The echocardiographic assessment of pulmonary artery pressure and pulmonary vascular resistance

Comparison of the hemodynamic and echocardiographic effects of sufentanil, fentanyl, isoflurane, and halothane for pediatric cardiovascular surgery

Sufentanil, fentanyl, halothane, and isoflurane were compared as sole anesthetic agents in 48 infants and children aged 6 months to 9 years, undergoing repair of congenital heart defects. Patients were randomly assigned to receive sufentanil, 20 microg/kg, fentanyl, 100 microg/kg, isoflurane, 1.6%, or halothane, 0.9%, along with pancuronium, 0.08 mg/kg, for induction and maintenance of anesthesia. Cardiovascular function was measured by echocardiography prior to induction, postinduction, and postintubation. Systemic arterial pressure and heart rate were also recorded. Left ventricular ejection fraction (LVEF) decreased following induction with each agent: sufentanil 9%, fentanyl 9%, isoflurane 4%, and halothane 8%. Following intubation LVEF increased in the sufentanil, fentanyl, and isoflurane groups, but LVEF remained 13% below baseline values in the halothane group. Five of the 12 patients in the halothane group had a LVEF less than 55%. Arterial pressure immediately prior to bypass was significantly less than baseline in each group; however, arterial pressure was higher in the narcotic groups during isolation and cannulation of the great vessels. It is concluded that halothane, 0.9%, used as an induction agent in infants and children undergoing cardiac surgery causes a clinically significant decrease in LVEF. Based on the echocardiographic data, sufentanil, fentanyl, and isoflurane as used in the present study do not have a clinically significant effect on cardiac function and may offer an advantage to infants and children with marginal cardiovascular reserve.

Echocardiographic recognition of pulmonary arterial disease and determination of its cause

Echocardiography provided the initial diagnosis of significant pulmonary hypertension, unrelated to left heart pathologic conditions, in 10 patients: four with acute pulmonary embolism; five with chronic pulmonary hypertension, primary in three patients and secondary to tumor emboli in the other two patients; and one with Eisenmenger's syndrome due to previously unsuspected atrial septal defects. Referral diagnoses were pericardial disease in five patients (including three with suspected tamponade), and right ventricular infarction versus pericarditis, atrial septal defect, dyspnea, inferoposterior infarction (by electrocardiography), and Ebstein's malformation in one patient each. The echocardiographic diagnoses were confirmed by lung scan (ventilation/perfusion mismatches were interpreted as high probability for pulmonary emboli in all four patients considered to have acute pulmonary emboli by echocardiographic study), pulmonary angiography (one patient), cardiac catheterization (four patients), and autopsy (three patients). No patient had evident aortic or mitral valvular, myocardial, or other left heart pathologic condition. In acute pulmonary embolism, mean right ventricular diameter was increased at 4.2 cm (range 3.2 to 6 cm) and right ventricular wall thickness was normal (mean 4.5 mm, range 3 to 5 mm). Moderate or marked right ventricular hypokinesis was noted in two patients each. Doppler examination, performed in three patients, revealed tricuspid regurgitation in all, with an increased flow velocity suggestive of mild to moderate systolic pulmonary hypertension (right ventricular minus right atrial pressures of 28 to 36 mm Hg). Patients with chronic pulmonary hypertension also had right ventricular dilatation (mean 4.4 cm diameter, range 3 to 5.4 cm) and hypokinesis (marked in four and moderate in one patient), but wall thickness was increased in all (mean of 9 mm, range 6 to 14 mm) and the flow velocities in the tricuspid regurgitant jets, detected by Doppler in all patients, suggested higher right ventricular minus right atrial pressures of 44 to 104 mm Hg (mean 64 mm Hg). The single patient with Eisenmenger's syndrome had right ventricular dilatation (3.2 cm), hypertrophy (10 mm), and hypokinesis (mild). Only the patient with Eisenmenger's syndrome had Doppler or contrast echocardiographic evidence for an intracardiac or extracardiac shunt. In the absence of left heart pathologic conditions, right ventricular dilatation and hypokinesis strongly suggest pulmonary arterial or primary right ventricular disease.(ABSTRACT TRUNCATED AT 400 WORDS)

Non-invasive measurement of pulmonary arterial pressure: I. A haemodynamic modelling approach

In order to monitor pulmonary arterial pressure (P) by any non-invasive imaging technique, a haemodynamic model of blood flow kinetics and wall mechanics has been developed. It is a one-dimensional model of pulsatile flow in an elastic pulmonary arterial trunk, assuming that blood is an incompressible fluid and viscous effects are negligible. The equations are P(t)-Pd = rho c2lnS(t)/Sd-1/2pw-2(t) Pd = (Sd/Ss)1/2Pp where, at any time of the ejection phase of systole, P(t), S(t) and w(t) are the pulmonary arterial pressure, cross-sectional area of the pulmonary artery and blood velocity averaged on the cross section S, respectively, PP is the pulse pressure, the difference between the peak systolic pressure and the diastolic pressure Pd; rho is blood density, c pulse wave velocity, and Ss and Sd are maximum (systolic) and minimum (diastolic) values of the cross-sectional area S. Using these equations, P(t) can be calculated if the three parameters, i.e. c, S(t) and w(t) are measured. So far, it has been impossible to measure the pulse wave velocity c non-invasively. We have investigated the calculation of c from S(t) and w(t) using the equation of continuity in the absence and presence of reflected pressure waves. The hypotheses of the haemodynamic model are discussed.

Prediction of peak pulmonary artery pressure by continuous-wave Doppler echocardiography in infants and children

Continuous-wave Doppler echocardiography was used to estimate peak pulmonary artery (PA) pressure in 104 infants and children, aged 4 days to 16 years, with normal hearts (control group) and 43, aged 29 days to 13 years, with various kinds of heart disease (patient group). The Doppler transducer was directed toward the right ventricular outflow tract and angled until the maximal velocity signal was reached. Doppler velocity time intervals were measured as follows: acceleration time (AT), from the onset to the peak of the velocity curve; and ejection time (ET), from the onset to the termination of the velocity curve. In the control group, AT corrected through dividing by the RR interval of the electrocardiogram (ATc), and AT/ET by dividing by the square root of the RR interval (AT/ETc), were independent of body surface area. In the patient group, peak PA pressure had a significant inverse correlation with both ATc (r = -0.78) and AT/ETc (r = -0.87). Thus, AT/ETc derived from continuous-wave Doppler echocardiography is a good quantitative predictor of peak PA pressure in infants and children.

