Combining edge detection with speckle-tracking for cardiac strain assessment in 3D echocardiography

• Published in: 2008 IEEE Ultrasonics Symposium pp. 1959 - 1962
• Main Authors: Orderud, F., Kiss, G., Langeland, S., Remme, E.W., Torp, H.G., Rabben, S.I.
• Format: Conference Proceeding
• Language: English
• Published: IEEE 01.11.2008
• Subjects: Capacitive sensors; Cardiology; Deformable models; Echocardiography; Image edge detection; Materials science and technology; Myocardium; Shape control; Strain measurement; Ultrasonic imaging
• ISBN: 1424424283; 9781424424283
• ISSN: 1051-0117
• DOI: 10.1109/ULTSYM.2008.0483

In this paper, we extend a computationally efficient framework for tracking of deformable subdivision surfaces in 3D echocardiography with speckle-tracking measurements to track material points. Tracking is performed in a sequential state-estimation fashion, using an extended Kalman filter to update a subdivision surface in a two-step process: Edge-detection is first performed to update the model for changes in shape and position, followed by a second update based on displacement vectors from speckle-tracking with 3D block-matching. The latter speckle-tracking update will only have to correct for residual deformations after edge-detection. This both leads to increased accuracy and computational efficiency compared to usage of speckle-tracking alone. Automatic tracking is demonstrated in a 3D echocardiography simulation of an infarcted ventricle. The combination of edge-detection and speckle-tracking consistently improved tracking accuracy (RMS 0.483, 0.433, 0.511 mm in X,Y,Z) compared to speckle-tracking alone (RMS 0.663, 0.439, 0.613 mm). It also improved the qualitative agreement for color-coded strain meshes to ground truth, and more clearly identified the infarcted region.