The right atrium (RA) dilates over time in patients with PH and it represents decreased right ventricular (RV) compliance and RV diastolic dysfunction. It is a reservoir for systemic venous return when the tricuspid valve is closed, a passive conduit during early diastole, and active conduit in late diastole (2). Imaging of the RA is easily obtained in the apical four chamber view where RA dimensions of minor and major axis are measured and planimetry of the RA area in end-systole is performed to evaluate for RA dilation (Figure 1) (3). Indexed RA area to body surface area in adult patients with idiopathic PH has been a predictor of mortality and has been shown to be a prognostic marker for follow up of PH patients in adults and children (4–6).

The inferior vena cava (IVC) can be dilated in patients with PH because of rising RA pressure. It is measured in the subcostal longitudinal view with IVC entering the RA. RA pressure can be estimated by IVC diameter and the presence of inspiratory collapse (7–9). IVC diameter ≤2.1 cm that collapses > 50% with a sniff suggests a normal RA pressure of 3 mmHg (range, 0–5 mmHg). IVC diameter ≥ 2.1 cm that collapses <50% with a sniff suggests a high RA pressure of 15 mmHg (range 10–20 mmHg) (3, 8, 10, 11). In children, the IVC varies with age of the patient. Elevated RA pressure in children can be assessed on the percentage of collapse of the IVC during inspiration rather than an absolute number.

With chronic pressure overload, there is progressive hypertrophy and dilation of the RV. The complex morphology of the RV makes 2D imaging of the RV difficult and frequently requires multiple views in the parasternal, apical, and subcostal views to completely evaluate the RV dimensions. However, current recommendation from the guidelines in assessing the right heart includes a standardized imaging of the RV linear dimensions to evaluate for RV dilation (3). The RV size can be measured from the apical four chamber view at end-diastole in the “RV-focused view” (3, 12). The basal diameter is measured at the level of the tricuspid valve and the mid-cavity diameter is measured at the middle third of the RV at the level of the left ventricular (LV) papillary muscle. The longitudinal dimension is from the plane of the tricuspid valve annulus to the RV apex (Figure 2). Indexed RV end-diastolic diameter measured just above the tricuspid valve annulus reported by Burgess et al. has been associated with poor prognosis in patients with chronic pulmonary disease in adults (13). RV dilation is an early sign of RV maladaptation to increased pressure overload and an early sign of RV dysfunction (14). This has also been shown in children with PAH although the measurements of RV end-diastolic dimension were measured from the parasternal short axis view from M-mode (6). Future studies are needed in RV basal diameters in children with PH to evaluate progressive RV dilation which is an early sign of RV dysfunction.

Right ventricular pressure overload causes flattening of the interventricular septum (IVS) in end-systole into the left ventricle (LV), resulting a “D-shaped” LV in parasternal short axis view. Eccentricity index has been derived from the ratio between the LV anteroposterior dimension and the septolateral dimension at the level of the papillary muscle (Figure 3) (15). LV deformation of the IVS is greatest in end-systole in patients with RV pressure overload. Eccentricity index is abnormal when the ratio is >1.0 and has been shown to correlate well with invasive measurements of pulmonary artery pressure and associated with adverse clinical outcome in adults with PH (5, 16). Serial evaluation of eccentricity index with improvement in this index has been shown in targeted PH therapy in adults (17). The eccentricity index has been shown in children to be worse in patients with idiopathic PH compared to PH associated with congenital heart disease (6). Flattening of the IVS can be classified into mild, moderate, or severe depending on the degree of PH (Figure 3). In the absence of tricuspid regurgitation (TR) to estimate RV pressure, septal flattening offers indirect evidence of elevated pulmonary artery pressure. End-systolic flattening of the IVS has proven to be a sensitive marker for RV systolic hypertension in children (18). RV/LV ratio at end-systole measured at the level of the papillary muscles incorporates RV dimension in the parasternal short axis view and has been shown to correlate with invasive measures of hemodynamics and RV/LV end-systolic ratio >1 is associated with adverse clinical outcomes in children with PH (Figure 4) (19). Flattening of IVS into the LV impairs LV filling. Both the systolic and diastolic volumes are reduced. The importance of ventricular–ventricular interactions is increasingly recognized in patients with PH in both adult and pediatric populations (20, 21). Interventricular septal shift impairs LV diastolic filling, which results in decreased LV function. In severe PH with severe septal shift, the LV mid-cavity or outflow tract may become obstructed and the cardiac output (CO) can be decreased. CO can be estimated from echocardiography by the following equation: CO=LVOT diameter∕22×3.14×VTI LVOT×HR

The LV outflow tract (LVOT) is obtained from the parasternal long axis view and the velocity time integral (VTI) of LVOT is obtained by spectral Doppler from an apical four chamber view tilted anterior to view the LVOT. Cardiac index is calculated by dividing the CO by the body surface area.

