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dedicated cmr postprocessing software suiteheart  (NeoSoft LLC)

 
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    Structured Review

    NeoSoft LLC dedicated cmr postprocessing software suiteheart
    Case 1 <t>CMR</t> ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, <t>cardiac</t> <t>magnetic</t> <t>resonance</t> imaging; MV, mitral valve.
    Dedicated Cmr Postprocessing Software Suiteheart, supplied by NeoSoft LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/dedicated cmr postprocessing software suiteheart/product/NeoSoft LLC
    Average 90 stars, based on 1 article reviews
    dedicated cmr postprocessing software suiteheart - by Bioz Stars, 2026-06
    90/100 stars

    Images

    1) Product Images from "Mitral Annulus Disjunction and Arrhythmic Mitral Valve Prolapse: Emerging Role of Cardiac Magnetic Resonance Imaging in the Workup"

    Article Title: Mitral Annulus Disjunction and Arrhythmic Mitral Valve Prolapse: Emerging Role of Cardiac Magnetic Resonance Imaging in the Workup

    Journal: The Indian Journal of Radiology & Imaging

    doi: 10.1055/s-0042-1754357

    Case 1 CMR ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, cardiac magnetic resonance imaging; MV, mitral valve.
    Figure Legend Snippet: Case 1 CMR ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, cardiac magnetic resonance imaging; MV, mitral valve.

    Techniques Used: Magnetic Resonance Imaging

    Case 2 CMR. ( A ) Two-chamber view demonstrating bileaflet mitral valve prolapse with prolapse distance measurements ( orange arrows ). ( B ) Note regurgitant jet from mitral regurgitation ( green arrow ) ( C ) Note the separation of LV myocardium from mitral annulus ( green line : MAD distance). ( D ) Curling of LV myocardium seen in two-chamber view with quantitative measurement of curling distance ( yellow arrow ). ( E ) LV basal hypertrophy Base: Mid LV thickness ratio of 2:1. ( F ) Focal LGE involving the posterobasal wall of LV myocardium. ( G ) Color coded feature tracking map in long axis views with global longitudinal strain curve depicting reduction in GLS. CMR, cardiac magnetic resonance imaging; GLS, global longitudinal strain; LV, left ventricle; MAD, mitral annulus disjunction.
    Figure Legend Snippet: Case 2 CMR. ( A ) Two-chamber view demonstrating bileaflet mitral valve prolapse with prolapse distance measurements ( orange arrows ). ( B ) Note regurgitant jet from mitral regurgitation ( green arrow ) ( C ) Note the separation of LV myocardium from mitral annulus ( green line : MAD distance). ( D ) Curling of LV myocardium seen in two-chamber view with quantitative measurement of curling distance ( yellow arrow ). ( E ) LV basal hypertrophy Base: Mid LV thickness ratio of 2:1. ( F ) Focal LGE involving the posterobasal wall of LV myocardium. ( G ) Color coded feature tracking map in long axis views with global longitudinal strain curve depicting reduction in GLS. CMR, cardiac magnetic resonance imaging; GLS, global longitudinal strain; LV, left ventricle; MAD, mitral annulus disjunction.

