Quantitative validation of cineangiographic axial oblique biplane left ventricular volume measurement

Axial oblique left ventriculography allows unique visualization of acquired and congenital cardiac lesions. However, validation of the accuracy of left ventricular (LV) volume with axial oblique projections is limited and clouded by orthogonal violations between biplane projections. Biplane cineradiographic volume measurement of 17 LV casts employing the axial projection 35 degrees right anterior oblique/55 degrees left anterior oblique/30 degrees cranial (35 degrees RAO/55 degrees LAO/30 degrees Cr) was performed and compared to the conventional postero-anterior/lateral (PA/Lat) and 30 degrees right anterior oblique/60 degrees left anterior oblique (30 degrees RAO/60 degrees LAO) views. LV volume was calculated from biplane cineradiograms by area length and Simpson's rule method. True LV volume by water displacement was 33 +/- 28 (mean +/- S.D.), range 15 to 112 ml. LV cast volume calculated by the area length method from cineradiograms was overestimated (p less than 0.002) but no different by Simpson's rule method (pNS). The ideal correlation was best approximated by the 35 degrees RAO/55 degrees LAO/30 degrees Cr biplane view calculated by Simpson's rule, r = 0.99, y = 3.5 + 0.9x, and standard error of estimate (SEE) = 4.3 ml. Biplane LV angiography with the axial projection permitted accurate LV volume measurement, and Simpson's rule provided the best representation of true volume.     

Determination of left ventricular systolic wall thickness by digital subtraction angiography

The accuracy of digital subtraction angiography (DSA) for determination of left ventricular (LV) systolic wall thickness and muscle mass was evaluated in 20 patients (mean age 50 +/- 11 years). Conventional LV angiograms were digitized and subtracted using a combined subtraction mode ('mask mode' and 'time interval difference' subtraction). Wall thickness and muscle mass were determined at end-diastole, after the first- and second-third of systole and at end-systole. M-mode echocardiography (Echo), which was obtained from beam selection of the two-dimensional echocardiogram and conventional angiography (LVA), served as reference techniques. Angiographic LV wall thickness and muscle mass were determined according to the technique of Rackley in both, right (RAO) and left (LAO) anterior oblique projections, whereas echocardiographic wall thickness was measured just below the mitral valve orthogonal to the posterior wall (= LAO equivalent). Percent wall thickening was calculated in all patients. LV end-diastolic wall thickness and muscle mass correlated well between DSA and LVA (LV end-diastolic wall thickness in LAO projection r = 0.72, biplane LV end-diastolic muscle mass r = 0.83), LV end-systolic wall thickness (1.44 vs 1.33 cm, P less than 0.05) and percent wall thickening (52 vs 42%, P less than 0.05) compared favourably between echocardiography and DSA but was significantly larger when echocardiographically measured than with DSA (LAO projection). DSA and echocardiography showed a good correlation in regard to LV end-diastolic and end-systolic wall thickness (correlation coefficient r = 0.89, standard error of estimate SEE = 0.15 cm or 13% of the mean value).(ABSTRACT TRUNCATED AT 250 WORDS)     

Measurement of regional wall motion from biplane contrast ventriculograms: a comparison of the 30 degree right anterior oblique and 60 degree left anterior oblique projections in patients with acute myocardial infarction

The value of performing biplane vs single plane analysis of regional wall motion from contrast ventriculograms was determined in 102 patients who received thrombolytic therapy and who underwent biplane ventriculography during acute myocardial infarction (n = 67), at follow-up more than 2 weeks later (n = 80), or both (n = 45). Hypokinesis in the infarct region and hyperkinesis in the noninfarct region were measured by the centerline method in the respective artery territories, which were defined from the data of 62 patients with single-vessel disease and were expressed in units of standard deviations from the mean of 32 normal subjects. Hypokinesis was more severe and extended over a longer segment of the left ventricular contour when measured in the right anterior oblique (RAO) projection in thrombosis of the left anterior descending coronary artery (LAD) but more severe and extensive in the left anterior oblique (LAO) projection in circumflex stenosis. Hyperkinesis opposite the LAD or the circumflex was greater in the LAO projection. In patients with thrombosis of the right coronary artery, wall motion abnormalities were similar in the two projections. Thus the evaluation of hypokinesis caused by acute coronary thrombosis and of the effect of therapeutic interventions in salvaging function can be adequately evaluated from single-plane 30 degree RAO ventriculograms, except in the small minority of patients with circumflex thrombosis.     