Long-term follow-up of right ventricular function after Mustard operation for transposition of the great arteries

As development of right ventricular (RV) failure is a potential risk after Mustard operation for transposition of the great arteries, 17 patients were reexamined 5-13 years postoperatively. Comparisons were made with healthy controls. There were no clinical signs of heart failure. Echocardiographically determined RV end-diastolic diameter was increased to 2.5 +/- 0.8 cm (controls: 1.5 +/- 0.4 cm, p less than 0.001). Comparison of RV systolic time intervals (STI) in patients with normal left ventricular (LV) STI revealed decreased RV function, with RPEPI 165 +/- 19 msec (controls 126 +/- 12, p less than 0.001) and RPEP/RVET 0.484 +/- 0.096 (controls 0.284 +/- 0.045, p less than 0.001). Nuclear angiography demonstrated decreased RV ejection fraction (EF), viz. 42.8 +/- 6.6% (normal RV 53 +/- 6%, LV 68 +/- 9%, p less than 0.001). Only two patients showed normal (5%) rise in RV-EF during exercise. There was no evidence of deterioration with passage of time. The results do not justify use of anatomic repair at our center, since the perioperative mortality might then be higher than in the Mustard or Senning procedures.

Left ventricular systolic circular index: an echocardiographic measure of transseptal pressure ratio

An echocardiographic index of left ventricular (LV) short axis circularity can be defined by the equation: left ventricular systolic circularity index (LVSCI) = 4 pi(LV area) X 100/(LV perimeter). This index was measured from two-dimensional echocardiograms in 98 children (ages 1 day to 19 years) with congenital heart disease, and results were compared to right ventricular/left ventricular peak systolic pressure ratios (RVP/LVP) determined at cardiac catheterization. LVSCI was also computed in 50 children without cardiovascular or pulmonary disease to define the normal range. A short axis image of the left ventricle at the level of the papillary muscles was obtained from the left parasternal position. Area and perimeter were determined by computer planimetry of the LV endocardium at end systole. LVSCI was measured from three consecutive beats and averaged. In the normal group all values of LVSCI exceeded 93% (mean 96%). In the group with congenital heart disease RVP/LVP correlated exponentially with LVSCI: RVP/LVP = e2.6-0.04 LVSCI; with r = 0.88, SEE = 0.39, and p less than 0.001. If patients with suprasystemic right ventricular pressures (RVP/LVP greater than 1.2) are excluded, there is a linear correlation between RVP/LVP and LVSCI: RVP/LVP = 2.3-0.021 LVSCI; with r = 0.80, SEE = 0.14, and p less than 0.001. LVSCI could distinguish between patients with normal, mildly elevated, moderately elevated, and severely elevated RVP/LVP. We conclude that LVSCI is a readily determined parameter that is independent of age or body size and predicts RVP/LVP in children with congenital heart disease.

The value of right atrial emptying rate in predicting reduction in pulmonary artery pressure in patients with chronic obstructive pulmonary disease

We used an improved noninvasive radionuclide method, recently developed by us, to evaluate changes in pulmonary artery pressure induced by sublingual nifedipine in patients with chronic obstructive pulmonary disease and pulmonary hypertension. The new method enhances the predictive power of right ventricular ejection fraction by using the right atrial emptying rate as an index of reduced right ventricular compliance. The results were compared to those of invasively measured pulmonary arterial pressure. In the 21 patients studied 20 mg of nifedipine sublingually reduced pulmonary arterial pressure by 13.35% from 36.95 +/- 13.95/12.71 +/- 6.24 (mean 20.79 +/- 8.19) mmHg to 32.67 +/- 12.17/10.9 +/- 6.2 (mean 18.16 +/- 7.3) mmHg (p less than 0.05 for all pressures). Cardiac index increased and the pulmonary and systemic resistances decreased. The percent changes in right atrial emptying rate showed an excellent correlation with the percent change in pulmonary pressure. An increase of 12% or more in right atrial emptying rate predicted in all patients a reduction in pulmonary arterial pressure of at least 8%, the specificity and positive predictive accuracy being 100%. The sensitivity and the predictive accuracy of a negative test were 93% and 80%, respectively. The new method is useful for long-term evaluation of drug therapy in patients with pulmonary hypertension.

Noninvasive prediction of pulmonary hypertension in chronic obstructive pulmonary disease by Doppler echocardiography

Thirty-six patients with chronic obstructive pulmonary disease (COPD) were studied by pulsed Doppler echocardiography. In 32 of the 36 patients, adequate Doppler signals were obtained in the pulmonary arterial trunk and correlated with right cardiac hemodynamics. The studied group included 26 patients with mean pulmonary arterial pressure (MPAP) greater than 20 mm Hg at rest (group A, with pulmonary hypertension) and six patients with MPAP of 20 mm Hg or less (group B, without pulmonary hypertension). A control group (group C) consisted of 12 subjects with normal hemodynamic data and pulmonary function. Analysis of Doppler data included flow velocity curve pattern, presence of a negative presystolic velocity, right ventricular pre-ejection period (RVPEP) and ejection period (RVEP), time between onset and peak of pulmonary velocity (time to peak velocity, TPV) and derived ratios of TPV/RVPEP and TPV/RVEP. In patients with pulmonary hypertension, the Doppler flow velocity curve in the pulmonary trunk showed a rapid acceleration and an early deceleration. The mean value for TPV was 78 +/- 12 msec in group A, 115 +/- 11 msec in group B, and 127 +/- 10 msec in group C. In patients with COPD, significant correlations were observed between TPV and log10 MPAP (r = -0.77; SEE = 0.07) and between TPV and log10 total pulmonary resistances (r = -0.84; SEE = 0.05). Accordingly, pulsed Doppler echocardiography may be a useful tool to predict pulmonary hypertension due to chronic pulmonary disease.

Evaluation of pulmonary artery pressure and resistance by pulsed Doppler echocardiography

Pulsed Doppler echocardiography was used to examine the relation between pulmonary valve motion and pulmonary artery (PA) flow velocity patterns in 39 adults. In 16 patients with normal PA pressure (mean pressure less than 20 mm Hg), PA flow velocity accelerated slowly to a peak flow velocity at midsystole (time to peak flow velocity, or acceleration time = 134 +/- 20 ms [mean +/- standard deviation]), followed by a slow deceleration to the end of ejection, producing a "dome-like" appearance. In contrast, in 23 patients with elevated PA pressure (mean pressure 20 mm Hg or more), flow velocity accelerated rapidly to a peak flow velocity in early systole (acceleration time = 88 +/- 25 ms, p less than 0.01), followed by rapid flow velocity deceleration to a nadir in midsystole. In 13 of these patients, a transient increase in flow velocity occurred in late systole, producing a "spike and dome" appearance. In patients with an acceleration time of 120 ms or less, there was a negative linear correlation with mean PA pressure, expressed by the equation: mean PA pressure = 90 - (0.62 X acceleration time). The standard error of the estimate was 8.3 mm Hg. A similar negative linear correlation was found between PA acceleration time and total pulmonary resistance. Using a PA acceleration time of 100 ms or less resulted in a 78% sensitivity and a 100% specificity for detection of elevated PA pressure. Although this Doppler method cannot precisely estimate PA pressure, it can be helpful in separating patients with normal pressure from those with elevated PA pressure.

