Impact of Acoustic Radiation Force Impulse Imaging in Clinical Practice of Patients after Orthotopic Liver Transplantation

The technical part of these Guidelines and Recommendations, produced under the auspices of EFSUMB, provides an introduction to the physical principles and technology on which all forms of current commercially available ultrasound elastography are based. A difference in shear modulus is the common underlying physical mechanism that provides tissue contrast in all elastograms. The relationship between the alternative technologies is considered in terms of the method used to take advantage of this. The practical advantages and disadvantages associated with each of the techniques are described, and guidance is provided on optimisation of scanning technique, image display, image interpretation and some of the known image artefacts. © Georg Thieme Verlag KG Stuttgart · New York.

Recurrence of hepatitis C after liver transplantation (LT) is the main cause of graft loss and retransplantation. Frequent liver biopsies are essential to follow-up hepatitis C virus (HCV)-induced liver damage. However, liver biopsy is an invasive and expensive procedure. We evaluated prospectively the diagnostic accuracy of noninvasive measurement of liver stiffness (by transient elastography) to assess the severity of hepatitis C recurrence after LT. For this purpose, we included 124 HCV-infected liver transplant recipients who underwent 169 liver biopsies and 129 hepatic hemodynamic studies with determination of hepatic venous pressure gradient (HVPG). Simultaneously, patients underwent measurement of liver stiffness. Liver fibrosis was mild (F0-F1) in 96 cases (57%) and significant (F2-F4) in 73 (43%). HVPG was normal ( or=6 mm Hg) in 60 (46%). Using a liver stiffness cutoff value of 8.5 kilopascals, the sensitivity, specificity, negative predictive value, and positive predictive value for diagnosis of fibrosis >or=F2 were 90%, 81%, 79%, and 92%, respectively. The area under the curve (AUC) for diagnosis of fibrosis >or=F2, >or=F3 and F4 were 0.90, 0.93, and 0.98, respectively. There was a close direct correlation between liver stiffness and HVPG (Pearson coefficient, 0.84; P or=6 mm Hg) was 0.93. Importantly, none of the individuals with liver stiffness below the cutoff value had either bridging fibrosis (F3) or cirrhosis (F4) or significant portal hypertension (HVPG >or=10 mm Hg). In conclusion, determination of liver stiffness is an extremely valuable tool to assess the severity of HCV recurrence after LT and in reducing the need of follow-up liver biopsies.

Acoustic radiation force based elasticity imaging methods are under investigation by many groups. These methods differ from traditional ultrasonic elasticity imaging methods in that they do not require compression of the transducer, and are thus expected to be less operator dependent. Methods have been developed that utilize impulsive (i.e. < 1 ms), harmonic (pulsed), and steady state radiation force excitations. The work discussed herein utilizes impulsive methods, for which two imaging approaches have been pursued: 1) monitoring the tissue response within the radiation force region of excitation (ROE) and generating images of relative differences in tissue stiffness (Acoustic Radiation Force Impulse (ARFI) imaging); and 2) monitoring the speed of shear wave propagation away from the ROE to quantify tissue stiffness (Shear Wave Elasticity Imaging (SWEI)). For these methods, a single ultrasound transducer on a commercial ultrasound system can be used to both generate acoustic radiation force in tissue, and to monitor the tissue displacement response. The response of tissue to this transient excitation is complicated and depends upon tissue geometry, radiation force field geometry, and tissue mechanical and acoustic properties. Higher shear wave speeds and smaller displacements are associated with stiffer tissues, and slower shear wave speeds and larger displacements occur with more compliant tissues. ARFI images have spatial resolution comparable to that of B-mode, often with greater contrast, providing matched, adjunctive information. SWEI images provide quantitative information about the tissue stiffness, typically with lower spatial resolution. A review these methods and examples of clinical applications are presented herein.