    Techniques Used: Magnetic Resonance Imaging

    CMR planning for assessment of mitral valve. ( A ) CMR short axis view at the level of mitral valve showing anatomy of mitral valve. A1, A2, and A3 scallops in the anterior leaflet. P1, P2, and P3 scallops in the posterior leaflet. ( B ) Modified left ventricular outflow tract view. Contiguous stack of cine images perpendicular to the mitral commissures transecting the principal line of coaptation to visualize and assess all the mitral scallops A1–P1, A2–P2, and A3–P3. ( C ) Additional/alternative slices perpendicular to the coaptation plane of the valve leaflets ( yellow and/or purple lines ) ( D ) For circumferential assessment of annular plane, six left ventricular long-axis cine slices are acquired at every 30degrees. The first projection was aligned through the superior right ventricular free wall insertion into the septum, and was defined as 0° in the annular plane, followed by clockwise labeling of the long-axis slices. CMR, cardiac magnetic resonance imaging.
    Figure Legend Snippet: CMR planning for assessment of mitral valve. ( A ) CMR short axis view at the level of mitral valve showing anatomy of mitral valve. A1, A2, and A3 scallops in the anterior leaflet. P1, P2, and P3 scallops in the posterior leaflet. ( B ) Modified left ventricular outflow tract view. Contiguous stack of cine images perpendicular to the mitral commissures transecting the principal line of coaptation to visualize and assess all the mitral scallops A1–P1, A2–P2, and A3–P3. ( C ) Additional/alternative slices perpendicular to the coaptation plane of the valve leaflets ( yellow and/or purple lines ) ( D ) For circumferential assessment of annular plane, six left ventricular long-axis cine slices are acquired at every 30degrees. The first projection was aligned through the superior right ventricular free wall insertion into the septum, and was defined as 0° in the annular plane, followed by clockwise labeling of the long-axis slices. CMR, cardiac magnetic resonance imaging.

    Techniques Used: Modification, Labeling, Magnetic Resonance Imaging



    Similar Products

    dedicated cmr postprocessing software suiteheart  (NeoSoft LLC)
    90
    NeoSoft LLC dedicated cmr postprocessing software suiteheart
    Case 1 <t>CMR</t> ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, <t>cardiac</t> <t>magnetic</t> <t>resonance</t> imaging; MV, mitral valve.
    Dedicated Cmr Postprocessing Software Suiteheart, supplied by NeoSoft LLC, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
    https://www.bioz.com/result/dedicated cmr postprocessing software suiteheart/product/NeoSoft LLC
    Average 90 stars, based on 1 article reviews
    dedicated cmr postprocessing software suiteheart - by Bioz Stars, 2026-06
    90/100 stars
    		  Buy from Supplier

    Image Search Results


    Case 1 CMR ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, cardiac magnetic resonance imaging; MV, mitral valve.

    Journal: The Indian Journal of Radiology & Imaging

    Article Title: Mitral Annulus Disjunction and Arrhythmic Mitral Valve Prolapse: Emerging Role of Cardiac Magnetic Resonance Imaging in the Workup

    doi: 10.1055/s-0042-1754357

    Figure Lengend Snippet: Case 1 CMR ( A ) 3D Long axis view showing bileaflet prolapse. The prolapsed distance is measured as superior displacement of leaflet beyond mitral annulus ( orange arrows ) ( B ) Long-axis view, Longitudinal mitral annulus disjunction (MAD; green line ) length is measured from the junction of left atrial (LA) wall–posterior MV leaflet to the top of the left ventricular (LV) inferobasal wall during end systole ( C ). Same image as in ( B ) showing measurement of curling distance by tracing a line between the LA wall–posterior MV leaflet junction and top of LV inferobasal wall, and from this line, a perpendicular line to the lower limit of the mitral annulus during end-systole. ( D ) LV basal hypertrophy. The LV thickness of basal and mid segments of the inferolateral wall is measured at diastole on long axis view. Base-to-mid ratio: 2.7. 3D, three-dimensional; CMR, cardiac magnetic resonance imaging; MV, mitral valve.

    Article Snippet: Data analysis and postprocessing was performed on dedicated CMR postprocessing software (suiteHEART; NeoSoft LLC, Wisconsin, United States).

    Techniques: Magnetic Resonance Imaging

    Case 2 CMR. ( A ) Two-chamber view demonstrating bileaflet mitral valve prolapse with prolapse distance measurements ( orange arrows ). ( B ) Note regurgitant jet from mitral regurgitation ( green arrow ) ( C ) Note the separation of LV myocardium from mitral annulus ( green line : MAD distance). ( D ) Curling of LV myocardium seen in two-chamber view with quantitative measurement of curling distance ( yellow arrow ). ( E ) LV basal hypertrophy Base: Mid LV thickness ratio of 2:1. ( F ) Focal LGE involving the posterobasal wall of LV myocardium. ( G ) Color coded feature tracking map in long axis views with global longitudinal strain curve depicting reduction in GLS. CMR, cardiac magnetic resonance imaging; GLS, global longitudinal strain; LV, left ventricle; MAD, mitral annulus disjunction.