Comparison of three Doppler ultrasound methods in the prediction of pulmonary artery pressure

Pulmonary artery pressure was noninvasively estimated by three Doppler echocardiographic methods in 50 consecutive patients undergoing cardiac catheterization. First, a systolic transtricuspid gradient was calculated from Doppler-detected tricuspid regurgitation; clinical jugular venous pressure or a fixed value of 14 mm Hg was added to yield systolic pulmonary artery pressure. Second, acceleration time from pulmonary flow analysis was used in a regression equation to derive mean pulmonary artery pressure. Third, right ventricular isovolumic relaxation time was calculated from Doppler-determined pulmonary valve closure and tricuspid valve opening; systolic pulmonary artery pressure was then derived from a nomogram. In 48 patients (96%) at least one of the methods could be employed. A tricuspid pressure gradient, obtained in 36 patients (72%), provided reliable prediction of systolic pulmonary artery pressure. The prediction was superior when 14 mm Hg rather than estimated jugular venous pressure was used to account for right atrial pressure. In 44 patients (88%), pulmonary flow was analyzed. Prediction of mean pulmonary artery pressure was unsatisfactory (r = 0.65) but improved (r = 0.85) when only patients with a heart rate between 60 and 100 beats/min were considered. The effect of correcting pulmonary flow indexes for heart rate was examined by correlating different flow indexes before and after correction for heart rate. There was a good correlation between corrected acceleration time and either systolic (r = -0.85) or mean (r = -0.83) pulmonary artery pressure. Because of a high incidence of arrhythmia, right ventricular relaxation time could be determined in only 11 patients (22%). Noninvasive prediction of pulmonary artery pressure is feasible in most patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Pulsed Doppler echocardiographic evaluation of neonatal circulatory changes

Pulsed Doppler echocardiograms were obtained from 42 normal fullterm neonates at less than 12 hours (20 subjects), 4 days (20 subjects), and 33 days (12 subjects). The acceleration time of the flow velocity and ventricular systolic time intervals were measured on recordings obtained at the right and left ventricular outflow tract, and the patency of the ductus arteriosus was evaluated by the flow at the pulmonary end of the ductus. The flow velocity pattern of the right ventricular outflow tract changed from a triangular shape with a peak velocity in early systole in the younger age groups to a dome-like contour with a peak velocity in mid-systole; thus the ratio of mean acceleration time to right ventricular ejection time increased with age. The flow velocity pattern of the left ventricular outflow tract was triangular in all age groups, and the ratio of mean acceleration time to left ventricular ejection time showed no significant change with age. The right ventricular pre-ejection period shortened and the right ventricular ejection time lengthened with age; thus the ratio of mean right ventricular pre-ejection period to right ventricular ejection time decreased with age. The left ventricular systolic time intervals showed no significant change with age. The ductus arteriosus was patent in all subjects who were less than 12 hours old but was closed in the older neonates. Pulsed Doppler echocardiography is a valuable method of evaluating pulmonary vascular bed in the early neonatal period.

Determination of right ventricular pressure in the presence of a ventricular septal defect using continuous wave Doppler ultrasound

Continuous wave Doppler ultrasound was employed in 38 patients with ventricular septal defects, many with associated lesions, to measure the velocity (V) of the shunted blood. Using the modified Bernoulli equation (delta P = 4V2) the pressure difference (delta P) between the ventricles was determined. In 22 patients both right ventricular and either left ventricular or ascending aortic pressure were measured at the time shunt velocity was determined. In another 16 patients these measurements were not obtained simultaneously but in most they were done within 24 hours of each other. In the entire group, measured pressure differences between the ventricles (or aorta and right ventricle) ranged from 0 to 97 mm Hg (mean 52 +/- 24). On the basis of velocity measurements the pressure difference ranged from 7 to 112 mm Hg (mean 51 +/- 24). A close correlation was found between the two methods (r = 0.95, SEE = 7.8 mm Hg). This accuracy was not altered by associated lesions. These findings indicate that by the use of continuous wave Doppler interrogation right ventricular pressure can be accurately measured in the presence of a ventricular septal defect.

Factors affecting use of the Doppler-determined time from flow onset to maximal pulmonary artery velocity for measurement of pulmonary artery pressure in children

Measurement of the time from onset to maximal or peak velocity (TPV) of pulmonary artery (PA) flow has been proposed as a noninvasive means of determining PA pressure. The effects of age, heart rate, increased PA pressure and flow, pulmonary valve obstruction and altered PA vascular resistance on this measurement were evaluated. In 84 children, aged 1 day to 18 years, TPV was measured using continuous-wave Doppler echocardiography. The children were separated into 3 groups. Group I (n = 33) consisted of children with no cardiovascular abnormalities. Group II (n = 33) consisted of children with a variety of cardiovascular diseases producing varying PA pressures and flows. Group III (n = 18) consisted of children who had valvular pulmonic stenosis with PA to right ventricular gradients greater than 40 mm Hg. Doppler studies of group II and III patients were performed in conjunction with measurement of PA pressures and flows at the time of cardiac catheterization. In group I TPV showed a significant negative linear correlation with heart rate (r = -0.86, p less than 0.001). The ratio of observed TPV to predicted TPV (TPVN) determined using the regression equation for TPV vs heart rate or TPV/TPVN was heart rate- and age-independent (p greater than 0.1) and ranged from 0.81 to 1.31 (mean 1.005). In group II TPV/TPVN was inversely related to the natural log of the PA pressures (systolic, r = -0.91; mean, r = -0.87; diastolic, r = -0.82; all p less than 0.01), whether pressure elevation was due to increased flow, resistance or left atrial hypertension.(ABSTRACT TRUNCATED AT 250 WORDS)

Right ventricular systolic time intervals: comparison of echocardiographic and Doppler-derived values

Although the clinical utility of right ventricular (RV) systolic time intervals (STI) has been well documented, their use is at times limited by an inability to obtain adequate M-mode echocardiographic images of the pulmonary valve. Therefore the relationship between the pulmonary artery Doppler flow tracing and the timing of pulmonary valve opening and closure was investigated to determine if the more readily available Doppler recording could be utilized for determining RV STIs. We compared RV preejection period (PEP), ejection time (VET), and PEP/VET ratio derived from the pulsed Doppler frequency-time curve recorded in the main pulmonary artery with measurements from a simultaneously recorded M-mode pulmonary valve echocardiogram (Echo). The nadir of the late systolic flow reversal, rather than the point at which the frequency spectrum crosses the zero baseline, correlated best with the point of pulmonary valve closure. By the use of this method for determining end-systole, all three Doppler-derived measurements were highly correlated with the values from the pulmonary valve echocardiogram: PEPEcho = 1.01 PEPDoppler - 3.1 (r = 0.990, S.E.E. PEPEcho = 2.7 msec); VETEcho = 0.98 VETDoppler + 10.2 (r = 0.998, S.E.E. VETEcho = 3.3 msec); (PEP/VET)Echo = 0.95 (PEP/VET)Doppler + 0.007 (r = 0.980, S.E.E. (PEP/VET)Echo = 0.012 msec). The Doppler velocity-time curve provides accurate measurement of RV STIs that can be recorded with relative ease compared with the pulmonary valve echocardiogram. This expanded availability of RV STIs permits an improved ability to investigate the hemodynamic determinants of these indices and their relation to the status of the pulmonary vasculature and right ventricular performance.

