Registration of 2D cardiac images to real-time 3D ultrasound volumes for 3D stress echocardiography

Registration of 2D cardiac images to real-time 3D ultrasound volumes for 3D stress echocardiography

Three-dimensional (3D) stress echocardiography is a novel technique for diagnosing cardiac dysfunction, by comparing wall motion of the left ventricle under different stages of stress. For quantitative comparison of this motion, it is essential to register the ultrasound data. We propose an intensit...

Teljes leírás

Elmentve itt :
Bibliográfiai részletek
Szerzők: Leung KYE
Van Stralen M
Voormolen MM
Van Burken G
Nemes Attila
Ten Cate FJ
Geleijnse ML
De Jong N
Van Der Steen AFW
Reiber JHC
Bosch JG
Dokumentumtípus: Könyv része
Megjelent: International Society for Optics and Photonics (SPIE) Bellingham (WA) 2006
Sorozat:Progress in Biomedical Optics and Imaging - Proceedings of SPIE 6144 No. 6144 I
Medical Imaging 2006: Image Processing 6144 No. 6144 I
Tárgyszavak:
Klinikai orvostan
doi:10.1117/12.652107

mtmt:2121663
Online Access:http://publicatio.bibl.u-szeged.hu/30753
Leíró adatok
Tartalmi kivonat:Three-dimensional (3D) stress echocardiography is a novel technique for diagnosing cardiac dysfunction, by comparing wall motion of the left ventricle under different stages of stress. For quantitative comparison of this motion, it is essential to register the ultrasound data. We propose an intensity based rigid registration method to retrieve two-dimensional (2D) four-chamber (4C), two-chamber, and short-axis planes from the 3D data set acquired in the stress stage, using manually selected 2D planes in the rest stage as reference. The algorithm uses the Nelder-Mead simplex optimization to find the optimal transformation of one uniform scaling, three rotation, and three translation parameters. We compared registration using the SAD, SSD, and NCC metrics, performed on four resolution levels of a Gaussian pyramid. The registration's effectiveness was assessed by comparing the 3D positions of the registered apex and mitral valve midpoints and 4C direction with the manually selected results. The registration was tested on data from 20 patients. Best results were found using the NCC metric on data downsampled with factor two: mean registration errors were 8.1mm, 5.4mm, and 8.0° in the apex position, mitral valve position, and 4C direction respectively. The errors were close to the interobserver (7.1mm, 3.8mm, 7.4°) and intraobserver variability (5.2mm, 3.3mm, 7.0°), and better than the error before registration (9.4mm, 9.0mm, 9.9°). We demonstrated that the registration algorithm visually and quantitatively improves the alignment of rest and stress data sets, performing similar to manual alignment. This will improve automated analysis in 3D stress echocardiography.
Terjedelem/Fizikai jellemzők:12
614418-1-614418-12
ISBN:0819464236; 9780819464231

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