On modeling the tissue response from ultrasonic B-scan images

• Published in: IEEE transactions on medical imaging Vol. 15; no. 4; pp. 479 - 490
• Main Authors: Abeyratne, U.R., Petropulu, A.P., Reid, J.M.
• Format: Journal Article
• Language: English
• Published: New York, NY IEEE 1996; Institute of Electrical and Electronics Engineers
• Subjects: Biological and medical sciences; Biological tissues; Biomedical engineering; Biomedical imaging; Computerized, statistical medical data processing and models in biomedicine; Frequency estimation; Higher order statistics; Life estimation; Liver; Medical sciences; Models and simulation; Radio frequency; Scattering; Ultrasonic imaging; Sonography; Human; B mode echography; B scan; Computer simulation; Periodicity; Experimental study; Radiofrequency; Scattering factor; Modeling; Tissue; Medical imagery; Microstructure
• ISSN: 0278-0062; 1558-254X
• DOI: 10.1109/42.511751

The authors model tissue as a collection of point scatterers embedded in a uniform media, and show that the higher-order statistics (HOS) of the scatterer spacing distribution can be estimated from digitized radio frequency (RF) scan line segments and be used in obtaining tissue signatures. The authors assume that RF echoes are non-Gaussian, on the grounds of empirical/theoretical justifications presented in the literature. Based on their model for tissue microstructure, the authors develop schemes for the estimation of reasonable periodicity as well as correlations among nonperiodic scatterers, Using HOS of the scattered signal, the authors define as tissue "color" a quantity that describes the scatterer spatial correlations, show how to evaluate it from the higher-order correlations of the digitized RF scan line segments, and investigate its potential as a tissue signature. The tools employed, i.e., HOS, were chosen as the most appropriate ones because they suppress Gaussian processes, such as the one arising from the diffused scatterers. HOS, unlike second-order statistics, also preserve the Fourier-phase of the signature, the color of the tissue response. Working on simulated and clinical data, the authors show that the proposed periodicity estimation technique is superior to the widely used power spectrum and cepstrum techniques in terms of the accuracy of estimations. The authors also show that even when there is no significant periodicity in data, they are still able to characterize tissues using signatures based on the higher-order cumulant structure of the scatterer spacing distribution.