Comparison of Doppler-determined elevated pulmonary arterial pressure with pressure measured at cardiac catheterization

This study assesses use of pulsed Doppler echocardiography to measure pulmonary artery (PA) pressure. PA flow at the right ventricular (RV) outflow tract was analyzed in 51 patients. Attention was focused on PA flow morphologic pattern, RV systolic intervals, time to peak flow and acceleration time index. Correlation was made with PA pressure and total pulmonary resistance. Three morphologic patterns of PA flow were found: type I indicates normal PA pressure (sensitivity 85%, specificity 100%) and types II and III indicate PA hypertension (sensitivity 100%, specificity 85%). The RV preejection/RV ejection ratio, time to peak flow and acceleration time index show a good correlation coefficient improved when a logarithmic function was applied. The best correlation was achieved with time to peak flow (r = -0.77 with PA pressure, r = -0.79 with total pulmonary resistance), and especially with acceleration time index (r = -0.84 with PA pressure, r = -0.87 with total pulmonary resistance). Analysis of pulmonary flow is a reliable new tool for evaluating PA pressure and is even better for evaluating total pulmonary resistance. Acceleration time index is the parameter that correlates best with these 2 variables.

Prediction of pulmonary arterial pressure in adults by pulsed Doppler echocardiography

Doppler echocardiography was used to estimate pulmonary artery (PA) pressure in 45 adult patients with various kinds of heart disease and the patterns were compared with those of 32 normal control subjects. Doppler signals obtained in the right ventricular (RV) outflow tract just proximal to the pulmonary valve and electrocardiogram were recorded simultaneously. Doppler velocity time intervals were measured as follows: RV preejection period, acceleration time from the onset of the RV ejection flow velocity to the peak, and RV ejection time. Thirty patients had PA hypertension and 16 patients had a low cardiac index. The best correlation with PA pressure was achieved by the RV preejection period/acceleration time index (r = 0.89 vs mean pressure). Sensitivity and specificity for predicting PA hypertension were 93% and 97%, respectively. Acceleration time correlated best with the logarithm of PA mean pressure (r = 0.88). Patients were separated into 2 groups according to cardiac index. In those patients with a cardiac index of less than 2.5 liters/min/m2, both RV preejection period/acceleration time and acceleration time were significantly correlated with PA mean pressure (r = 0.87) and log (PA mean pressure) (r = -0.87), respectively. However, the slope of the regression line for acceleration time and log (PA mean pressure) was significantly steeper than that for patients with a cardiac index of greater than or equal to 2.5 liters/min/m2 (p less than 0.05), whereas the relation between RV preejection period/acceleration time and PA mean pressure in the 2 groups could not be differentiated statistically from each other. Other intervals and ratios were less quantitative because of late systolic turbulent flow and individual variability.(ABSTRACT TRUNCATED AT 250 WORDS)

Improved radionuclide method for assessment of pulmonary artery pressure in COPD

An improved method of noninvasive assessment of pulmonary arterial pressure is presented. The already existing radionuclide method for assessment of pulmonary arterial pressure based on right ventricular ejection fraction, although having a relatively good positive predictive accuracy (75 percent), lacks in specificity and correlates only weakly with pulmonary arterial pressure, r = .66. In the present study a diastolic index of the ventricular performance (right atrial early diastolic emptying rate) was used to improve the predictive value of the right ventricular ejection fraction. Phase image analysis was used to differentiate the right atrium from the rest of the cardiac structures, and right atrial emptying rate was calculated after time activity curves were generated. A reasonably good correlation was found between right atrial emptying rate and pulmonary arterial pressure, r = .75. This diastolic index, however, was limited in its ability to detect patients with COPD and normal pulmonary arterial pressure (negative predictive value 62 percent). In order to improve the predictive value of right ventricular ejection fraction, having low specificity (33 percent) but high sensitivity (93 percent), a score index was constructed, combining right ventricular ejection fraction with right atrial emptying rate (having high specificity 100 percent, but modest sensitivity 78 percent). Score index proved to be an excellent indicator of pulmonary arterial hypertension (positive predictive value 93 percent, negative predictive value 100 percent.

Effect of intralipid on the neonatal pulmonary bed: an echographic study

The effect of Intralipid infusion on pulmonary vascular resistance was studied prospectively by serial echocardiography on 13 occasions in six low birth weight infants. After 90 minutes of Intralipid infusion, the ratio of right ventricular preejection period to ejection time (RVPEP/ET) rose from 0.232 +/- 0.025 (mean +/- SD) to 0.285 +/- 0.035 (P = 0.0001). Of the 13 infusions studied, six (43%) resulted in RVPEP/ET values suggestive of pulmonary hypertension. Six LBW infants were observed over the same time period without Intralipid infusion, and RVPEP/ET did not change (0.209 +/- 0.035 vs 0.194 +/- 0.024). The increase in RVPEP/ET with Intralipid administration could not be explained by differences in preload or contractility, and most likely reflects an increase in pulmonary vascular tone. Caution in the use of Intralipid is recommended in infants who would be at particular risk from increased pulmonary vascular resistance.

Magnetic resonance imaging in pulmonary arterial hypertension

Magnetic resonance imaging (MRI) was used to examine the right ventricle and pulmonary arteries in 17 patients with pulmonary artery (PA) hypertension documented by cardiac catheterization. The study population consisted of 7 patients with primary pulmonary hypertension, 7 with Eisenmenger's syndrome and 3 with pulmonary hypertension secondary to lung disease. The MRI studies of patients were compared with those of 10 normal volunteers. Multislice gated transaxial images encompassed the right ventricle and central pulmonary arteries, showing the severity of right ventricular (RV) hypertrophy in proportion to the elevation of PA pressure and reversal of septal curvature when PA pressure approximated systemic pressure. End-diastolic RV wall thickness and mean pulmonary pressure correlated well (r = 0.79). MRI showed enlargement of PAs in all patients with PA hypertension. A magnetic resonance signal was present in the PAs throughout the cardiac cycle in patients with severe PA hypertension (more than 90 mm Hg) and was absent during systole in normal subjects. A signal within the PAs in systole is consistent with decreased flow velocity in patients with severe PA hypertension. MRI was useful in detecting each of the congenital anatomic defects in patients with Eisenmenger's syndrome. This study indicates the potential of MRI for evaluating the severity of PA hypertension by providing direct measurements of RV wall thickness and PA diameter and by detecting abnormal intraluminal signal intensity during the cardiac cycle.