Non-invasive determination of left ventricular ejection fraction using a mobile ECG-triggered scintillation measuring probe. Comparison of cineventriculography, echocardiography and radionuclide ventriculography

In 29 unselected patients, the left ventricular ejection fraction was evaluated using a mobile ECG-gated scintillation probe (Nuclear Stethoscope) after in vivo labeling of the erythrocytes with 15 mCi technetium-99m. To validate the method, the Nuclear Stethoscope measurements were correlated to the results of: 1. Single-plane contrast cineventriculography in the right and left anterior oblique projections (RAO, LAO), 2. Radionuclide ventriculography with a gamma camera computer system, 3. Two-dimensional echocardiography from the apical two- and four-chamber views. The ejection fraction measured by the Nuclear Stethoscope showed a close correlation to the values obtained by cineventriculography in the RAO projection (r = 0.748) and radionuclide ventriculography (r = 0.785). In this group of unselected patients, the correlations with the results of two-dimensional echocardiography were poor (r = 0.451 and 0.557). Cineventriculographic findings and radionuclide ventriculography correlated well (RAO: r = 0.786; LAO: r = 0.758). The Nuclear Stethoscope provides a simple, reliable, and noninvasive method for measuring ventricular ejection fraction. Ongoing studies indicate that the Nuclear Stethoscope is a valid method even at a lower dose of 5 mCi technetium-99m.     

Quantitative axial oblique contrast left ventriculography: Validation of the method by demonstrating improved visualization of regional wall motion and mitral valve function with accurate volume determinations

To compare the relative merits of conventional and axial $\text{RAO}\text{LAO}$ angiography, we performed biplane left ventricular (LV) cineangiograms in 36 patients in both the conventional 30-degree $\text{RAO}\text{60}\text{-}\text{degree}$ LAO projection and in the axial 45-degree $\text{RAO}\text{60}\text{-degree}\text{LAO}\text{25}\text{-degree}$ cranial projection, in random sequence. LV volumes were calculated by a computerized system utilizing modification of the area-length method. End-diastolic volume, end-systolic volume, and ejection fraction correlated closely between the two projections (r = 0.93, 0.95, and 0.86, respectively). The axial 60-degree LAO view projected the LV apex inferiorly, the LV outflow tract superiorly, reduced LV foreshortening, and “uncovered” the LV outflow tract in all cases. Segmental wall motion abnormalities of the ventricular septum, apex, and posterior wall were better evaluated by the axial 60-degree LAO view in patients with regional asynergy in these zones. The 45-degree RAO, compared to the 30-degree RAO view, allowed a true tangential view of the mitral valve and provided a large “clear area” between the mitral valve and descending aorta, which improved the ability to quantify mitral regurgitation. Thus, axial oblique LV angiography improves evaluation of LV regional wall motion and mitral valve function without compromising LV volume quantitation.     

Quantitative angiographic analysis of right ventricular global function in normal incidences and in patients with coronary artery disease

At present right ventriculography data cannot be accurately estimated owing to the absence of software for quantitative analysis of the right ventricle (RV) volumes and function. The aim of this study was to use existing software for left ventriculography analysis to estimate right ventricular volumes and function in patients without coronary lesions and in those with coronary artery disease (CAD). Thirty-two patients without significant lesions of coronary arteries and 20 patients with CAD were examined with left ventriculography and right atriography. Each examination was performed in 2 projections: 30 degrees right anterior oblique (RAO 30 degrees) and 60 degrees left anterior oblique (LAO 60 degrees) projections. Correction factor (CF) was obtained by finding the ratio between stroke volumes of the left and right ventricles. The mean CF was 0.9243+/-0.2887 for patients without CAD and 0.8758+/-0.2232 for patients with CAD. Such calculation is the easiest and quite accurate method of determining RV volumes and function by using existing software of quantitative angiographic analysis.     

