Your search keyword '"Joan Solheim"' showing total 4 results

1. Effect of three-dimensional valve shape on the hemodynamics of aortic stenosis

Author

Mary Etta King, Dan Gilon, Edward G. Cape, Robert A. Levine, Joan Solheim, Michael D. VanAuker, Jae Kwan Song, and Mark D. Handschumacher

Subjects

Pressure drop, Aortic valve, medicine.medical_specialty, Planimeter, business.industry, Hemodynamics, Anatomy, 030204 cardiovascular system & hematology, medicine.disease, 03 medical and health sciences, Stenosis, 0302 clinical medicine, medicine.anatomical_structure, Bicuspid valve, Internal medicine, medicine, Cardiology, 030212 general & internal medicine, business, Cardiology and Cardiovascular Medicine, Body orifice, Pressure gradient

Abstract

Objectives This study tested the hypothesis that the impact of a stenotic aortic valve depends not only on the cross-sectional area of its limiting orifice but also on three-dimensional (3D) valve geometry. Background Valve shape can potentially affect the hemodynamic impact of aortic stenosis by altering the ratio of effective to anatomic orifice area (the coefficient of orifice contraction [Cc]). For a given flow rate and anatomic area, a lower Cc increases velocity and pressure gradient. This effect has been recognized in mitral stenosis but assumed to be absent in aortic stenosis (constant Cc of 1 in the Gorlin equation). Methods In order to study this effect with actual valve shapes in patients, 3D echocardiography was used to reconstruct a typical spectrum of stenotic aortic valve geometrics from doming to flat. Three different shapes were reproduced as actual models by stereolithography (computerized laser polymerization) with orifice areas of 0.5, 0.75, and 1.0 cm2 (total of nine valves) and studied with physiologic flows. To determine whether valve shape actually influences hemodynamics in the clinical setting, we also related Cc (= continuity/planimeter areas) to stenotic aortic valve shape in 35 patients with high-quality echocardiograms. Results In the patient-derived 3D models, Cc varied prominently with valve shape, and was largest for long, tapered domes that allow more gradual flow convergence compared with more steeply converging flat valves (0.85 to 0.90 vs. 0.71 to 0.76). These variations translated into differences of up to 40% in pressure drop for the same anatomic area and flow rate, with corresponding variations in Gorlin (effective) area relative to anatomic values. In patients, Cc was significantly lower for flat versus doming bicuspid valves (0.73 ± 0.14 vs. 0.94 ± 0.14, p Conclusions Three-dimensional valve shape is an important determinant of pressure loss in patients with aortic stenosis, with smaller effective areas and higher pressure gradients for flatter valves. This effect can translate into clinically important differences between planimeter and effective valve areas (continuity or Gorlin). Therefore, valve shape provides additional information beyond the planimeter orifice area in determining the impact of valvular aortic stenosis on patient hemodynamics.

Published

2002

2. Insights From Three-dimensional Echocardiographic Laser Stereolithography

Author

Mark D. Handschumacher, Edward G. Cape, Dan Gilon, Robert A. Levine, Joan Solheim, Arthur E. Weyman, Stockton M. Miller-Jones, Eleanor Morris, John T. Strobel, Leng Jiang, and Charles Sears

Subjects

Pressure drop, business.industry, Lasers, Models, Cardiovascular, Blood Pressure, Geometry, Conical surface, medicine.disease, Myocardial Contraction, Stenosis, Mitral valve stenosis, medicine.anatomical_structure, Echocardiography, Physiology (medical), Mitral valve, Image Processing, Computer-Assisted, Humans, Mitral Valve Stenosis, Medicine, Tube (container), Cardiology and Cardiovascular Medicine, business, Body orifice, Pressure gradient

Abstract

Background Three-dimensional echocardiography can allow us to address uniquely three-dimensional scientific questions, for example, the hypothesis that the impact of a stenotic valve depends not only on its limiting orifice area but also on its three-dimensional geometry proximal to the orifice. This can affect the coefficient of orifice contraction (Cc=effective/anatomic area), which is important because for a given flow rate and anatomic area, a lower Cc gives a higher velocity and pressure gradient, and Cc, routinely assumed constant in the Gorlin equation, may vary with valve shape (60% for a flat plate, 100% for a tube). To date, it has not been possible to study this with actual valve shapes in patients. Methods and Results Three-dimensional echocardiography reconstructed valve geometries typical of the spectrum in patients with mitral stenosis: mobile doming, intermediate conical, and relatively flat immobile valves. Each geometry was constructed with orifice areas of 0.5, 1.0, and 1.5 cm 2 by stereolithography (computerized laser polymerization) (total, nine valves) and studied at physiological flow rates. Cc varied prominently with shape and was larger for the longer, tapered dome (more gradual flow convergence proximal and distal to the limiting orifice): for an anatomic orifice of 1.5 cm 2 , Cc increased from 0.73 (flat) to 0.87 (dome), and for an area of 0.5 cm 2 , from 0.62 to 0.75. For each shape, Cc increased with increasing orifice size relative to the proximal funnel (more tubelike). These variations translated into important differences of up to 40% in pressure gradient for the same anatomic area and flow rate (greatest for the flattest valves), with a corresponding variation in calculated Gorlin area (an effective area) relative to anatomic values. Conclusions The coefficient of contraction and the related net pressure loss are importantly affected by the variations in leaflet geometry seen in patients with mitral stenosis. Three-dimensional echocardiography and stereolithography, with the use of actual information from patients, can address such uniquely three-dimensional questions to provide insight into the relations between cardiac structure, pressure, and flows.

Published

1996

3. Clinical application of three-dimensional echocardiographic laser stereolithography: Effect of leaflet funnel geometry on the coefficient of orifice contraction, pressure loss and the Gorlin formula in aortic stenosis

Author

Charles Sears, Arthur E. Weyman, Edward G. Cape, Joan Solheim, Mark D. Handschumacher, Michael D. VanAuker, Robert A. Levine, Mary Etta King, and Dan Gilon

Subjects

Pressure drop, Contraction (grammar), business.product_category, Leaflet (botany), business.industry, medicine.disease, Laser, law.invention, Stenosis, law, medicine, Funnel, Cardiology and Cardiovascular Medicine, business, Body orifice, Stereolithography, Biomedical engineering

Published

1996

4. Clinical application of three-dimensional echocardiographic laser stereolithography: Effect of leaflet funnel geometry on the coefficient of orifice contraction, pressure loss and the gerlin formula in mitral stenosis

Author

Charles Sears, Mark D. Handschumacher, Arthur E. Weyman, Edward G. Cape, Dan Gilon, Robert A. Levine, Joan Solheim, Eleanor Morris, John T. Strobel, and Leng Jiang

Subjects

Pressure drop, Contraction (grammar), business.product_category, business.industry, Anatomy, medicine.disease, Laser, law.invention, Stenosis, law, medicine, Radiology, Nuclear Medicine and imaging, Funnel, Cardiology and Cardiovascular Medicine, business, Stereolithography, Body orifice

Published

1995