Calculation of strain values from strain rate curves: how should this be done?

Author

Hooge, J.D. ; Jamal, F. ; Bijnens, B. ; Heimdal, A. ; Thoen, J. ; van de Werf, F. ; Sutherland, G.R. ; Suetens, P.

Author_Institution

Med. Image Comput., Katholieke Univ., Leuven, Belgium

Volume

2

fYear

2000

fDate

36800

Firstpage

1269

Abstract

The noninvasive quantification of regional myocardial function is an important goal in clinical cardiology. Myocardial strain and strain rate indices are two methods of attempting to define regional myocardial function. Several approaches to extract these indices have been proposed in the literature, one of which is to extract the strain rate information as the spatial gradient in myocardial velocities that had been estimated using Doppler myocardial imaging techniques. In order to obtain information on the strain profile, the strain rate curve is time integrated. In practice however, the strain rate curves can be post-processed in several ways and different strain indices can be extracted. As no information exists on which scheme is advantageous, this paper attempts to define the optimal post-processing scheme for the clinical setting

Keywords

blood flow measurement; curve fitting; echocardiography; haemorheology; medical image processing; Doppler myocardial imaging; Lagrangian strain estimates; clinical cardiology; end systolic strain; noninvasive quantification; optimal postprocessing scheme; regional myocardial function; strain rate curves; strain values calculation; time integrated curve; Animals; Biomedical imaging; Capacitive sensors; Cardiology; Data acquisition; Data mining; Lagrangian functions; Myocardium; Physics computing; Robustness;

fLanguage

English

Publisher

ieee

Conference_Titel

Ultrasonics Symposium, 2000 IEEE

Conference_Location

San Juan

ISSN

1051-0117

Print_ISBN

0-7803-6365-5

Type

conf

DOI

10.1109/ULTSYM.2000.921554

Filename

921554