Interobserver variability in interpreting contrast left ventriculograms (CASS)

Randomly selected left ventricular cineangiograms performed by 14 medical centers (clinical sites) participating in a large multicenter study of medical and surgical treatment of coronary artery disease (CASS) were systematically recalled and reread by one of four designated quality control centers. The end diastolic volume (EDV), end systolic volume (ESV), and ejection fraction (EF) calculated by the quality control center were compared with those calculated by the clinical site, and correlation coefficients of 0.71, 0.84, and 0.79, respectively, were obtained. Regional left ventricular (LV) wall motion abnormalities were assessed by dividing the LV wall as viewed in the right anterior oblique (RAO) and left anterior oblique (LAO) views into five segments each and grading the motion of each segment according to six categories of increasing abnormalities from normal to aneurysm. When discrepancies based on “nearest neighbor” differences in naming adjacent segments were eliminated and only marked differences of more than one degree of severity of wall motion abnormality were considered, interobserver differences were 7% and 10% for RAO and LAO segments, respectively. Agreement was less frequent in designating a segment “aneurysmal”. When each LV segment was assigned a numerical score based on increasing severity of wall motion abnormality and a total LV score for each ventriculogram computed, the quality control and clinical site readings were in good agreement with a correlation coefficient of 0.83.     

Reversal of increased diastolic stiffness in mitral stenosis after successful balloon valvuloplasty

BACKGROUND AND AIM OF THE STUDY: Abnormal passive elastic properties have been reported in patients with severe mitral stenosis and have been attributed to either: (i) chamber atrophy due to unloading; (ii) myocardial fibrosis; (iii) right and left ventricular (LV) interaction; or (iv) internal restrictions due to the rigid mitral valve apparatus. The study aim was to evaluate the effect of percutaneous mitral balloon valvuloplasty (PMV) on passive elastic properties in 19 patients with severe mitral stenosis. Ten patients with normal coronary arteries and LV function served as controls. METHODS: LV high-fidelity pressure measurements and simultaneous biplane LV angiograms were obtained before and after PMV (n = 11). The constant of chamber stiffness (b; ml(-1)) was calculated from the diastolic pressure-volume relationship and the constant of myocardial stiffness (beta) from the diastolic stress-strain relationship. The time constant of relaxation (T; ms) was calculated from the LV pressure decay during isovolumic relaxation. Regional ejection fraction (radial axis system) was determined in six regions of the right anterior oblique (RAO) and left anterior oblique (LAO) angiographic projections. RESULTS: Mitral valve area was increased from 1.0 to 2.2 cm2 after PMV, whereas diastolic pressure gradient was reduced from 14 to 4 mmHg. Global LV ejection fraction (EF) was slightly reduced (57% versus 63%; p<0.05) before valvuloplasty and normalized thereafter. Regional EF increased significantly (p<0.05) in the posterolateral region of the LAO projection after intervention. Myocardial stiffness was increased before, and decreased significantly after balloon valvuloplasty (from 16 to 11; p<0.05). The rate of relaxation and chamber stiffness remained unchanged. CONCLUSIONS: Myocardial stiffness is increased in patients with mitral stenosis, but normalized after successful PMV. The improvement in passive elastic properties after valvuloplasty can be explained by the mobilization of the subvalvular apparatus with an improvement in regional LV function.     

Comparison of single and biplane ventriculography for determination of left ventricular volume and ejection fraction.

