a convolutional neural network to perform localization microscopy in dense scenarios, learning the nonlinear image-domain implications of overlapping RF signals originating from such sets of closely spaced microbubbles. Deep-ULM is trained effectively using realistic on-line synthesized data, enabling robust inference in-vivo under a wide variety of imaging conditions. We show that deep learning attains super-resolution with challenging contrast-agent densities, both in-silico as well as in-vivo. Deep-ULM is suitable for real-time applications, resolving about 70 high-resolution patches (128×128 pixels) per second on a standard PC. Exploiting GPU computation, this number increases to 1250 patches per second.
KW - deep learning
KW - neural network
KW - super resolution
KW - Ultrasound
KW - ultrasound localization microscopy
UR - http://www.scopus.com/inward/record.url?scp=85102318453&partnerID=8YFLogxK
U2 - 10.1109/TMI.2020.3037790
DO - 10.1109/TMI.2020.3037790
M3 - Article
C2 - 33180723
SN - 0278-0062
VL - 40
SP - 829
EP - 839
JO - IEEE Transactions on Medical Imaging
JF - IEEE Transactions on Medical Imaging
IS - 3
M1 - 9257449
ER -