Echocardiographic assessment of cardiac function in infants and children

Echocardiography has become an established technique for the assessment of cardiac function in infants and children. M-mode echocardiography provides measurements of left ventricular diameter and wall thickness and allows calculation of their rate of change during the cardiac cycle. Left and right ventricular systolic time intervals may be determined from recordings of aortic and pulmonary valve motion. Two-dimensional echocardiographic images may be utilized for the determination of left and right ventricular volume and ejection fraction. Compared with other noninvasive imaging methods, echocardiography is a rapid, safe and inexpensive technique. Moreover, future developments are likely to include improved image processing and computer analysis of two-dimensional images.

Relationship of prospective diabetes control in pregnancy to neonatal cardiorespiratory function

We evaluated two groups of diabetic women in pregnancy who differed primarily in the time of initiation of careful diabetes management. Group A (early) were entered in the first trimester (n = 35); group B (late) were entered in the late second or early third trimester (n = 28). Normal women delivering at the same period were used as controls (n = 23). All infants were evaluated by a thorough clinical and echocardiographic examination between 24 and 72 hours of life. Both groups of infants of diabetic mothers had mild increase in mean thickness of ventricular and septal walls compared with those of normal newborn infants, and both had a significant percentage with septal hypertrophy (43% vs 39%). None of the infants in the early group had respiratory symptoms requiring oxygen therapy, compared with 19% in the late group. The early group had significantly fewer infants with elevated right ventricular systolic time interval ratios than did the late group (20% vs 50%); none of the normal infants had elevated ratios. We conclude that careful management of diabetes in pregnancy reduces the severity of hypertrophic cardiomyopathy, although no advantage of early vs late management was obvious. Early management does significantly reduce the number of infants of diabetic mothers who develop respiratory symptoms requiring oxygen therapy.

Heart rate and systolic time intervals in healthy newborn infants: longitudinal study

To determine the influence of heart rate (HR) on systolic time intervals (STI) in neonates, serial measurements of right ventricular (RVSTI) and left ventricular systolic time intervals (LVSTI) were made on 30 healthy term newborn infants at age 4-8 h, 24-30 h, eight days, and four weeks. STI was related to HR and age. Age-related changes were similar to previously reported results. The preejection periods (RPEP and LPEP) significantly shortened with increasing age, whereas the right and left ventricular ejection times (RVET and LVET) were unrelated to age. RPEP was unrelated to HR, but tended to be prolonged in restless infants. With increasing HR, RVET decreased and RPEP/RVET increased in all age groups, but less at four weeks. A rise in HR of 50/min resulted in an increase of RPEP/RVET by 26% of the mean value at age 4-8 h and by 20% at four weeks. In 14 infants, RVSTI was recorded during a change in HR. In all these infants, RPEP and RPEP/RVET increased with increasing HR. We conclude that HR-related changes of RVSTI in neonates are different from those in older subjects. It should be considered that in neonates elevated values of RPEP/RVET, suggesting increased pulmonary vascular resistance, may be caused by high HR and unrest.

Quantification of left to right shunt in atrial septal defect using systolic time intervals derived from pulsed Doppler velocimetry

Systolic time intervals derived from Doppler velocimetry measurements were used instead of direct pulmonary to systemic flow ratio measurements in adults with atrial septal defect to quantify left to right atrial shunts. Thirteen normal subjects and 25 patients with uncomplicated atrial septal defect confirmed by cardiac catheterisation were studied. The pulmonary to systemic flow ratio (Qp:Qs) expressing the shunt size was determined by the Fick method; in normal subjects the Qp:Qs ratio was assumed to be equal to 1.0. The pulsed Doppler analogue velocity recording of flow in the pulmonary artery and the ascending aorta was taken as indicating the ejection time of each ventricle and the Q wave of the electrocardiogram as indicating the onset of systole. From these measurements the ratios of the pre-ejection periods to the ejection times (haemodynamic ratio) were calculated for each ventricle and the ratios of each variable (pre-ejection period, ejection time, and haemodynamic ratio) were calculated for both ventricles. Significant differences were found between the normal subjects and the patients with atrial septal defect for all these ratios. When the Doppler findings and the Fick measurements of Qp:Qs were compared the best linear correlation coefficient was for the left to right haemodynamic ratio. It is concluded that the use of a ratio involving several variables, such as the pre-ejection period and the ejection time for both ventricles, improves the reliability of this method, which appears to be applicable in adults.

Cross sectional echocardiographic assessment of cardiac chamber size and ejection fraction in children

Cross sectional echocardiography can be used to determine left ventricular size and ejection fraction in children. We used two orthogonal planes from the apical four and two chamber planes to calculate the left ventricular volume in 20 children with a variety of congenital heart lesions and compared these volumes with those calculated using angiography. Better correlations were achieved at end diastole than at end systole. Comparisons between ejection fraction calculated by angiography and echocardiography showed the correlation was closer for two-dimensional than M-mode techniques. Studies using newer two-dimensional methods suggest that an even closer correlation for volume and ejection fraction can be achieved than those reported in our initial studies. Most studies which have determined right ventricular volume have used biplane methods combining short axis and four chamber images. We used single plane area-length methods from parasternal short axis and apical four chamber planes to calculate right ventricular volume in 20 children undergoing angiocardiography for a variety of congenital heart diseases. The single plane volume method underestimated the volume calculated from angiography uniformly so that a good estimate of the angiographic ejection fraction was obtained. Adding the volumes derived from each plane provided a closer approximation of the angiographic volumes and a good estimate of the ejection fraction. High resolution ultrasound equipment and computer assisted tracing devices have made accurate noninvasive assessment of volume and function accurate and practical.

Noninvasive estimation of peak pulmonary artery pressure by M-mode echocardiography

In an attempt to predict peak pulmonary artery pressure from routine M-mode echocardiographic tracings, 95 infants and children with congenital heart disease were examined. Following the Burstin method for prediction of peak pulmonary artery pressure, which was originally based on the phonocardiogram and jugular phlebogram, M-mode echocardiography was used to measure the interval from pulmonary valve closure to tricuspid valve opening, namely, the period of isovolumic diastole. The measured interval was plotted on a modified table relating the interval, heart rate and predicted peak pulmonary artery pressure. The peak pulmonary artery pressure predicted by echocardiography was compared with that measured at cardiac catheterization. The correlation between predicted and actual peak pulmonary artery pressure was good (r = 0.86) for routine studies with the patient in the nonsedated state. All patients with a predicted peak pressure less than 40 mm Hg were found at catheterization to have a pressure less than 40 mm Hg. The correlation was better (r = 0.96) when comparing predictions made from the echocardiogram obtained while the patient was sedated for catheterization. Prediction of the magnitude of elevation of peak pressure was especially good when prediction and measurement were nearly simultaneous. Predictions were less accurate in the presence of tachycardia at rates of more than 155 beats/min. The method for estimating peak pulmonary artery pressure from M-mode echocardiographic tracings is reliable, relatively simple and clinically useful.