This study was done to compare single and biplane left ventriculography in quantitating left ventricular (LV) volumes and ejection fraction. LV volumes and ejection fraction were measured from a 30 degrees right anterior oblique single plane ventriculogram and a 30 degrees right anterior oblique 60 degrees left anterior oblique biplane ventriculogram in 152 men (aged 59 +/- 9 [mean +/- standard deviation] years), of whom 102 had hypokinesia, akinesia, or dyskinesia. There was excellent agreement between the results of single and biplane ventriculography with respect to LV end-diastolic volume (r = 0.96), end-systolic volume (r = 0.98) and ejection fraction (r = 0.97). The end-diastolic and end-systolic volumes measured by biplane ventriculography were consistently slightly larger than those measured by single plane, whereas ejection fractions measured by the 2 techniques were remarkably similar, even for the 46 patients with biplane ejection fractions less than 0.50 and the 102 with hypokinesia, akinesia or dyskinesia. Thus, LV volumes and ejection fractions determined by single plane ventriculography correlate very well with those determined by biplane ventriculography, even in patients with hypokinesia, akinesia, or dyskinesia and depressed LV systolic performance. Biplane ventriculography appears to provide little information that cannot be obtained reliably from single plane.     

Comparison of biplane and single plane left ventricular volumes in atrial septal defect

The close agreement between biplane (BP) and single-plane (SP) angiographic estimates of left ventricular (LV) volumes results from the similarity of the minor axes measured in the right anterior oblique (RAO) and left anterior oblique (LAO) views. Disease states that alter LV geometry may change the length of one minor axis more than the other, producing a discrepancy between BP and SP volumes. To examine this hyposthesis, angiographically derived volumes in 21 patients with atrial septal defects (ASD) in which the LV appears to be compressed and flattened by an enlarged right ventricle, were compared to 100 normal control patients. In the control patients, the median SP estimate of end-diastolic volume (EDV) was 7.6% larger than the BP determination, whereas in patients with ASD, the median SP EDV estimate was 16.7% larger than the BP EDV (P<0.0001). The SP end-systolic volume (ESV) underestimated the BP value by 3.4% in controls but overestimated the BP ESV in patients with ASD by 4.3% (P<0.02). The overestimate of the SP EDV and SP ESV when compared to the BP volumes may be due to changes in either the minor axes or the appearance of the longest major axis in the LAO view. The longest major axis was found in the RAO view in 99% (99/100) of normals and 95% (20/21) of ASD patients (P?NS). The median ratio of RAO to LAO end-diastolic minor axes, however, was 1.07 in the normals and 1.17 for ASD patients. The median ratio of end-systolic minor axes was 0.97 for controls and 1.04 for ASD patients. Compression of the LV in patients with ASD shortens the LAO minor axis, resulting in a significantly greater SP overestimation of LV volume than occurs in normals. The degree of SP volume overestimate was not predicted by the magnitude of the left-to-right shunt or pulmonary pressure. This source of error affects all SP methods for determining left ventricular volume, including radionuclide techniques using static images.     

Assessment of left ventricular wall thickness in healed myocardial infarction by magnetic resonance imaging

The ability of magnetic resonance imaging (MRI) to detect and localize healed myocardial infarction (MI) was assessed. Seventeen consecutive patients with healed MI assessed by biplane contrast ventriculography underwent MRI using oblique imaging planes. Seven normal subjects underwent MRI as controls. In each patient, ventriculography identified regional wall motion abnormalities. MRI, performed with a 0.15-Tesla resistive magnet and oblique imaging planes relating to the left ventricle, detected zones of regional wall thinning conforming to the wall motion abnormalities localized by ventriculography in 16 patients. In these patients, adjacent areas of intact myocardium were identified in areas shown by ventriculography to be normal. The left ventricular wall thickness at the site of MI was significantly less than adjacent noninfarcted myocardium (p less than 0.001) and normal hearts (p less than 10(-6)). The ratio of the thickness of the infarct to adjacent normal wall averaged 0.40 (range 0.22 to 0.62). MRI could differentiate healed MI from adjacent noninfarcted myocardium and normal hearts.     

Evaluation of segmental left ventricular wall motion by equilibrium gated radionuclide ventriculography.

