• DocumentCode
    1427885
  • Title

    Ultrafast compound doppler imaging: providing full blood flow characterization

  • Author

    Bercoff, Jeremy ; Montaldo, Gabriel ; Loupas, Thanasis ; Savery, David ; Mézière, Fabien ; Fink, Mathias ; Tanter, Mickael

  • Author_Institution
    R&D, Super-Sonic Imagine, Aix-en-Provence, France
  • Volume
    58
  • Issue
    1
  • fYear
    2011
  • fDate
    1/1/2011 12:00:00 AM
  • Firstpage
    134
  • Lastpage
    147
  • Abstract
    Doppler-based flow analysis methods require acquisition of ultrasound data at high spatio-temporal sampling rates. These rates represent a major technical challenge for ultrasound systems because a compromise between spatial and temporal resolution must be made in conventional approaches. Consequently, ultrasound scanners can either provide full quantitative Doppler information on a limited sample volume (spectral Doppler), or averaged Doppler velocity and/or power estimation on a large region of interest (Doppler flow imaging). In this work, we investigate a different strategy for acquiring Doppler information that can overcome the limitations of the existing Doppler modes by significantly reducing the required acquisition time. This technique is called ultrafast compound Doppler imaging and is based on the following concept: instead of successively insonifying the medium with focused beams, several tilted plane waves are sent into the medium and the backscattered signals are coherently summed to produce high-resolution ultrasound images. We demonstrate that this strategy allows reduction of the acquisition time by a factor of up to of 16 while keeping the same Doppler performance. Depending on the application, different directions to increase performance of Doppler analysis are proposed and the improvement is quantified: the ultrafast compound Doppler method allows faster acquisition frame rates for high-velocity flow imaging, or very high sensitivity for low-flow applications. Full quantitative Doppler flow analysis can be performed on a large region of interest, leading to much more information and improved functionality for the physician. By leveraging the recent emergence of ultrafast parallel beamforming systems, this paper demonstrates that breakthrough performances in flow analysis can be reached using this concept of ultrafast compound Doppler.
  • Keywords
    Doppler measurement; biomedical ultrasonics; blood flow measurement; data acquisition; high-speed optical techniques; medical image processing; spatiotemporal phenomena; ultrasonic imaging; Doppler flow imaging; averaged Doppler velocity; backscattered signals; blood flow characterization; high-resolution ultrasound images; high-velocity flow imaging; power estimation; spatio-temporal sampling rates; tilted plane waves; ultrafast compound Doppler imaging; ultrasound data acquisition; ultrasound scanners; Compounds; Doppler effect; Image color analysis; Image resolution; Imaging; Signal resolution; Ultrasonic imaging; Algorithms; Humans; Image Processing, Computer-Assisted; Phantoms, Imaging; Signal Processing, Computer-Assisted; Time Factors; Ultrasonography, Doppler;
  • fLanguage
    English
  • Journal_Title
    Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0885-3010
  • Type

    jour

  • DOI
    10.1109/TUFFC.2011.1780
  • Filename
    5688407