7 research outputs found
Acousto-electrical speckle pattern in Lorentz force electrical impedance tomography
Ultrasound speckle is a granular texture pattern appearing in ultrasound
imaging. It can be used to distinguish tissues and identify pathologies.
Lorentz force electrical impedance tomography is an ultrasound-based medical
imaging technique of the tissue electrical conductivity. It is based on the
application of an ultrasound wave in a medium placed in a magnetic field and on
the measurement of the induced electric current due to Lorentz force. Similarly
to ultrasound imaging, we hypothesized that a speckle could be observed with
Lorentz force electrical impedance tomography imaging. In this study, we first
assessed the theoretical similarity between the measured signals in Lorentz
force electrical impedance tomography and in ultrasound imaging modalities. We
then compared experimentally the signal measured in both methods using an
acoustic and electrical impedance interface. Finally, a bovine muscle sample
was imaged using the two methods. Similar speckle patterns were observed. This
indicates the existence of an "acousto-electrical speckle" in the Lorentz force
electrical impedance tomography with spatial characteristics driven by the
acoustic parameters but due to electrical impedance inhomogeneities instead of
acoustic ones as is the case of ultrasound imaging
Homodyned-K quantitative ultrasound and machine learning for detection of lateral epicondylosis of the elbow
Lateral epicondylosis (LE) of the elbow is a common syndrome found among working-age individuals, leading to degenerative changes of the common extensor tendon (CET). Ultrasound (US) is well suited for the investigation of LE because of its relative affordability and good spatial resolution. Among quantitative ultrasound (QUS) imaging techniques, homodyned-K (HK) statistical modeling of the echo envelope aims at characterizing tissue microstructures. The goal of this study was to assess the potential of HK parameters in detecting LE. In this prospective study, 30 LE elbows in 27 patients and 24 asymptomatic elbows in 13 volunteers underwent US imaging of the CET and radial collateral ligament (RCL). After US imaging examination per clinical standard practice, a long-axis, 3-second loop of a radiofrequency US image sequence of the CET and RCL was acquired using a Terason t3000 US scanner (Teratech, Burlington, MA) equipped with a linear 12L5-MHz transducer. Three statistical parameters based on HK modeling were estimated on the CET region-of-interest: 1) mean intensity normalized by its maximum value; 2) reciprocal 1/α of the scatterer clustering parameter; 3) coherent-to-diffuse signal ratio k. Moreover, HK parametric maps were calculated on the CETRCL region based on local estimation of the same parameters, from which were extracted additional features, as well as area of the two regions. Random forest classifier modeling identified the most discriminating combination of 3 features or less. The best combination of features was: CET global estimate of 1/α, CETRCL area, and inter-quartile range of local estimate of k. The area under the receiver operating characteristic curve, sensitivity, and specificity of the QUS-based model were 0.82 (95% confidence interval [CI], 0.80–0.85), 0.73, and 0.79, respectively. These values are comparable with values obtained in a meta-analysis: pooled sensitivity of 0.82 (95% CI, 0.76–0.87) and pooled specificity of 0.66 (95% CI, 0.60–0.72) when using US in the diagnosis of suspected LE