The ability of equilibrium gated radionuclide ventriculography to detect segmental left ventricular (LV) wall motion abnormalities was determined in 26 patients undergoing cardiac catheterization. Multiple gated studies obtained in 30 degrees right anterior oblique and 45 degrees left anterior oblique projections, played back in a movie format, were compared to the corresponding LV ventriculograms. The LV wall in the two projections was divided into eight segments. Each segment was graded as normal, hypokinetic, akinetic, dyskinetic, or indeterminate. Thirteen percent of the segments in the gated images were indeterminate; 24 out of 27 of these were proximal or distal inferior wall segments. There was exact agreement in 86% of the remaining segments. The sensitivity of the radionuclide technique for detecting normal versus any abnormal wall motion was 71%, with a specificity of 99%. Equilibrium gated ventriculography is an excellent noninvasive technique for evaluating segmental LV wall motion. It is least reliable in assessing the proximal inferior wall and interventricular septum.     

Standard contraction curves of the left ventricle for the objective quantification of segmental kinetics

Two left ventricle angiographically-standard contraction curves are proposed: one for the 30-degree right anterior oblique (RAO) projection, and the other for the 60-degree left anterior oblique (LAO) projection. These curves are obtained by a calculation which uses the end-diastolic and end-systolic silhouettes along with the longitudinal axes. The best calculation method, which is different in the two projections, has been identified by computer testing of a number of hypothesis over a "normal" population of 18 pairs of RAO and 7 pairs of LAO silhouettes. The working hypothesis was selected by minimizing the standard deviation. In both projections the percent reduction of 20 areas is performed. The 20 RAO areas are defined by 10 equidistant orthogonal coordinates which intersect the longitudinal axis; moreover, the longitudinal axis "angiographic shortening", becomes divided into "cavity real shortening" and "apical parietal effacement'. The 20 LAO areas are defined by radial axes spaced by 15 degree intervals. The proposed standard curves show a low standard deviation of the calculated points: mean 7.8% +/- 3.68 (SD) for the RAO curve, and mean 9.8% +/- 3.68 for the LAO curve. These curves achieve the goal of a standard reference for the objective evaluation of the left ventricle segmentary contraction analysis.     

Evaluation of segmental left ventricular wall motion by equilibrium gated radionuclide ventriculography

The ability of equilibrium gated radionuclide ventriculography to detect segmental left ventricular (LV) wall motion abnormalities was determined in 26 patients undergoing cardiac catheterization. Multiple gated studies obtained in 30° right anterior oblique and 45° left anterior oblique projections, played back in a movie format, were compared to the corresponding LV ventriculograms. The LV wall in the two projections was divided into eight segments. Each segment was graded as normal, hypokinetic, akinetic, dyskinetic, or indeterminate. Thirteen percent of the segments in the gated images were indeterminate; 24 out of 27 of these were proximal or distal inferior wall segments. There was exact agreement in 86% of the remaining segments. The sensitivity of the radionuclide technique for detecting normal versus any abnormal wall motion was 71%, with a specificity of 99%. Equilibrium gated ventriculography is an excellent noninvasive technique for evaluating segmental LV wall motion. It is least reliable in assessing the proximal inferior wall and interventricular septum.     

Left ventricular volumes by single-plane cineangiography: in vivo validation of the Kennedy regression equation

This study was performed to assess the accuracy and reliability of the regression equations of Kennedy et al and Wynne et al in the quantitation of single plane left ventricular (LV) volumes. In 15 patients with normal LV function and without intracardiac shunting or valvular insufficiency, gated equilibrium blood pool scintigraphy was performed simultaneously with the measurement of cardiac output (by thermodilution), after which left ventriculography was performed in the 30 degrees right anterior oblique (RAO) projection. From the scintigraphically determined LV ejection fraction (EF) and the thermodilution-measured stroke volume (SV), absolute LV volumes were calculated. The cineangiographic LV volumes obtained with the regression equation of Kennedy et al closely approximated those calculated by scintigraphy/thermodilution, whereas the volumes determined using the regression equation of Wynne et al were larger (p less than 0.05) than the calculated volumes. In 204 patients without intracardiac shunting or valvular insufficiency, SV was measured by the Fick or indicator dilution methods, after which single-plane left ventriculography was performed in the 30 degrees RAO projection. In the 83 patients without coronary artery disease with normal (n = 69) or depressed (n = 14) LVEF, cineangiographic SV (obtained using the regression equation of Kennedy et al) closely approximated forward SV. Similarly, this relation was excellent in the 142 patients whose LVEFs were greater than or equal to 0.50.(ABSTRACT TRUNCATED AT 250 WORDS)     

