Your search keyword '"Rodevand O"' showing total 13 results

1. Left atrial volumes assessed by three- and two-dimensional echocardiography compared to MRI estimates

Author

Rodevand, O., Bjornerheim, R., Ljosland, M., Maehle, J., Smith, H.J., and Ihlen, H.

Published

1999

2. Authorship: From Credit to Accountability

Author

Alfonso, F., primary, Zelveian, P., additional, Monsuez, J.-J., additional, Aschermann, М., additional, Boehm, M., additional, Hernandez, A. B., additional, Wang, T.-D., additional, Cohen, A., additional, Izetbegovic, S., additional, Doubell, A., additional, Echeverri, D., additional, Enc, N., additional, Ferreira-Gonzalez, I., additional, Undas, A., additional, Fortmüller, U., additional, Gatzov, P., additional, Ginghina, C., additional, Goncalves, L., additional, Addad, F., additional, Hassanein, M., additional, Heusch, G., additional, Huber, K., additional, Hatala, R., additional, Ivanusa, M., additional, Lau, Chu-Pak, additional, Marinskis, G., additional, Cas, L.D., additional, Rochitte, C. E., additional, Nikus, K., additional, Fleck, E., additional, Pierard, L., additional, Obradovic, S., additional, Del Pilar Aguilar Passano, M., additional, Jang, Y., additional, Rodevand, O., additional, Sander, M., additional, Shlyakhto, E., additional, Erol, C., additional, Tousoulis, D., additional, Ural, D., additional, Piek, J., additional, Varga, A., additional, Flammer, A., additional, Mach, F., additional, Dibra, A., additional, Guliyev, F., additional, Mrochek, A., additional, Rogava, M., additional, Melgar, I. G., additional, Di Pasquale, G., additional, Kabdrakhmanov, K., additional, Haddour, L., additional, Fras, Z., additional, Held, C., additional, and Shumakov, V., additional

Published

2019

3. Normal reference ranges for left and right atrial volume indexes and ejection fractions obtained with real-time three-dimensional echocardiography

Author

Aune, E., primary, Baekkevar, M., additional, Roislien, J., additional, Rodevand, O., additional, and Otterstad, J. E., additional

Published

2009

4. Left ventricular hypertrophy and myocardial ischaemia in hypertension: The THAMES Study

Author

OTTERSTAD, J. E., primary, DA VIES, M., additional, BALL, S. G., additional, ERIKSSEN, J., additional, BIRKIN, E., additional, VIRK, S., additional, RYNNING, S. E., additional, RODEVAND, O., additional, HANSSON, L., additional, BERGBRANDT, A., additional, FINDLAY, I., additional, KHOKHAR, A. A., additional, ARESKOG, N. H., additional, NYLANDER, E., additional, SMITH, S., additional, and MARLOW, H. F., additional

Published

1993

5. Reversal of Intraventricular Flow Propagation During Isovolumic Relaxation: A Marker of Anterior Wall Dysfunction

Author

Edvardsen, T., Rodevand, O., Aakhus, S., Bjornerheim, R., and Ihlen, H.

Abstract

Background: Myocardial infarction induces left ventricular (LV) wall motion abnormalities during isovolumic relaxation (IVR) and may potentially alter intraventricular flow during this period. This study evaluated whether 2-dimensional color Doppler measurements of intraventricular flow during IVR were able to identify LV dysfunction caused by coronary artery disease. Methods: Patients with single-vessel coronary artery disease and posterior wall infarction (21 patients) or anterior wall infarction (27 patients) were included. Eighteen healthy persons served as a control group. LV function was examined by 2-dimensional echocardiography, 2-dimensional color Doppler, and pulsed Doppler techniques. Results: All normal persons (23.6 +/- 10.9 cm/s) and patients with posterior infarction (19.6 +/- 9.3 cm/s) had flow propagation towards LV apex during IVR. Patients with anterior wall infarction had reversed flow direction (-12.2 +/- 8.7 cm/s, P < .001). The echocardiographic wall motion score index of the 4 apical segments correlated well with flow velocities (r = -0.78, P < .001). Conclusion: Reversed flow propagation during IVR may become a sensitive clinical marker of regional ischemia. (J Am Soc Echocardiogr 1999;12:801-10.)