An atrial level shunt is important in patients with PH as it provides relief to symptoms of severe PH by increasing systemic flow, reducing RV preload, and increasing CO. Atrial level shunts can be assessed in the parasternal short axis, subcostal short axis, and subcostal long axis views. Contrast echocardiography may also help in the assessment of atrial level shunt. In adults with PH, functional class has been shown to improve with the creation of an atrial level shunt, which leads to cyanosis from right to left shunting but can increase CO. Some series advocate use of an atrial septostomy to prolong survival (22, 23).

The presence of pericardial effusion is associated with increased risk of poor outcome in adults with PH but has not been a prognostic indicator for children (5). The size of the pericardial effusion is not predictive of outcome in children. Pericardial thickening and total pericardial score has been developed to score the amount of pericardial effusion seen in patients with PH (24). Increased pericardial thickening and increased pericardial effusion were found to be higher in adults with severe PH.

The normal TR jet has a maximal velocity of <2.5 m/s (25). The normal estimated systolic pulmonary artery pressure (SPAP) is ≤35 mmHg (26). SPAP can be estimated from a peak TR velocity by continuous-wave Doppler using the modified Bernoulli equation in the absence of RV outflow tract (RVOT) obstruction (27). This is the most useful non-invasive method to predict SPAP. The mean RA pressure must be added to the result of the Bernoulli equation to determine the RV systolic pressure (RVSP). In the absence of RVOT obstruction, the SPAP equals the RVSP. The equation is below: RVSP=SPAP=4TR max2+mean RA pressure mRAP Estimation of SPAP from the TR jet is dependent on the angle and the presence of the sufficient Doppler envelope (Figure 5). Therefore, it is recommended that the TR is obtained from multiple views (apical four chamber view or parasternal views) until the best Doppler angle and the highest velocity are obtained. Adult studies have shown that this method of estimating SPAP correlates linearly with hemodynamic assessment in cardiac catheterizations (28, 29). In pediatric patients with chronic lung disease, this estimate of SPAP using TR velocity has been shown to correctly diagnose the presence or absence of PH in 79% of children but was only able to diagnose correctly the severity of PH in 47%. (30) In a recent prospective trial of pediatric PH patients using TR to estimate SPAP compared to right heart catheterization, overestimation and underestimation of RV pressure occurred and TR velocity was inaccurate in children with elevated right heart pressures (31). Nevertheless, TR is still used clinically and serially to evaluate children with PH.

Estimation of SPAP can also be made in the presence of ventricular septal defect (VSD). This can only be done if there is no RV or LV outflow tract obstruction. This method has been shown to correlate well with invasive measurements obtained by cardiac catheterization (32, 33). The equation is below: SPAP=Systolic blood pressure (SBP)−4V (VSD) max⁡2     (for left to right shunts)SPAP=SBP+4V (VSD) max⁡2 (for right to left shunts) The maximal velocity across the ventricular septal defect is V(VSD)max. Flow direction and velocity across the VSD may help in the diagnosis of PH. Right to left shunt across the VSD and low velocity left to right shunt may suggest the presence of elevated pulmonary pressure (Figure 6). Parasternal and subcostal long axis views are used to interrogate perimembranous VSDs whereas parasternal and subcostal short axis views are best used to interrogate muscular VSDs.

Lastly, SPAP can be estimated in patients with patent ductus arteriosus (PDA) in the following equation: SPAP=SBP−4VPDA max2for left to right shuntsSPAP=SBP+4VPDA max2for right to left shunts The maximal velocity across the PDA is denoted as V(PDA) max. This method has been validated by invasive measurements in cardiac catheterization (34). The flow and velocity across the PDA are dependent on the pressure between the aorta and the main pulmonary artery. Right to left shunting across the PDA indicates SPAP higher than the aortic pressure (Figure 6). Left to right shunting across the PDA indicates lower SPAP compared to the aortic pressure. Bidirectional shunting across the PDA is a common finding in newborns until the pulmonary vascular resistance (PVR) has decreased (Figure 6).

