Comparison between Doppler echocardiography and hot-film anemometry in measuring the turbulent shear stress downstream of artificial mitral valves: a methodological study.
- Author:
Yi SUN
1
;
Rui-jie LI
;
Gan-niu LI
;
Bin LI
;
Yu WANG
;
Run-wei MA
;
Bai-hui YANG
;
Sen-lin LU
;
Gui-min ZHANG
Author Information
- Publication Type:Journal Article
- MeSH: Animals; Echocardiography, Doppler; methods; Heart Valve Prosthesis; Image Processing, Computer-Assisted; Mitral Valve; diagnostic imaging; surgery; Pulsatile Flow; Rheology; Stress, Mechanical; Swine
- From: Chinese Medical Journal 2013;126(11):2174-2178
- CountryChina
- Language:English
-
Abstract:
BACKGROUNDTurbulent shear stress (TSS) plays an important role in the research of fluid dynamics of heart valves. This study aimed to perform a quantitative study of TSS downstream of porcine artificial mitral valves in order to verify the correlation of hot-film anemometry (HFA) and Doppler echocardiography combined with computer-aided image analysis for the detection of TSS.
METHODSA porcine model of mitral valve replacement was established. HFA and Doppler ultrasound techniques were used to directly and indirectly measure TSS-relevant parameters of the artificial mitral valve following different mitral valve replacements: different approaches were used to reserve the subvalvular apparatus of the mitral valve. A correlation analysis was then carried out.
RESULTSThere was a significant correlation between the HFA and Doppler ultrasound combined with computer-aided image analysis of the TSS at the same time and at the same site. No significant difference was found in the TSS measured by the two methods.
CONCLUSIONSCompared with HFA, Doppler echocardiography combined with computer-aided image analysis is a safe, non-invasive, and real-time method that enables accurate and quantitative detection of TSS downstream in vivo, objectively reflecting the flow field downstream of the artificial mitral valve. Doppler ultrasound combined with computer-aided image analysis can be employed for quantitatively evaluating the downstream hemodynamic performance of the mitral valve.