    Journal: The Indian Journal of Radiology & Imaging

    Article Title: Mitral Annulus Disjunction and Arrhythmic Mitral Valve Prolapse: Emerging Role of Cardiac Magnetic Resonance Imaging in the Workup

    doi: 10.1055/s-0042-1754357

    Figure Lengend Snippet: Case 2 CMR. ( A ) Two-chamber view demonstrating bileaflet mitral valve prolapse with prolapse distance measurements ( orange arrows ). ( B ) Note regurgitant jet from mitral regurgitation ( green arrow ) ( C ) Note the separation of LV myocardium from mitral annulus ( green line : MAD distance). ( D ) Curling of LV myocardium seen in two-chamber view with quantitative measurement of curling distance ( yellow arrow ). ( E ) LV basal hypertrophy Base: Mid LV thickness ratio of 2:1. ( F ) Focal LGE involving the posterobasal wall of LV myocardium. ( G ) Color coded feature tracking map in long axis views with global longitudinal strain curve depicting reduction in GLS. CMR, cardiac magnetic resonance imaging; GLS, global longitudinal strain; LV, left ventricle; MAD, mitral annulus disjunction.

    Article Snippet: Data analysis and postprocessing was performed on dedicated CMR postprocessing software (suiteHEART; NeoSoft LLC, Wisconsin, United States).

    Techniques: Magnetic Resonance Imaging

    CMR planning for assessment of mitral valve. ( A ) CMR short axis view at the level of mitral valve showing anatomy of mitral valve. A1, A2, and A3 scallops in the anterior leaflet. P1, P2, and P3 scallops in the posterior leaflet. ( B ) Modified left ventricular outflow tract view. Contiguous stack of cine images perpendicular to the mitral commissures transecting the principal line of coaptation to visualize and assess all the mitral scallops A1–P1, A2–P2, and A3–P3. ( C ) Additional/alternative slices perpendicular to the coaptation plane of the valve leaflets ( yellow and/or purple lines ) ( D ) For circumferential assessment of annular plane, six left ventricular long-axis cine slices are acquired at every 30degrees. The first projection was aligned through the superior right ventricular free wall insertion into the septum, and was defined as 0° in the annular plane, followed by clockwise labeling of the long-axis slices. CMR, cardiac magnetic resonance imaging.

    Journal: The Indian Journal of Radiology & Imaging

    Article Title: Mitral Annulus Disjunction and Arrhythmic Mitral Valve Prolapse: Emerging Role of Cardiac Magnetic Resonance Imaging in the Workup

    doi: 10.1055/s-0042-1754357

    Figure Lengend Snippet: CMR planning for assessment of mitral valve. ( A ) CMR short axis view at the level of mitral valve showing anatomy of mitral valve. A1, A2, and A3 scallops in the anterior leaflet. P1, P2, and P3 scallops in the posterior leaflet. ( B ) Modified left ventricular outflow tract view. Contiguous stack of cine images perpendicular to the mitral commissures transecting the principal line of coaptation to visualize and assess all the mitral scallops A1–P1, A2–P2, and A3–P3. ( C ) Additional/alternative slices perpendicular to the coaptation plane of the valve leaflets ( yellow and/or purple lines ) ( D ) For circumferential assessment of annular plane, six left ventricular long-axis cine slices are acquired at every 30degrees. The first projection was aligned through the superior right ventricular free wall insertion into the septum, and was defined as 0° in the annular plane, followed by clockwise labeling of the long-axis slices. CMR, cardiac magnetic resonance imaging.

    Article Snippet: Data analysis and postprocessing was performed on dedicated CMR postprocessing software (suiteHEART; NeoSoft LLC, Wisconsin, United States).

    Techniques: Modification, Labeling, Magnetic Resonance Imaging