An off-line gating method for suppressing motion artifacts in ICUSsequence
Computers in Biology and Medicine
Real-time gating of IVUS sequences based on motion blur analysis: method and quantitative validation
MICCAI'10 Proceedings of the 13th international conference on Medical image computing and computer-assisted intervention: Part II
Manifold learning for image-based gating of intravascular ultrasound (IVUS) pullback sequences
MIAR'10 Proceedings of the 5th international conference on Medical imaging and augmented reality
Compensation of in-plane rigid motion for in vivo intracoronary ultrasound image sequence
Computers in Biology and Medicine
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Intracoronary UltraSound (IVUS) imaging allows to obtain high resolution images of internal part of coronary arteries. This tool is unique in the possibility to explore internal vessel structures of the coronary wall, being a powerful tool for diagnosis [1]. Since the coronary vessel is moving due to the periodical contraction and expansion of heart muscles, the acquired images present different artifacts. One of the most severe problems is the longitudinal oscillation of the IVUS catheter inside the vessel. To alleviate this problem, ECG-gating has been proposed. The goal of gating is to have subsequent frames that represent the internal vessel section in "stable" position and avoid the repetition of frames; that is to generate an image sequence in which the artifacts due to the heart beat have been removed while, possible translation due to vessel tortuosity can still be present. This paper presents a simple and efficient model of catheter longitudinal movement together with a fast and robust image based gating algorithm. Experimental results on 9 sequences from 7 patients, plus a comparison with ECG gating are presented.