Impact of transcutaneous aortic valve implantation on myocardial deformation.

AIMS: To define the impact of transcutaneous aortic valve implantation (TAVI) using the CoreValve prosthesis on myocardial deformation in a serial echocardiographic study with analysis of strain and strain rate. METHODS: In 36 patients (83 ± 6 years; EuroScore: 26 ± 13%) with severe aortic stenosis scheduled for CoreValve implantation serial echocardiographic studies pre- and postintervention (within 1 month) were performed. Midparasternal short-axis and three apical views were acquired. Using customized computer software which allows automatic frame-by-frame tracking of acoustic markers during the heart cycle circumferential, radial, and longitudinal strain (CS, RS, and LS) and strain rate (CSR, RSR, and LSR) were calculated for each segment in a 16 segment model of the left ventricle. RESULTS: Longitudinal strain, systolic, and early diastolic longitudinal strain rate increased significantly within 1 month after TAVI (LS from -15.8 ± 3.6% to -17.6 ± 3.1%; P < 0.001; LSR(S) from -1.03 ± 0.21 s(-1) to -1.21 ± 0.19 s(-1); P < 0.001 and LSR (E) from -1.15 ± 0.42 s(-1) to 1.51 ± 0.44 s(-1); P < 0.001). Circumferential strain and strain rate values remained unchanged after CoreValve implantation. RS (29.1 ± 17.1 to 34.0 ± 15.8%; ns), RSR (S) (1.56 ± 0.69 to 1.91 ± 0.87 s(-1); ns) and RSR(E) (-1.56 ± 0.78 to -1.81 ± 0.82 s(-1); ns) increased only nonsignificantly after TAVI. Analysis of covariance showed only chronic kidney disease to have a relevant impact on early diastolic LSR (P = 0.01). CONCLUSIONS: Mainly longitudinal mechanics respond to unloading of the left ventricle after TAVI for severe aortic stenosis while radial and circumferential deformation is substantially unchanged. Pacemaker implantation or onset of left bundle brunch block after TAVI do not influence early myocardial deformation parameters.

Comparison of direct planimetry of mitral valve regurgitation orifice area by three-dimensional transesophageal echocardiography to effective regurgitant orifice area obtained by proximal flow convergence method and vena contracta area determined by color Doppler echocardiography.

Direct measurement of anatomic regurgitant orifice area (AROA) by 3-dimensional transesophageal echocardiography was evaluated for analysis of mitral regurgitation (MR) severity. In 72 patients (age 70.6 ± 13.3 years, 37 men) with mild to severe MR, 3-dimensional transesophageal echocardiography and transthoracic color Doppler echocardiography were performed to determine AROA by direct planimetry, effective regurgitant orifice area (EROA) by proximal convergence method, and vena contracta area (VCA) by 2-dimensional color Doppler echocardiography. AROA was measured with commercially available software (QLAB, Philips Medical Systems, Andover, Massachusetts) after adjusting the first and second planes to reveal the smallest orifice in the third plane where planimetry could take place. AROA was classified as circular or noncircular by calculating the ratio of the medial-lateral distance above the anterior-posterior distance (≤1.5 compared to >1.5). AROA determined by direct planimetry was 0.30 ± 0.20 cm², EROA determined by proximal convergence method was 0.30 ± 0.20 cm², and VCA was 0.33 ± 0.23 cm². Correlation between AROA and EROA (r = 0.96, SEE 0.058 cm²) and between AROA and VCA (r = 0.89, SEE 0.105 cm²) was high considering all patients. In patients with a circular regurgitation orifice area (n = 14) the correlation between AROA and EROA was better (r = 0.99, SEE 0.036 cm²) compared to patients with noncircular regurgitation orifice area (n = 58, r = 0.94, SEE 0.061 cm²). Correlation between AROA and EROA was higher in an EROA ≥0.2 cm² (r = 0.95) than in an EROA <0.2 cm² (r = 0.60). In conclusion, direct measurement of MR AROA correlates well with EROA by proximal convergence method and VCA. Agreement between methods is better for patients with a circular regurgitation orifice area than in patients with a noncircular regurgitation orifice area.

Myocardial rotation but not circumferential strain is transducer angle dependent: a speckle tracking echocardiography study.

BACKGROUND: Doppler derived strain analysis has been shown to be angle dependent. Speckle tracking analysis using 2D echocardiographic images is thought to provide angle independent parameters of regional and global myocardial function. This study sought to evaluate whether myocardial circumferential strain and rotation derived from automatic frame-by-frame tracking of natural acoustic markers is dependent on angulation of the transducer. METHODS: In 48 healthy volunteers (mean age 36 ± 3 years, 20 male) parasternal short-axis views at apical level were obtained as follows: at the standard parasternal position (5th intercostal space) with a most possible circular short-axis image of the left ventricle (angulation 1), at an angulation of the transducer by 20° from this standard position to the apex (angulation 2) and at an angulation of the transducer by 20° to the base of the left ventricle (angulation 3). Using an automatic frame-by-frame tracking system of natural acoustic echocardiographic markers (EchoPAC, GE Ultrasound, Horton, Norway) circumferential strain and rotation were calculated for six segments within a short-axis circumference. RESULTS: Image quality was sufficient for acquisition and analysis of images at all three-transducer angulation in 90% of the analyzed segments. Rotation was measured to be 7.7 ± 1.2° at angulation 1, 2.7 ± 0.9° at angulation 2 and 4.3 ± 1.1° at angulation 3 (p < 0.05). Average circumferential strain data was found to be -27.2 ± 5.1% at angulation 1, -26.5 ± 3.8% at angulation 2 and 28.9 ± 4.4% at angulation 3 (p = 0.287). CONCLUSION: Circumferential strain analysis is not dependent on transducer angulation. In contrast, determination of myocardial rotation is dependent on transducer angulation. Therefore, accurate transducer angulation has to be taken care of if rotation measurements are performed.