Abstract 11516: Quantification of Regurgitation Through Dual Orifices: Pulsatile in Vitro Analysis with Echocardiography and MRI Assessment
IntroductionProximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow convergence (FC) zones are complicated with dual orifices, seen with mitral clipping. This study seeks to investigate how flow through one orifice affects PISA m...
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| Published in | Circulation (New York, N.Y.) Vol. 144; no. Suppl_1; p. A11516 |
|---|---|
| Main Authors | , , , , |
| Format | Journal Article |
| Language | English |
| Published |
Lippincott Williams & Wilkins
16.11.2021
|
| Online Access | Get full text |
| ISSN | 0009-7322 1524-4539 |
| DOI | 10.1161/circ.144.suppl_1.11516 |
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| Abstract | IntroductionProximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow convergence (FC) zones are complicated with dual orifices, seen with mitral clipping. This study seeks to investigate how flow through one orifice affects PISA measurement across the other to better quantify RVol in dual orifice conditions. Methods3D-printed dual circular orifice models with varying relative areas were integrated into a pulsatile flow phantom simulating left heart flow. One orifice (A) was standardized at 19.6 mm2 while the other (B) was 1X, 2X, and 3X the area of A in three models. Inter-orifice distance was 5 mm to emulate mitral clipping. Continuous wave doppler echocardiography measured peak velocity and velocity time integral. PISA was performed at four aliasing velocities normalized to peak velocity (Va/Vpeak) (10%, 8%, 4%, 2%) to compute RVol with 2D phase contrast MRI as reference. In each model, PISA RVol and percent error was calculated to see how varying the area of B impacts PISA accuracy of A. 4D flow MRI FC data was also collected to visualize the 3D formation of FC zones. ResultsUsing a high Va/Vpeak to create distinct FC zones provides a better RVol estimation with PISA, as low Va/Vpeak will merge the FC zones, overestimating flow across individual orifices. Single factor analysis of variance (ANOVA) of percent error of A across the three models showed no significant difference at high Va/Vpeak (8%p=0.80, 10%p=0.23), but significant difference at low Va/Vpeak (2%p=0.010, 4%p=0.005). High Va/Vpeak FC zones of orifices are independent from each other; PISA can be measured with standard practices and added together for an accurate total RVol. At low Va/Vpeak, FC orifice zones overlap with overestimation error increasing with larger B area. This finding suggests that resolving two separate FC zones to minimize flow interference is important for accurate RVol estimate in a dual orifice setting. |
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| AbstractList | Abstract only
Introduction:
Proximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow convergence (FC) zones are complicated with dual orifices, seen with mitral clipping. This study seeks to investigate how flow through one orifice affects PISA measurement across the other to better quantify RVol in dual orifice conditions.
Methods:
3D-printed dual circular orifice models with varying relative areas were integrated into a pulsatile flow phantom simulating left heart flow. One orifice (A) was standardized at 19.6 mm
2
while the other (B) was 1X, 2X, and 3X the area of A in three models. Inter-orifice distance was 5 mm to emulate mitral clipping. Continuous wave doppler echocardiography measured peak velocity and velocity time integral. PISA was performed at four aliasing velocities normalized to peak velocity (V
a
/V
peak
) (10%, 8%, 4%, 2%) to compute RVol with 2D phase contrast MRI as reference. In each model, PISA RVol and percent error was calculated to see how varying the area of B impacts PISA accuracy of A. 4D flow MRI FC data was also collected to visualize the 3D formation of FC zones.
Results:
Using a high V
a
/V
peak
to create distinct FC zones provides a better RVol estimation with PISA, as low V
a
/V
peak
will merge the FC zones, overestimating flow across individual orifices. Single factor analysis of variance (ANOVA) of percent error of A across the three models showed no significant difference at high V
a
/V
peak
(8%: p=0.80, 10%: p=0.23), but significant difference at low V
a
/V
peak
(2%: p=0.010, 4%: p=0.005). High V
a
/V
peak
FC zones of orifices are independent from each other; PISA can be measured with standard practices and added together for an accurate total RVol. At low V
a
/V
peak
, FC orifice zones overlap with overestimation error increasing with larger B area. This finding suggests that resolving two separate FC zones to minimize flow interference is important for accurate RVol estimate in a dual orifice setting. IntroductionProximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow convergence (FC) zones are complicated with dual orifices, seen with mitral clipping. This study seeks to investigate how flow through one orifice affects PISA measurement across the other to better quantify RVol in dual orifice conditions. Methods3D-printed dual circular orifice models with varying relative areas were integrated into a pulsatile flow phantom simulating left heart flow. One orifice (A) was standardized at 19.6 mm2 while the other (B) was 1X, 2X, and 3X the area of A in three models. Inter-orifice distance was 5 mm to emulate mitral clipping. Continuous wave doppler echocardiography measured peak velocity and velocity time integral. PISA was performed at four aliasing velocities normalized to peak velocity (Va/Vpeak) (10%, 8%, 4%, 2%) to compute RVol with 2D phase contrast MRI as reference. In each model, PISA RVol and percent error was calculated to see how varying the area of B impacts PISA accuracy of A. 4D flow MRI FC data was also collected to visualize the 3D formation of FC zones. ResultsUsing a high Va/Vpeak to create distinct FC zones provides a better RVol estimation with PISA, as low Va/Vpeak will merge the FC zones, overestimating flow across individual orifices. Single factor analysis of variance (ANOVA) of percent error of A across the three models showed no significant difference at high Va/Vpeak (8%p=0.80, 10%p=0.23), but significant difference at low Va/Vpeak (2%p=0.010, 4%p=0.005). High Va/Vpeak FC zones of orifices are independent from each other; PISA can be measured with standard practices and added together for an accurate total RVol. At low Va/Vpeak, FC orifice zones overlap with overestimation error increasing with larger B area. This finding suggests that resolving two separate FC zones to minimize flow interference is important for accurate RVol estimate in a dual orifice setting. |
| Author | Wu, Erik Mason, Oneil R Thomas, James D Lee, Jeesoo Markl, Michael |
| AuthorAffiliation | Northwestern Univ, Chicago, IL |
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| Author_xml | – sequence: 1 givenname: Erik surname: Wu fullname: Wu, Erik organization: Northwestern Univ, Chicago, IL – sequence: 2 givenname: Jeesoo surname: Lee fullname: Lee, Jeesoo – sequence: 3 givenname: Oneil R surname: Mason fullname: Mason, Oneil R – sequence: 4 givenname: Michael surname: Markl fullname: Markl, Michael – sequence: 5 givenname: James D surname: Thomas fullname: Thomas, James D |
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| Snippet | IntroductionProximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow convergence (FC)... Abstract only Introduction: Proximal Isovelocity Surface Area (PISA) measurement is widely accepted to quantify mitral regurgitant volume (RVol), but flow... |
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| Title | Abstract 11516: Quantification of Regurgitation Through Dual Orifices: Pulsatile in Vitro Analysis with Echocardiography and MRI Assessment |
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