Your search keyword '"Steve G. Azevedo"' showing total 2 results

1. Using data fusion to characterize breast tissue

Author

Richard R. Leach, Jeffrey E. Mast, Peter Littrup, James V. Candy, Steve G. Azevedo, Nebojsa Duric, Thomas A. Moore, Earle Holsapple, and David H. Chambers

Subjects

medicine.medical_specialty, Scanner, Breast tissue, Materials science, business.industry, Dynamic range, Ultrasound, Resolution (electron density), Sensor fusion, Speed of sound, medicine, Radiology, Sensitivity (control systems), business, Biomedical engineering

Abstract

New ultrasound data, obtained with a circular experimental scanner, are compared with data obtained with standard X-ray CT. Ultrasound data obtained by scanning fixed breast tissue were used to generate images of sound speed and reflectivity. The ultrasound images exhibit approximately 1 mm resolution and about 20 dB of dynamic range. All data were obtained in a circular geometry. X-ray CT scans were used to generate X-ray images corresponding to the same 'slices' obtained with the ultrasound scanner. The good match of sensitivity, resolution and angular coverage between the ultrasound and X-ray data makes possible a direct comparison of the three types of images. We present the results of such a comparison for an excised breast fixed in formalin. The results are presented visually using various types of data fusion. A general correspondence between the sound speed, reflectivity and X-ray morphologies is found. The degree to which data fusion can help characterize tissue is assessed by examining the quantitative correlations between the ultrasound and X-ray images.

Published

2002

2. Characterizing tissue with acoustic parameters derived from ultrasound data

Author

Thomas A. Moore, Earle Holsapple, Peter Littrup, Steve G. Azevedo, Nebojsa Duric, Richard R. Leach, David H. Chambers, Jeffrey E. Mast, and James V. Candy

Subjects

Scanner, Optics, Materials science, business.industry, Scattering, Attenuation, Speed of sound, Acoustics, Ultrasound, Full field, Tissue characterization, business, Reflectivity

Abstract

In contrast to standard reflection ultrasound (US), transmission US holds the promise of more thorough tissue characterization by generating quantitative acoustic parameters. We compare results from a conventional US scanner with data acquired using an experimental circular scanner operating at frequencies of 0.3 - 1.5 MHz. Data were obtained on phantoms and a normal, formalin-fixed, excised breast. Both reflection and transmission-based algorithms were used to generate images of reflectivity, sound speed and attenuation.. Images of the phantoms demonstrate the ability to detect sub-mm features and quantify acoustic properties such as sound speed and attenuation. The human breast specimen showed full field evaluation, improved penetration and tissue definition. Comparison with conventional US indicates the potential for better margin definition and acoustic characterization of masses, particularly in the complex scattering environments of human breast tissue. The use of morphology, in the context of reflectivity, sound speed and attenuation, for characterizing tissue, is discussed.

Published

2002