Quantitative Assessment of Arterial Wall Biomechanical Properties Using Shear Wave Imaging

Quantitative Assessment of Arterial Wall Biomechanical Properties Using Shear Wave Imaging

Abstract A new ultrasound-based technique is proposed to assess the arterial stiffness: the radiation force of an ultrasonic beam focused on the arterial wall induces a transient shear wave (∼10 ms) whose propagation is tracked by ultrafast imaging. The large and high-frequency content (100 to 1500...

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Veröffentlicht in:Ultrasound in medicine & biology 2010-10, Vol.36 (10), p.1662-1676
Hauptverfasser: Couade, Mathieu, Pernot, Mathieu, Prada, Claire, Messas, Emmanuel, Emmerich, Joseph, Bruneval, Patrick, Criton, Aline, Fink, Mathias, Tanter, Mickael
Format: Artikel
Sprache:eng
Schlagworte:
Acoustic radiation force
Arterial stiffness
Biological and medical sciences
Biomechanical Phenomena
Biomechanics. Biorheology
Carotid Arteries - diagnostic imaging
Elastic Modulus
Elasticity
Elasticity Imaging Techniques - methods
Elastography
Feasibility Studies
Fundamental and applied biological sciences. Psychology
Humans
Image Processing, Computer-Assisted - methods
Phantoms, Imaging
Radiology
Reference Values
Shear Strength
Tissues, organs and organisms biophysics
Ultrasound
Vascular imaging
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Zusammenfassung:Abstract A new ultrasound-based technique is proposed to assess the arterial stiffness: the radiation force of an ultrasonic beam focused on the arterial wall induces a transient shear wave (∼10 ms) whose propagation is tracked by ultrafast imaging. The large and high-frequency content (100 to 1500 Hz) of the induced wave enables studying the wave dispersion, which is shown experimentally in vitro and numerically to be linked to arterial wall stiffness and geometry. The proposed method is applied in vivo . By repeating the acquisition up to 10 times per second (theoretical maximal frame rate is ∼100 Hz), it is possible to assess in vivo the arterial wall elasticity dynamics: shear modulus of a healthy volunteer carotid wall is shown to vary strongly during the cardiac cycle and measured to be 130 ± 15 kPa in systole and 80 ± 10 kPa in diastole. (E-mail: mathieu.couade@gmail.com )
ISSN:0301-5629
1879-291X
DOI:10.1016/j.ultrasmedbio.2010.07.004