Negative U-wave as a predictor of antihypertensive treatment effect on regression of echocardiographic hypertrophy in hypertensive patients.

To clarify the mechanism and the predictors of the reduction in left ventricular mass (LVM) induced by antihypertensive drugs, forty hypertensive patients were classified according to the presence of left ventricular hypertrophy (LVH) as a defined by echocardiographic LVM findings (LVH group: 27 patients, non-LVH group: 13 patients) and according to the presence of negative U-waves (NU) (NU group: 10 patients, non-NU group: 30 patients). Negative U-waves appeared in the LVH group only (10 of 27 patients). The hemodynamic determinants were investigated as a mechanism of LVM reduction in 38 of these patients who were treated for 2 years with antihypertensive drugs. In the LVH group, thickness of interventricular septum (IVST), posterior wall thickness (PWT) and LVM increased significantly compared to the non-LVH group. In the NU group, the left ventricular end-diastolic dimension (LVDD) was significantly larger and the relative wall thickness was significantly smaller compared to the non-NU group in the LVH group, with no difference in LVM between the two groups. Negative U-waves disappeared in all cases after treatment. Significant decreases in LVDD and LV wall thickness were observed in the NU group and significant decrease in LV wall thickness in the non-NU group. LVM index was reduced by 24.0% in the NU group and 9.5% in the non-NU group. The disappearance of negative U-waves was an independent predictor of the reduction of LVH.     

Identification of less-irradiating tube angulations in invasive cardiology

OBJECTIVES: We sought to identify tube angulations in invasive cardiology, which promise minimal radiation exposure to patients and operators. BACKGROUND: Radiation exposure in invasive cardiology is high. METHODS: We mapped the fluoroscopic dose-area product per second (DAP/s), applied to an anthropomorphic Alderson-Rando phantom and, in absence of radiation protection devices, the mean personal dose in the operator's position in 10 degrees steps from the 100 degrees right anterior oblique (RAO) to the 100 degrees left anterior oblique (LAO) projection, as well as for all geometrically feasible craniocaudal tube angulations. RESULTS: For our specific setting conditions RAO 20 degrees /0 degrees tube angulation generated the lowest DAP/s and operator's personal dose. The mean patient DAP/s and operator personal dose for all postero-anterior (PA) projections, cranialized and caudalized together, rose significantly: 3.7 and 10.6 times the PA 0 degrees baseline values toward LAO 100 degrees and 3.7 and 2.4 times toward RAO 100 degrees , respectively. Patient and operator values for all PA projections, angulated to the right and left, increased approximately 2.5 times toward 30 degrees craniocaudal angulations. Caudal PA 0 degrees /30 degrees - angulation instead of caudal LAO 60 degrees /20 degrees - angulation for the left coronary main stem and cranial PA 0 degrees /30 degrees + view in place of cranial LAO 60 degrees /20 degrees + view for the left anterior descending coronary artery bifurcation enable 2.6-fold dose reductions to the patient and eight- and five-fold dose reductions to the operator, respectively. CONCLUSIONS: The PA views and RAO views >or=40 degrees , heretofore unconventional in clinical routine, should be favored over steep LAO projections >or=40 degrees whenever possible. Tube angulations that are radiation intensive to the patient exponentially increase the operator's radiation risk.     

