A Parallelizable Real-time Motion Tracking Algorithm with Applications to Ultrasonic Strain Imaging

Overview

Journal Phys Med Biol

Publisher IOP Publishing

Specialties Biophysics
Nuclear Medicine
Radiology

Date 2007 Aug 1

PMID 17664576

Citations 35

Authors

J Jiang

T J Hall

Affiliations

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Abstract

Ultrasound-based mechanical strain imaging systems utilize signals from conventional diagnostic ultrasound systems to image tissue elasticity contrast that provides new diagnostically valuable information. Previous works (Hall et al 2003 Ultrasound Med. Biol. 29 427, Zhu and Hall 2002 Ultrason. Imaging 24 161) demonstrated that uniaxial deformation with minimal elevation motion is preferred for breast strain imaging and real-time strain image feedback to operators is important to accomplish this goal. The work reported here enhances the real-time speckle tracking algorithm with two significant modifications. One fundamental change is that the proposed algorithm is a column-based algorithm (a column is defined by a line of data parallel to the ultrasound beam direction, i.e. an A-line), as opposed to a row-based algorithm (a row is defined by a line of data perpendicular to the ultrasound beam direction). Then, displacement estimates from its adjacent columns provide good guidance for motion tracking in a significantly reduced search region to reduce computational cost. Consequently, the process of displacement estimation can be naturally split into at least two separated tasks, computed in parallel, propagating outward from the center of the region of interest (ROI). The proposed algorithm has been implemented and optimized in a Windows system as a stand-alone ANSI C++ program. Results of preliminary tests, using numerical and tissue-mimicking phantoms, and in vivo tissue data, suggest that high contrast strain images can be consistently obtained with frame rates (10 frames s(-1)) that exceed our previous methods.

Citing Articles

Accelerating 3-D GPU-based Motion Tracking for Ultrasound Strain Elastography Using Sum-Tables: Analysis and Initial Results.

Peng B, Luo S, Xu Z, Jiang J Appl Sci (Basel). 2019; 9(10).

PMID: 31372306 PMC: 6675029. DOI: 10.3390/app9101991.

Efficient Two-Pass 3-D Speckle Tracking for Ultrasound Imaging.

Jeng G, Zontak M, Parajuli N, Lu A, Ta K, Sinusas A IEEE Access. 2019; 6:17415-17428.

PMID: 30740286 PMC: 6365000. DOI: 10.1109/ACCESS.2018.2815522.

A 3-D Region-Growing Motion-Tracking Method for Ultrasound Elasticity Imaging.

Wang Y, Jiang J, Hall T Ultrasound Med Biol. 2018; 44(8):1638-1653.

PMID: 29784436 PMC: 6026560. DOI: 10.1016/j.ultrasmedbio.2018.04.011.

Ultrasound 2D strain measurement for arm lymphedema using deformable registration: A feasibility study.

Yang X, Torres M, Kirkpatrick S, Curran W, Liu T PLoS One. 2017; 12(8):e0181250.

PMID: 28854199 PMC: 5576739. DOI: 10.1371/journal.pone.0181250.

Three-dimensional Ultrasound Elasticity Imaging on an Automated Breast Volume Scanning System.

Wang Y, Nasief H, Kohn S, Milkowski A, Clary T, Barnes S Ultrason Imaging. 2017; 39(6):369-392.

PMID: 28585511 PMC: 5643218. DOI: 10.1177/0161734617712238.