Published

1999

6. The limited usefulness of real-time 3-dimensional echocardiography in obtaining normal reference ranges for right ventricular volumes

Author

Rodevand Olaf, Baekkevar Morten, Aune Erlend, and Otterstad Jan

Subjects

Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Abstract Background To obtain normal reference ranges and intraobserver variability for right ventricular (RV) volume indexes (VI) and ejection fraction (EF) from apical recordings with real-time 3-dimensional echocardiography (RT3DE), and similarly for RV area indexes (AI) and area fraction (AF) with 2-dimensional echocardiography (2DE). Methods 166 participants; 79 males and 87 females aged between 29–79 years and considered free from clinical and subclinical cardiovascular disease. Normal ranges are defined as 95% reference values and reproducibility as coefficients of variation (CV) for repeated measurements. Results None of the apical recordings with RT3DE and 2DE included the RV outflow tract. Upper reference values were 62 ml/m2 for RV end-diastolic (ED) VI and 24 ml/m2 for RV end-systolic (ES) VI. Lower normal reference value for RVEF was 41%. The respective reference ranges were 17 cm2/m2 for RVEDAI, 11 cm2/m2 for RVESAI and 27% for RVAF. Males had higher upper normal values for RVEDVI, RVESVI and RVEDAI, and a lower limit than females for RVEF and RVAF. Weak but significant negative correlations between age and RV dimensions were found with RT3DE, but not with 2DE. CVs for repeated measurements ranged between 10% and 14% with RT3DE and from 5% to 14% with 2DE. Conclusion Although the normal ranges for RVVIs and RVAIs presented in this study reflect RV inflow tract dimensions only, the data presented may still be regarded as a useful tool in clinical practice, especially for RVEF and RVAF.

Published

2009

7. Fostering diffusion of scientific contents of national society cardiovascular journals: the new ESC search engine.

Author

Alfonso F, Gonçalves L, Pinto F, Timmis A, Ector H, Ambrosio G, Vardas P, Antoinades O, Apetrei E, Aschermann M, Bologneze L, Dilic M, Edes I, Filipiak KJ, Guliyev F, Haouala H, Hassanein MM, Heras M, Hoglund C, Hulin I, Huber K, Ivanusa M, Marinskis G, Masic I, Ostojic M, Pachinger O, Raev D, Rogava M, Rodevand O, Sansoy V, Shlyakhto E, Shumakov VA, Van der Wall E, Videbaek J, and Luscher TF

Subjects

Europe, Humans, Cardiology, Information Dissemination methods, Periodicals as Topic, Search Engine, Societies, Medical

Published

2013

8. Interaction between left ventricular wall motion and intraventricular flow propagation in acute and chronic ischemia.

Author

Edvardsen T, Rodevand O, Endresen K, and Ihlen H

Subjects

Acute Disease, Adult, Aged, Angioplasty, Balloon, Coronary, Blood Flow Velocity, Case-Control Studies, Chronic Disease, Coronary Stenosis physiopathology, Coronary Stenosis therapy, Diastole, Female, Humans, Male, Middle Aged, Myocardial Infarction physiopathology, Myocardial Ischemia diagnostic imaging, Ultrasonography, Doppler, Coronary Circulation, Myocardial Ischemia physiopathology, Ventricular Function, Left

Abstract

Myocardial ischemia has been associated with left ventricular (LV) postsystolic shortening. The combination of tissue Doppler imaging and high frame-rate acquisition of two-dimensional color flow makes it possible to study the interaction between LV wall motion and intraventricular flow propagation. The aim of this study was to examine in a clinical model the impact that acute myocardial ischemia and prior myocardial infarct might have on LV flow patterns and to explain the underlying mechanisms from the tissue Doppler data. LV flow propagation and tissue velocities during early diastole were studied in 18 healthy individuals, 17 patients with prior anterior myocardial infarct, and 16 patients before and during percutaneous coronary intervention (PCI) of the left anterior descending artery. Normal individuals had intraventricular flow propagation toward the apex during isovolumic relaxation. During this early diastolic time phase, myocardial velocities measured at mid- and apical septal segment were directed away from the apex. Before PCI, patients without myocardial infarction had similar findings as in normal individuals. In contrast, each patient with either prior myocardial infarction or PCI-induced acute ischemia had flow propagation opposite to normal individuals, and tissue velocities reversed toward the apex during early diastole. Reversal of early diastolic LV flow propagation in acute and chronic anterior myocardial ischemia reflects postsystolic shortening in the dyskinetic apical and septal myocardial segments.

