Digital radiofrequency echocardiography in the detection of myocardial contrast following intravenous administration of Albunex(R)

Abstract: Conventional contrast echo techniques have proved inadequate for the detection of myocardial perfusion using intravenously injected echo contrast agents because of the limitations and relative insensitivity of standard echocardiographic equipment. In order to avoid these problems, we have obtained pure digital radiofrequency ultrasound data from the left ventricle and myocardium during i.v. contrast myocardial perfusion echo studies. In 30 patients, following coronary arteriography, i.v. injections of the echo… Show more

“…Measurements of time-domain integrated backscatter [10,11] and the centroid frequency ofpower spectra [12][13][14][15][16][17][18][19] were performed on excised specimens of bovine tendon. This tissue type was chosen because the fibers are very weil aligned and one can readily vary the scattering and attenuation properties by changing the angle of insonification with respect to the predominant fiber orientation.…”

Effects of Inherent Tissue Anisotropy on Measurements Obtained with a Clinical Ultrasonic Imaging System

“…Measurements of time-domain integrated backscatter [10,11] and the centroid frequency ofpower spectra [12][13][14][15][16][17][18][19] were performed on excised specimens of bovine tendon. This tissue type was chosen because the fibers are very weil aligned and one can readily vary the scattering and attenuation properties by changing the angle of insonification with respect to the predominant fiber orientation.…”

Effects of Inherent Tissue Anisotropy on Measurements Obtained with a Clinical Ultrasonic Imaging System

“…However, when imaging air-filled microbubbles, the nonlinear factors (harmonics) impact the amplitude of the scattering properties. These acoustic factors include 1) medium properties: surface tension, viscosity, thermal transfers, and liquid and gas vapor pressures; 2) gas properties: molecular weight and gas solubility; 3) shell properties: elastic modulus, thickness, and damping effects; 4) ultrasound transceiver: high-speed digital interfaces (16,84,85), harmonics (70,71,90), and ultra-and subharmonics (10).…”

The powerful microbubble: from bench to bedside, from intravascular indicator to therapeutic delivery system, and beyond

“…Second harmonic imaging was originally developed as a technique to increase the sensitivity of detection of ultrasound contrast agents, [7][8][9] particularly when evaluating organ perfusion or to delineate cardiac chambers when assessing left ventricular function in patients with poor echocardiography windows. Ultrasound contrast agents usually consist of very small gas microspheres.…”

Second harmonic imaging: a new tune for an old fiddle?