Noninvasive assessment of right ventricular systolic pressure in atrial septal defect: analysis of the end-systolic configuration of the ventricular septum by two-dimensional echocardiography

This study was performed to determine if 2-dimensional echocardiography (2-D echo) can be used to predict right ventricular (RV) systolic pressure. Ninety-one patients with atrial septal defect were studied prospectively. Analysis of the end-systolic configuration of the ventricular septum (VS) in the short-axis 2-D echocardiogram allowed classification of patients into 4 groups: type A (67 patients)--the VS was more circular at end-systole than at end-diastole; type B (9 patients)--the VS curvature at end-systole was same as or further flattened compared with that at end-diastole; type C (9 patients)--the VS was straight at end-systole; type D (6 patients)--the VS curvature at end-systole was reversed so that it was convex toward the left ventricle. Between these types, the RV pressure was different. The RV systolic pressure ranged from 18 to 55 mm Hg (mean 34 +/- 1) in type A, 46 to 55 mm Hg (50 +/- 1) in type B, 60 to 76 mm Hg (66 +/- 2) in type C, and 72 to 118 mm Hg (93 +/- 7) in type D. The RV systolic pressure was statistically different between types except for types C and D. These data indicate that the end-systolic configuration of the VS in the short-axis 2-D echocardiogram may be useful for the semiquantitative assessment of the RV systolic pressure in patients with atrial septal defect.

Doppler echocardiographic prediction of pulmonary arterial hypertension in congenital heart disease

This study determines the accuracy of Doppler echocardiography (echo) for predicting the presence of pulmonary artery (PA) hypertension from Doppler PA velocity traces. The patient group included 17 patients with congenital cardiac disease who had undergone catheterization. The control group was composed of 15 normal subjects. Doppler traces were analyzed qualitatively and quantitatively. Qualitative assessment included evaluation for a negative presystolic velocity that was the equivalent of the pulmonary a wave detected by M-mode echo. Quantitative assessment included measurement of the following time intervals and ratio of intervals: preejection period (PEP), time to peak velocity (TPV), right ventricular ejection time (RVET), PEP/RVET and TPV/RVET ratios. In the patient group, systolic PA pressure ranged from 22 to 90 mm Hg (mean 50 +/- 23), and mean PA pressure ranged from 12 to 60 mm Hg (mean 32 +/- 17). Five patients had systolic PA pressures of less than or equal to 30 mm Hg and 12 had systolic PA pressures greater than 30 mm Hg. Of 15 control subjects, 14 had a negative presystolic a wave. Of 5 patients with PA pressure less than or equal to 30 mm Hg, 4 had a presystolic negative velocity, and all with higher pressures had no presystolic negative velocity. One patient with pressure less than 30 mm Hg and 2 with PA pressure greater than 30 mm Hg had indeterminate status of presystolic velocity pattern because of turbulence or baseline blanking. The best quantitative indexes for separating patients with normal PA pressure from those with elevated PA pressure were TPV and TPV/RVET, which respectively correlated negatively with systolic PA pressure (r = -0.82, standard error of the estimate [SEE] = 0.02; and r = -0.70, SEE = 0.05). These measurements also correlated negatively with mean PA pressure (r = -0.75, SEE = 0.02; and r = -0.76, SEE = 0.05). Other intervals and ratios had enough individual variability to make them less useful as predictors of PA hypertension.

Diagnosis and follow-up of congenital heart disease in children with the use of two-dimensional Doppler echocardiography

Two-dimensional echocardiography (2D) represents a major advance in non-invasive diagnosis of congenital heart disease (CHD) in children. Nevertheless it has diagnostic limitations in nearly all kinds of heart lesions. These can be overcome for the most part by integration of a pulsed Doppler system. This may be called two-dimensional Doppler echocardiography (2DD). Hereby blood flow information is added to the 2D image. Some common types of CHD including ventricular and atrial septal defects, persistent ductus arteriosus, pulmonic stenosis and coarctation are described with their typical 2DD findings. Non-invasive follow up of children with CHD and early recognition of typical complications can be achieved reliably using 2DD. Future prospects consist in a more quantitative diagnostic application of 2DD.

Detection of right ventricular pressure overloading by thallium-201 myocardial scintigraphy. Results in 57 patients with chronic respiratory diseases

The diagnostic value of thallium 201 (201Tl) myocardial imaging was studied in 57 patients with chronic respiratory diseases, most with COPD (n = 46), by comparing the results to hemodynamic findings. In healthy subjects, the right ventricle (RV) is not visualized; therefore, any recorded activity of the RV was considered as indicating RV hypertrophy due to RV pressure overloading (RVPO). RV activity was graded from 0 (no activity) to 3 (activity greater than or equal to that of the left ventricle). Patients were divided into three groups according to the level of the pulmonary artery mean pressure (PPA): PPA less than or equal to 20 mm Hg (no pulmonary arterial hypertension [PAH] ) = group 1, n = 20; PPA ranging from 21 to 30 mm Hg (mild to moderate PAH) = group 2, n = 20; PPA greater than 30 mm Hg (marked PAH) = group 3, n = 17. RV was visualized in 14 patients in group 3 (82 percent) and in 13 patients in group 2 (65 percent). For all patients with PAH (2 + 3) the sensitivity of 201Tl imaging for the diagnosis of RVPO was of 73 percent, higher than that of ECG and echocardiography (both 51 percent). The sensitivity of 201Tl, even if moderate (65 percent) was better than that of ECG (30 percent) or echo (40 percent) in patients with mild-to-moderate PAH (group 2). A high RV activity (grade 3) was observed in only three patients. The specificity of this method (obtained from results in group 1) was of 80 percent vs 89 percent for echo and 100 percent for ECG. These results suggest that 201Tl myocardial imaging is a rather sensitive method and could be of interest for the noninvasive diagnosis of RVPO in COPD patients.

Ventricular systolic time intervals by simultaneous echocardiographic recording of the semilunar valves during the first days of life: a study of normal newborn infants

A modified ultrasonic method was used to image simultaneously the semilunar valves in order to study comparative neonatal right and left ventricular systolic time intervals (STI) and phasic respiration. We obtained 72 serial M-mode echocardiograms from 24 normal term infants during the first 3 days of life. Right and left ventricular pre-ejection period (RPEP, LPEP), ejection times (RVET, LVET), and STI ratios (RPEP/RVET, LPEP/LVET) did not vary with respiratory variation during the first days of life; aortic (Q-Ac) and pulmonic valve (Q-Pc) closure intervals were uninfluenced by respiration. Widening of Ac-Pc interval beyond 15 msec was present in 56% by day 3. The RPEP/LVET was greater than LPEP/LVET on the first day--a finding previously described in infants with dextro-transposition of the great arteries. Relatively fixed duration of right ventricular systole (Q-Pc) and the absence of inspiratory widening of the Ac-Pc interval, despite decreasing pulmonary vascular resistance, may be related to differences of right ventricular compliance and pulmonary vascular capacitance in the newborn infant.