Published

2005

9. Postsystolic shortening of ischemic myocardium: a mechanism of abnormal intraventricular filling.

Author

Urheim S, Edvardsen T, Steine K, Skulstad H, Lyseggen E, Rodevand O, and Smiseth OA

Subjects

Animals, Atrial Function, Left physiology, Blood Pressure physiology, Dogs, Echocardiography, Doppler, Color, Electrocardiography, Female, Heart Rate physiology, Heart Ventricles physiopathology, Male, Systole physiology, Ventricular Function, Left physiology, Myocardial Contraction physiology, Myocardial Ischemia physiopathology

Abstract

Acute myocardial ischemia has been associated with abnormal filling patterns in the left ventricular (LV) apex. We hypothesized that this may in part be due to postsystolic shortening of ischemic apical segments, which leads to reversal of early diastolic apical flow. Fourteen open-chest anesthetized dogs were instrumented with micromanometers in the LV apex and left atrium and myocardial sonomicrometers in the anterior apical LV wall. Intraventricular filling by color Doppler and wall motion by strain Doppler echocardiography (SDE) were assessed from an apical view. Measurements were taken before and after 5 min of left anterior descending coronary artery (LAD) occlusion. In four dogs, we measured the pressure difference between the LV apex and outflow tract. At baseline, peak early diastolic flow velocities in the distal one-third of the LV were directed toward apex (9.2 +/- 1.6 cm/s). After LAD occlusion, the velocities reversed (-2.3 +/- 0.4 cm/s, P < 0.01), indicating that blood was ejected from the apex toward the base during early filling. This interpretation was confirmed by wall motion analysis, which showed postsystolic shortening of apical myocardial segments. The postsystolic shortening represented 9.7 +/- 1.7% (P < 0.01) and 14.2 +/- 2.4% (P < 0.01) of end-diastolic segment length by SDE and sonomicrometry, respectively. Consistent with the velocity changes, we found reversal of the early diastolic pressure gradient from the LV apex to outflow tract. In the present model, acute LAD occlusion resulted in reversal of early diastolic apical flow, and this was attributed to postsystolic shortening of dyskinetic apical segments. The clinical diagnostic importance of this finding remains to be determined.

Published

2003

10. Diastolic flow pattern in the normal left ventricle.

Author

Rodevand O, Bjornerheim R, Edvardsen T, Smiseth OA, and Ihlen H

Subjects

Adult, Analysis of Variance, Female, Humans, Male, Middle Aged, Reference Values, Reproducibility of Results, Signal Processing, Computer-Assisted, Blood Flow Velocity, Diastole physiology, Echocardiography, Doppler, Color, Heart Ventricles diagnostic imaging, Ventricular Function, Left physiology

Abstract

Objectives: This study sought to clarify the diastolic flow pattern in the normal left ventricle., Background: During left ventricular filling, basally directed (retrograde) velocities are seen in the outflow compartment. These velocities may represent blood returned from the apical region or a shortcut at a more basal level., Methods: Left ventricular flow patterns were identified in 18 healthy individuals (age 47 +/- 12 years) with the use of high frame-rate two-dimensional color Doppler and color M-mode Doppler echocardiography techniques. Intraventricular velocities were measured with single pulsed Doppler at 3 levels in both inflow and outflow compartments (posterolateral and anteroseptal parts of the left ventricle)., Results: During early transmitral flow acceleration, all intraventricular velocities were directed towards the apex. However, after peak early and late inflow velocities and during diastasis, retrograde velocities were identified in the outflow compartment. These retrograde velocities occurred earlier, and were higher, at the level of the deflected anterior mitral leaflet tip compared with more apical levels (P <.001). A velocity pattern was established, consistent with early intraventricular vortex formation behind both mitral leaflets. The vortex adjacent to the anterior leaflet subsequently enlarged to include a major part of the left ventricle., Conclusion: Uniform diastolic flow patterns were identified in the normal left ventricles. The findings suggest that both early and late diastolic filling start with an initial motion of a fluid column, succeeded by vortex formation, which explains retrograde flow in the outflow compartment.

