Mingyi Tang , Yu-Qing Zhou , Mark C. Blaser , David A. Steinman , Craig A. Simmons
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引用次数: 0
Abstract
Objective
Abnormal hemodynamics is thought to play an essential role in the development of cardiovascular diseases. Mouse models are widely used for elucidating the underlying mechanisms; however, their small size and high heart rates make it difficult to perform quantitative flow velocity field mapping with sufficient temporal resolution. Our objective was to develop a noninvasive method for quantitative flow field mapping in mice based on speckle-tracking from high-frequency ultrasound B-mode imaging.
Methods
Ultrasound ECG-gated kilohertz visualization (EKV) was performed on a mouse-aorta-sized tubular flow phantom at frame rates up to 10,000 fps. Unexpected velocity underestimations were elucidated by simulating EKV reconstruction and performing ultrasound image velocimetry (UIV) in silico. A technique for error correction was developed and validated in vitro, and demonstrated in vivo.
Results
In flow phantoms, EKV-UIV underestimated velocity in the beam lateral direction by 50%–70%. This was attributed to loss of speckle contiguity owing to EKV's retrospective strip-based reconstruction of the two-dimensional B-mode image. The proposed correction technique reduced the errors to <10% by accounting only for speckle movement within each image strip. A preliminary in vivo study showed that vortex shapes and near-wall expansion movement inside a mouse left ventricle were more aligned with physical expectations after correction.
Conclusion
A novel technique was developed to quantitatively map blood flow with high spatiotemporal resolution. Further optimization will enable longitudinal studies in mice to gain insights on the role of local hemodynamic forces in the development of cardiovascular diseases.
期刊介绍:
Ultrasound in Medicine and Biology is the official journal of the World Federation for Ultrasound in Medicine and Biology. The journal publishes original contributions that demonstrate a novel application of an existing ultrasound technology in clinical diagnostic, interventional and therapeutic applications, new and improved clinical techniques, the physics, engineering and technology of ultrasound in medicine and biology, and the interactions between ultrasound and biological systems, including bioeffects. Papers that simply utilize standard diagnostic ultrasound as a measuring tool will be considered out of scope. Extended critical reviews of subjects of contemporary interest in the field are also published, in addition to occasional editorial articles, clinical and technical notes, book reviews, letters to the editor and a calendar of forthcoming meetings. It is the aim of the journal fully to meet the information and publication requirements of the clinicians, scientists, engineers and other professionals who constitute the biomedical ultrasonic community.
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