Noninvasive evaluation of pulmonary hypertension by a pulsed Doppler technique

We used a pulsed Doppler technique to examine the flow velocity pattern in the right ventricular outflow tract in 33 adults. In the patients with normal pulmonary artery pressure (mean pressure less than 20 mm Hg, 16 patients), ejection flow reached a peak level at midsystole (137 +/- 24 msec, mean +/- SD), producing a domelike contour of the flow velocity pattern during systole. In contrast, the flow velocity pattern in patients with pulmonary hypertension (mean pressure greater than or equal to 20 mm Hg, 17 patients) was demonstrated to accelerate rapidly and to reach a peak level sooner (97 +/- 20 msec, p less than .01); in 10 of the pulmonary hypertensive patients a secondary slower rise in flow velocity was observed during a deceleration, resulting in the midsystolic notching. The time to peak flow (acceleration time, AcT) and right ventricular ejection time (RVET) were measured from the flow velocity pattern. Either AcT or AcT/RVET decreased with increase in mean pulmonary artery pressure, and a very high correlation (r = -.90) was found between AcT/RVET and log10 (mean pulmonary artery pressure). The use of this technique permitted the noninvasive estimation of the pulmonary artery pressure.

The pulmonic valve echogram in the assessment of pulmonary hypertension in children

Echocardiographic patterns of pulmonary valve motion and right-sided systolic time intervals were correlated with pulmonary arterial hemodynamics in 56 children with congenital heart defects. The sensitivity of an abnormal a-dip, reduced e-f slope or mid-systolic valve closure in detecting elevated pulmonary artery diastolic or mean pressures or pulmonary to systemic resistance ratio varied from 36 to 62%. Specificities ranged from 50% (e-f slope for increased Rp:Rs) to 93% (mid-systolic closure for PA diastolic pressure greater than 10 mm Hg). Systolic-time-intervals (RPEP/RVET) did not significantly correlate with pulmonary hemodynamics. We therefore conclude that these echocardiographic features are insufficiently sensitive to be clinically applied to detect pulmonary hypertension in pediatric patients, and that only 2 (a-dip and mid-systolic closure) were of sufficient specificity to be useful.

Evaluation of right ventricular volume and ejection fraction in children by two-dimensional echocardiography

We estimated right ventricular volume and ejection by two-dimensional echocardiography (2DE) and compared the measurements with those obtained by right ventricular cineangiography (ANGIO) in 20 children whose ages ranged from 1 month to 10 years and who had a variety of congenital defects. The two echocardiographic planes used for calculating volume were the apical four-chamber (A4C) and parasternal short-axis (SA) planes. End diastolic volume (EDV) and end systolic volume (ESV) were calculated from these planes by single-plane area-length methods. The EDV and ESV were uniformly underestimated, but the estimate of ejection fraction (EF) was satisfactory. For EF, r = 0.83 from the apical four-chamber view and r = 0.78 from the short-axis view. The axes of the two echocardiographic planes passed through different segments of the right ventricle (RV) and we found that the value given by adding the volumes obtained from the two single-plane segments correlated quite well with the value obtained by angiography: for EDV, 2DE = 0.62 ANGIO + 7.0, r = 0.81, standard error of the estimate (s.e.e.) = 15.4 ml; for ESV, 2DE = 0.82 ANGIO + 1.4, r = 0.85, s.e.e. = 6.5 ml; and for EF, 2DE = 0.66 ANGIO + 17.8, r = 0.82, s.e.e. = 7.4 ml. Two-dimensional echocardiography can be used to evaluate right ventricular EF derived from volume measurements or from each of the echocardiographic planes of which, in our series, the apical four-chamber EF provided the better correlation.

Respiratory complications of achondroplasia

Nine patients with achondroplasia who were seen over a three-year period developed significant respiratory complications. Eight had sleep-disordered breathing, including obstructive sleep apnea in five, for which two required tracheostomy. Of the seven patients with significant hypoxemia, five had clinical evidence of cor pulmonale and recurrent pulmonary infiltrates. Two patients died, one with autopsy findings of compression of the medulla at the level of the foramen magnum and one with respiratory and cardiac failure. Appropriate therapy for our patients depended on recognition of the mechanisms that led to the respiratory complications, including (1) chest deformity, (2) upper airway obstruction and sleep-disordered breathing, (3) neurologic complications, and (4) coincidental chronic pulmonary conditions such as asthma.

Echocardiographic and hemodynamic findings in isolated symptomatic coarctation of the aorta in infancy

Echocardiographic findings and cardiac catheterization data were evaluated in 18 infants less than 1 year old in order to define anatomical or pathophysiological features that were associated with early cardiac decompensation. The infants could be divided into three groups: Group I (10 patients) had left ventricular dilatation and depressed contractility in response to the severe systemic hypertension. Group II (3 patients) had marked myocardial hypertrophy In response to the systemic hypertension. Group III (5 patients) were the youngest patients and had findings of right ventricular volume overload and pulmonary hypertension. This study demonstrates that, in early infancy, the ventricular response to simple coarctation of the aorta is variable in infants in a state of cardiac decompensation. The different echocardiographic and hemodynamic findings may be a consequence of the lesion exerting its influence at various stages of the patients' intrauterine or postnatal life. In most patients, resection of the coarctation results in rapid normalization of the echocardiographic findings.

Postural changes in pulmonary blood flow in pulmonary hypertension: a noninvasive technique using ventilation-perfusion scans

To determine whether postural changes in ratio of upper to lower (U:L) zone pulmonary blood flow reflect pulmonary arterial pressures, we used pulmonary perfusion photoscintigraphy to study 12 normal subjects and 10 patients with precapillary pulmonary hypertension (eight classified as "primary" and two as thromboembolic). All patients underwent right-heart catheterization and measurement of pulmonary arterial systolic, diastolic, mean and capillary (wedge) pressures. The distribution of perfusion was then assessed in the supine and erect positions after i.v. injection of technetium-99m-labeled, macroaggregated albumin. Perfusion distribution was corrected for lung volume by xenon-133 equilibrium ventilation scans. In normal subjects, the U:L lung zone perfusion ratio decreased by 70.7 +/- 12.2% with the change in position. The patient group differed (p less than 0.0001) from normal subjects in that there was only a 19 +/- 17.4% shift of U:L ratio with the postural change. The mean pulmonary arterial pressure in the patient groups was 50 +/- 24.2 mm Hg. The postural change in U:L zone ratio correlated significantly with the mean pulmonary arterial pressure (r = -0.84, p less than 0.01) pulmonary arterial systolic (r = -0.83, p less than 0.01) and diastolic pressures (r = -0.72, p less than 0.05) and with the pulmonary vascular resistance (r = -0.74, p less than 0.02). No correlation was found with other hemodynamic, spirometric or blood gas data. We conclude that the postural shift in U:L ratio warrants further exploration as a noninvasive approach for detecting and quantifying pulmonary hypertension.