Published

1999

11. Left ventricular volumes assessed by different new three-dimensional echocardiographic methods and ordinary biplane technique.

Author

Rodevand O, Bjornerheim R, Aakhus S, and Kjekshus J

Subjects

Animals, In Vitro Techniques, Models, Cardiovascular, Observer Variation, Phantoms, Imaging, Reproducibility of Results, Sensitivity and Specificity, Swine, Echocardiography, Three-Dimensional methods, Ventricular Dysfunction, Left diagnostic imaging

Abstract

Unlabelled: Three-dimensional (3D) echocardiography may overcome the problems with inadequate accuracy and reproducibility of 2D volume measurements of the left ventricle., Aims: To establish the in vitro accuracy and reproducibility of two new methods for 3D echocardiographic volume determination as compared to biplane measurements., Methods: Validation of volume measurements by a multiplane 3D method was performed on asymmetric latex phantoms (n = 8, true volumes 45-304 ml) using rotational acquisition of 90 image planes. Porcine agarose-filled asymmetrical left ventricles (n = 7, true volumes 34-280 ml) were measured by the same multiplane 3D method based on images acquired by probe rotation axis perpendicular (A) and parallel (B) to the ventricular long axis. Ventricular volumes were also obtained by a simplified 3D system using only the three standard apical views (C) and by the ordinary biplane Simpson's method (D)., Results: On latex phantoms systematic deviation from true volumes by multiplane 3D was less than 2%, and 95% variability of individual measurements from this mean was +/- 4.9%. For accuracy on left ventricles, systematic bias was small with all the methods (< 5%), but 95% variability of individual measurements was +/- 9.0%, 15.4%, 18.8% and 41.3% of true volumes for methods A-D respectively. Corresponding results in the same range were obtained for inter- and intraobserver variability., Conclusion: Individual in vitro volume estimates of left ventricles are of similar quality using apical multiplane or apical triplane 3D echocardiography. Both methods were superior to the ordinary apical biplane method, but inferior to multiplane 3D method with the probe directed perpendicular to the ventricular long axis.

Published

1998

12. Left ventricular mass assessed by three-dimensional echocardiography using rotational acquisition.

Author

Rodevand O, Bjornerheim R, Kolbjornsen O, Ihlen H, and Kjekshus J

Subjects

Animals, Echocardiography, Evaluation Studies as Topic, Swine, Echocardiography, Three-Dimensional methods, Heart Ventricles diagnostic imaging, Image Enhancement

Abstract

Background: The reproducibility of left ventricular (LV) mass measurement by two-dimensional (2-D) echocardiography is inadequate for individual assessments., Hypothesis: This study was undertaken to evaluate the potential of LV mass determination with a new three-dimensional (3-D) echocardiographic method compared with 2-D measurements., Methods: Porcine agarose-filled left ventricles (n = 15, true mass 61-511 g) of different shapes were measured by a multiplane 3-D method based on 90 images acquired by probe rotation axis (1) perpendicular and (2) parallel to the ventricular long axis ["parasternal" (the left sternal border was not present as a reference point in this study) and apical views]. Mass was also obtained using (3) the biplane truncated ellipsoid and (4) area-length methods, as well as (5) the modified cube formula. Five hearts were not analyzed with the apical 3-D technique because of insufficient image quality., Results: Systematic deviation from true mass was small with all methods (< 5.3%). Accuracy, expressed as 1 standard deviation of individual estimates around this systematic bias, was 7.7, 13.6, 8.2, 11.9, and 11.9% of true mass for the methods 1-5, respectively. Interobserver reproducibility, expressed as the coefficient of variation, was 4.7, 8.8, 8.1, 8.9, and 9.4% for the same methods., Conclusion: Limits for individual accuracy and reproducibility of LV mass estimates are nearly doubled using apical compared with "parasternal" 3-D echocardiography in vitro. A main advantage of "parasternal" 3-D compared with 2-D LV mass estimates is better reproducibility, but at the expense of greater time consumption. Apical 3-D technique is not superior to simpler 2-D methods based on "parasternal" short axis imaging.

Published

1997

13. The European cardiologist.

Author

Rodevand O

Subjects

Curriculum, Europe, Guidelines as Topic, United States, Cardiology education, Cardiology standards

Published

1996