Phase and amplitude images using Fourier analysis in radioisotopic angiography. Comparison with contrast angiography for studying regional changes in ventricular contraction

Phase-amplitude images and phase distribution histograms, derived from a temporal Fourier analysis of equilibrium ecg-gated blood pool studies, were used to assess the overall wall motion synchronism and to detect regional wall motion abnormalities in 69 consecutive patients with suspected or documented coronary artery disease, in whom biplane contrast left ventriculography and coronary angiography were performed. Four regions were considered on the 15 degrees caudal left-anterior oblique view radionuclide image, in order to identify the 7 conventional angiographic left ventricular wall segments (as the American Heart Association Council of Cardiovascular Surgery). Regional abnormalities on the phase-amplitude images from the 15 degrees caudal left anterior oblique view scans were studied in order to identify local hypokinesis, akinesis or dyskinesis (in accord to definitions used for contrast cineangiography) relative to seven conventional left ventricular wall segments. Results of phase-amplitude image analysis were compared with those of contrast cineangiography. The parametric images showed overall sensitivity of 82% and 92% respectively towards biplane and monoplane (left anterior oblique) contrast cineangiography, with a high degree of specificity (97%). Most akinetic and dyskinetic segments were correctly identified. A significant phase delay (greater than or equal to 70 degrees) from mean value, always occurred in dyskinetic segments and generally related to the severity of the wall motion abnormality. Lower accuracy was observed for hypokinetic regions; sensitivity was lower for apical and antero-lateral segments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Accuracy of biplane axial oblique and oblique cineangiographic left ventricular cast volume determinations using a modification of Simpson''s rule algorithm

In order to compare biplane left ventricular cast volume determinations from orthogonal and nonorthogonal axial oblique and standard orthogonal oblique cineangiograms to those that were obtained by water (H2O) displacement, we evaluated 14 human heart specimens in the following projections: 30-degree right anterior oblique and 60-degree left anterior oblique/20-degree cranial (LVa), 45-degree left posterior oblique and 60-degree left anterior oblique/30-degree cranial (LVb), and 30-degree right anterior oblique and 60-degree left anterior oblique (LVc). The correlation coefficients and standard errors of the estimate (SEEs) for the biplane orthogonal and nonorthogonal axial oblique (LVa and LVb, respectively) and standard orthogonal oblique (LVc) cineangiographic left ventricular volume determinations compared with the left ventricular cast volumes obtained by H2O displacement were similar (each r = 0.99 with SEEs = 5 to 7 milliliters (ml)). However, the mean biplane cineangiographic cast volume of 69 +/- 43 ml (SD) by LVa exceeded the average left ventricular cast volume of 60 +/- 35 ml by H2O displacement (p less than 0.01), while the average left ventricular cast volumes obtained with LVb and LVc (63 +/- 35, and 60 +/- 34 ml, respectively) did not differ significantly from the mean left ventricular cast volume obtained by H2O displacement. We concluded that the biplane orthogonal and nonorthogonal axial oblique cineangiographic views of the left ventricle, which have been reported to improve the delineation of cardiac anatomy, left ventricular regional wall motion, and the assessment of mitral regurgitation, also provide accurate determinations of left ventricular volume that are similar to those calculated from standard biplane orthogonal oblique cineangiograms.     

Preoperative angiocardiography in infants with tetrad of fallot: Review of 36 cases

Angiocardiograms in 36 infants with tetrad of Fallot were reviewed to determine which projections best displayed the anatomy. The occurrence of associated cardiovascular anomalies was also recorded. An additional ventricular septal defect was found in 14 percent (5 of 36), peripheral pulmonary stenoses in 30 percent (10 of 36) and surgically important coronary arterial abnormalities in 8 percent (3 of 36).

This retrospective study indicated that optimal biplane angiocardiography should include: (1) right ventriculography in a sitting or hepatoclavicular view for demonstration of the right ventricular, Infundibular, and pulmonary artery anatomy, (2) left ventriculography in the long axial oblique (cranially angled oblique) view for display of ventricular septal defects and coronary arteries, and (3) an aortogram at the valve level (oblique view) if coronary arteries are not well seen in the left ventricular study.