Long-term follow-up study after closure of secundum atrial septal defect in children: an echocardiographic study

Serial echocardiography was performed in 51 children with isolated secundum atrial septal defect before and after surgery to measure the effects of chronic right ventricular overload on ventricular function. Right ventricular dilation increased dramatically with growth and with size of the left to right shunt only in the youngest children (body surface area less than 0.5 m2). A lesser effect of growth and no significant effect of shunt size were noted in older children. Although an initial decrease in right ventricular size occurred in the first 3 months after operation, persistent right ventricular dilation remained up to 5 years after closure of the interatrial defect in more than 80 percent of patients. Preoperatively, the ratio of the right ventricular preejection period to ejection time was significantly less than that of normal children. This ratio increased dramatically after operation, exceeding normal values early in the postoperative period in 18 of 48 children and persisting in 6 of 22 after 3 months. Left ventricular dimensions were normal early and late after operation. Left ventricular function was apparently normal, although an exceptionally high shortening fraction was noted in 22 (44 percent) of 51 children after operation. Aortic systolic time interval ratios decreased after operation from high normal to low normal values. It is hypothesized that the persistent enlargement of the right ventricle after operation may be due to the chronic preoperative dilation secondary to chronic interatrial shunting. The abnormally high shortening fraction after operation may result from an abnormal left ventricular geometric configuration or abnormality of filling. It is suggested that surgical closure of the atrial defect in the first 3 years of life may prevent these abnormalities.

Radionuclide angiocardiographic assessment of pulmonary vascular reactivity in patients with left to right shunt and pulmonary hypertension

Radionuclide angiocardiography was used to assess pulmonary vascular reactivity in eight patients (nine studies) with a large, relatively unrestrictive intracardiac defect and pulmonary arterial hypertension. Radionuclide angiocardiograms, using technetium-99m pertechnetate, were performed first with the patient breathing room air and then after 10 minutes of breathing a mixture containing 90 percent or more of oxygen. The pulmonary to systemic flow ratios obtained by gamma variate analysis of the radionuclide time-activity curves were compared with those calculated with the Fick principle at the time of cardiac catheterization. There was a good correlation between the two methods both in room air studies (r = 0.88) and in those obtained with 90 percent or more of oxygen (r = 0.94). All six studies (in five patients) with a reactive pulmonary vasculature (judged by a pulmonary vascular resistance at cardiac catheterization of less than 6 units/m2 with oxygen or after tolazoline) had a radionuclide pulmonary to systemic flow ratio of 3.0 or greater with oxygen. The three patients with a nonreactive pulmonary vasculature had a radionuclide pulmonary to systemic flow ratio of 2.3 or less with oxygen, a value that was unchanged from the room air value. These data suggest that radionuclide angiocardiography may be a useful, relatively noninvasive method of assessing pulmonary vascular reactivity in patients with a large, relatively unrestrictive intracardiac defect.

Estimation of pulmonary arterial pressure by measuring the size of the right pulmonary artery in the suprasternal echocardiogram

We studied 175 patients within 24 hr before cardiac catheterization with suprasternal echocardiography to evaluate whether pulmonary arterial hypertension can be derived by measuring the size of the right pulmonary artery. Group I consisted of 103 patients without pulmonary arterial hypertension (enddiastolic less than or equal to 12 mm Hg; mean pressure less than 20 mm Hg) and group II consisted of 72 patients with pulmonary arterial hypertension. The right pulmonary artery could be imaged in 91.2% of the patients studied. The size of the right pulmonary artery at the end of diastole in group I measured 17.9 +/- 0.2 mm (mean +/- SEM) and correlated best to the body surface area in this group (r = 0.63; p less than 0.001). The respective index size amounted to 9.9 +/- 0.1 mm/m2, and was different from that in group II with 14.1 +/- 0.4 mm/m2 (p less than 0.001). The systolic percent expansion of the right pulmonary artery in group I was 21.2 +/- 0.8% and in group II 9.2 +/- 0.8% (p less than 0.001). The index size of the right pulmonary artery for both groups correlated best to the pulmonary enddiastolic pressure (r = 0.82; p less than 0.001). The systolic per cent expansion showed a negative log linear relationship to the pulmonary enddiastolic pressure (r = 0.67; p less than 0.001). Thus, pulmonary arterial pressure can be derived by measuring the size of right pulmonary artery with suprasternal echocardiography.

Estimation of pulmonary artery pressure by ultrasound. A study comparing simultaneously recorded pulmonary valve echogram and pulmonary arterial pressures

To determine the most reliable echocardiographic criteria of the pulmonary valve echo in predicting pulmonary artery (PA) pressures or PA resistance, 48 children, aged 6 months to 16 years with congenital (CHD) or rheumatic heart disease (RHD), were studied. During routine heart catheterization, simultaneously recorded PA pressures and one-dimensional PA valve echograms were obtained. Echocardiographic measurements of the e-f and b-c slopes, the "a" dip, right ventricular (RV) and left ventricular (LV) systolic time intervals (STI; PEP = pre-ejection period; ET = ejection time), and their ratios were compared with PA systolic, diastolic, and mean pressures as well as the pulmonary arteriolar resistance (PAR) and the ratio PAR to systemic resistance (SR). The e-f and b-c slope correlated poorly with PA pressures and PAR. RVPEP/RVET ratio gave a good second-degree polynomial correlation with PA diastolic pressure, PAR and PAR/SR in CHD (r = .78, .79, .87). The correlation was better for children with CHD than for those with RHD. This correlation was also more significant than RVPEP/LVPEP, and RVET/LVET. The "a" dip correlated well with the diastolic PA pressure in CHD and RHD (r = .73). A multivariant analysis of the "a" dip and RVSTI ratios slightly improves the correlation coefficient and the prediction rate for PA diastolic pressures, PAR, and resistance ratios in CHD and CHD + RHD.

Hemodynamic determinants of pulmonary valve motion during systole in experimental pulmonary hypertension

To clarify the determinants of pulmonary valve (PV) motion in pulmonary hypertension, we examined the correlations among PV echo patterns, the pulmonary artery (PA) flow curve just above the PA orifice and the pulmonary artery-right ventricle (PA-RV) pressure gradient. By constricting the PA, we could produce a variety of PV echo patterns, including midsystolic semiclosure in open-chest dogs. Throughout the experiments, the PV echo pattern and PA flow curve were similar in pattern and timing. When the PV echo showed midsystolic semiclosure with reopening. The PA flow curve showed a transient decrease followed by a transient increase during midsystole. The PA-RV pressure gradient became transiently positive (PA pressure greater than RV pressure) and then negative in midsystole only when the PV echo showed midsystolic semiclosure with reopening. In conclusion, PV motion during systole may be instantaneously determined by PA flow change and the PA-RV pressure gradient during the cardiac cycle in experimental pulmonary hypertension.