The diastolic pulmonary artery pressure (DPAP) can be estimated from the velocity of the end-diastolic pulmonary regurgitant velocity using the modified Bernoulli equation (Figure 7): DPAP=4V(end-diastolic pulmonary regurgitation velocity)2     + RA pressure

The mean pulmonary artery pressure (mPAP) can be estimated from the following equation (Figure 7): mPAP=4Vearly peak pulmonary regurgitation velocity2+ RA pressure This equation has been shown to correlate well with invasive measurements in adults and children (35, 36). Another method to estimate mPAP is by using pulmonary acceleration time (AT) measured by pulsed-wave Doppler of the pulmonary artery in systole, where mPAP = 79 – (0.45 × AT) and in patients with AT < 120 ms, the formula for mPAP = 90 − (0.62 × AT) performed better (37). Recently, a newer method to evaluating mPAP is by adding the mean RA pressure to the velocity–time integral of the TR jet. This method has been validated by invasive measurements in adults where the mean difference between mPAP calculated using this method was closer to the right heart catheterization mPAP (38, 39). Some of the equations used to estimate mPAP do not add the mean RA pressure.

Pulmonary vascular resistance is calculated from cardiac catheterization as pressure gradient across the pulmonary bed divided by the pulmonary blood flow. PVR is important in the evaluation of PH and can be estimated using the following equation: PVR=VTR max∕VTIRVOT×10+0.16 The VTI(RVOT) denotes the velocity time integral of RVOT that can be obtained by spectral Doppler in the parasternal short axis view. In adults, this echocardiographic derived PVR has been validated with cardiac catheterization (40). In another adult study that included children, PVR can be estimated using a simple ratio of peak TR velocity to the VTI(RVOT) and value of >38 provided a specificity of 100% for a PVR of >8 Wood units (WU) (41). However, this relationship is not reliable in patients with very high PVR as determined by invasive hemodynamic measurements (42). In children with congenital heart disease, the ratio of isovolumic time (IVRT) to RV ejection time (ET) has been shown to correlated with PVR, with IVRT/ET <0.3 being 97% specific for a PVR < 3 WU and a IVRT/ET ratio > 0.4 highly predictive of PVR > 5WU (43). However, other studies did not find a correlation between the ratio of IVRT/ET and PVR. Recently, Panda et al. used TR velocity over VTI(RVOT) ratio (TRV/VTIRVOT) to correlate with invasive measurements of PVR in children with PH in congenital heart disease (44). The TRV/VTIRVOT ratio correlated well with PVR measured at catheterization. They found that for PVR of 6 WU, a TRV/VTIRVOT value of 0.14 provided a sensitivity of 96.67% and a specificity of 92.86% and for PVR of 8 WU a TRV/VTIRVOT value of 0.17 provided a sensitivity of 79.17% and a specificity of 95% (44). Although echocardiogram can estimate PVR, cardiac catheterization remains the gold standard in diagnosing PVR.

The myocardial performance index (MPI) is a non-invasive measurement of global ventricular function (systolic and diastolic) independent of geometric assumptions (63). It can be applied to the RV and the LV. It is defined as the ratio of isovolumic time divided by the ET. MPI=isovolumic contraction timeIVCT+IVRT∕ET The MPI is easily obtained from either the spectral Doppler or from tissue Doppler imaging (TDI) (Figure 10). RV MPI is difficult to obtain in one single heart beat or similar heart beat because it is difficult to image the tricuspid valve and pulmonary valve in the same spectral Doppler signal. This results in errors in the calculation of the RV MPI. In TDI, the RV MPI is more easily measured from a single heart beat by sampling at the tricuspid annulus. RV MPI using the spectral Doppler has been studied in pediatric patients with PH. It is increased in PH patients compared to controls and RV MPI correlated well with both mPAP at cardiac catheterization and response to therapy. (64) Another study in infants with PH from congenital diaphragmatic hernia has shown that RV MPI is elevated compared to controls, but did not correlate well with SPAP (65). RV MPI may be a useful tool to follow PH patients serially but it may be unreliable if there is significant TR with an elevated RA pressure because the IVRT will shorten and result in an inappropriately lower value of MPI. RV MPI will not work if patients have irregular heart rates. There are currently no studies in children using TDI method of RV MPI to evaluate pediatric PH and further studies are needed in this area.