Patients studied

We included in our study 50 patients following corrective surgery for tetralogy of Fallot, and 30 age-matched normal subjects. The patients were asymptomatic, and selected on the basis that they had no patent oval foramen or residual ventricular septal defect, were in sinus rhythm, and had an adequate transthoracic window for echocardiographic examination. Their characteristics are shown in Table 1. The mean age at corrective repair was 6.4 years, with a range from 4 months to 51 years, and their mean age at examination was 17.1 years, with a range from 6 to 56 years. The period of follow-up was 8.7 years, with a range from 1 to 28 years. During surgical repair, the right ventricular outflow tract had been reconstructed with a valved homograft or heterograft in 26 patients (52%), and by insertion of a patch in 24 patients (48%). Data from the patients with tetralogy of Fallot was compared with findings from 30 age-matched healthy subjects, who were examined for evaluation of an innocent murmur. Their mean age was 14 years, with a range from 6 to 62 years. Among the 50 patients, 20 underwent a magnetic resonance tomographic examination in order to quantify the right ventricular systolic function. Informed written consent was obtained from the patients or their parents. The patients included in the studies involving magnetic resonance tomography were those who agreed to undergo the examination on the same day as the echocardiographic study. The main characteristics of the 20 patients who received magnetic resonance tomographic examination, and of the other 30 patients, are comparable (Table 2).

Table 1. Characteristics of the 50 patients studied after corrective surgery for tetralogy of Fallot.

Table 2. Comparison of characteristics between the patients with tetralogy of Fallot having or not having a magnetic resonance tomographic examination.

Cross-sectional echocardiography

All the normal subjects and the patients were examined using a 2.5/3.5 transducer interfaced with a Vingmed system V (GE Vingmed, Horten, Norway). Initially, routine diagnostic imaging was performed, including colour flow mapping, along with pulsed and continuous wave Doppler. The standard apical four-chamber view was recorded. The right atrial area was measured along its endocardium in three different phases of the cardiac cycle, as previously described,¹² when the right atrium reaches its maximal area, at the onset of the electrocardiographic P wave, or at its minimal area. The active right atrial area of emptying was calculated as the area at the onset of atrial contraction minus the minimal area, while the right atrial passive area of emptying was calculated as the maximal area minus the area at the onset of atrial contraction. We then computed the ratio between the active and passive areas of atrial emptying. The fractional area of right atrial active emptying was calculated as the area at the onset of atrial contraction minus the minimal area divided by the area at the onset of atrial contraction, and expressed as a percentage.

Tissue Doppler imaging studies

After the normal echocardiographic examination, colour Doppler myocardial imaging was performed with the same apical four-chamber view in all the subjects. Sector size and depth were chosen to achieve a frame rate of 130 ± 20/s. Gain settings, filters, and pulse repetition frequency were adjusted to optimise colour saturation. We recorded 3 consecutive cardiac cycles during normal quiet respiration. The myocardial colour Doppler data were stored in digital format, and transferred to a computer workstation for the off-line analysis with dedicated software (TVI; GE Vingmed, Echopack). In all the normal subjects, and the patients, curves of right atrial and right ventricular strain rate were assessed in the middle of the corresponding lateral walls (Fig. 1). A pixel of 1 × 1 was applied, and strain rate was estimated by measuring the spatial velocity gradient over a computation distance of around 2–3 mm in the direction of measurement.

Figure 1. The characteristic peaks in the curve of atrial strain rate. A: late diastolic peak strain rate; E: early diastolic peak strain rate; RA: right atrium; RV: right ventricle; S: systolic peak strain rate.

The curve of atrial strain rate was also characterised by the three main waves, systolic, early diastolic and late diastolic, which coincided with the ventricular systolic, early diastolic and late diastolic periods, respectively. The direction of the curve for atrial strain rate was the opposite to that of the ventricular curve (Fig. 1).

Magnetic resonance tomographic study

In 20 of the patients, we performed magnetic resonance tomographic studies on the same day as the tissue Doppler examination for the evaluation of ventricular function. For magnetic resonance imaging, we used a 1.5 T Philips instrument (Philips, Eindhoven, Netherlands). Using previously published methods,¹³ the ventricular volumes were measured by a third independent observer, who was blinded to the results obtained after analysis of the data from tissue Doppler. The ventricular ejection fraction was calculated as the end-diastolic minus the end-systolic volume divided by the end-diastolic volume, and was again expressed as a percentage.

Statistical analysis

The statistical software used was SPSS 10.0. Data were expressed as mean plus or minus standard deviation. The nonparametric Mann-Whitney test was used to assess the differences between two unpaired groups. For analysis of correlations the nonparametric Spearman rank correlation was performed. We considered a p value of <0.05 to be statistically significant.

Standard echocardiographic results

The echocardiographic results are shown in Table 1. Following the corrective surgery, none of the examined patients had a residual ventricular or atrial septal defect. Of the patients, 14 (28%) patients had a gradient greater than 40 mmHg across the right ventricular outflow tract, and 44 (88%) had mild-to-moderate pulmonary regurgitation. Two of the patients undergoing magnetic resonance tomography, and three from the other thirty, showed a Doppler pattern of restrictive right ventricular physiology, which was diagnosed when antegrade pulmonary flow in late diastole was detected throughout the respiratory circle.

Right atrial performance measured by cross-sectional echocardiography (Table 3).

Table 3. Comparing the right atrial and right ventricular performance measured by cross-sectional echocardiography and tissue Doppler imaging between the 30 normal subjects and the 50 patients with tetralogy of Fallot.

There were no significant differences in age or heart rate between the normal subjects and those who had undergone corrective surgery. In the patients, the minimal right atrial area (p = 0.001), the area at atrial contraction (p = 0.001), and the maximal area (p = 0.013) were significantly larger than in normal subjects. The fractional area of active right atrial emptying was significantly lower (p = 0.005), while the ratio between active and passive emptying was significantly higher (p = 0.001) in the patients when compared to their normal controls (Figs 2 and 3).

Figure 2. Comparison of the fractional area of right atrial active emptying between patients after surgical correction of tetralogy of Fallot and normal controls.

Figure 3. Comparison of the active and passive emptying areas between patients after surgical correction of tetralogy of Fallot and normal controls.

Right atrial and right ventricular performance measured by tissue Doppler derived strain rate

Using tissue Doppler imaging, we showed that the systolic (p = 0.001), early diastolic (p = 0.038) and late diastolic (p = 0.002) peaks for the strain rate of the lateral wall of the right atrium (Fig. 4), as well as the comparable peaks for the strain rate of the right ventricular free wall, with respective p values being 0.001 for systolic, 0.013 for early diastolic, and 0.001 for late diastolic peaks, were all significantly reduced in the patients with tetralogy of Fallot when compared to their normal controls (Table 3). In patients with a right ventricular ejection fraction of less than 50%, the peak late diastolic strain rate for the right atrium was significantly higher (p = 0.021) than in those with a right ventricular ejection fraction of more than 50% (Fig. 5, Table 4).

Figure 4. Comparison of the right atrial lateral wall peak strain rates measured by tissue Doppler between patients after surgical correction of tetralogy of Fallot and normal controls.

Figure 5. Comparison of right atrial lateral wall late diastolic peak strain rate in patients after surgical correction of tetralogy of Fallot when also comparing those with right ventricular ejection fractions of greater or less than 50%.

Table 4. Comparison of the tetralogy of Fallot patients with right ventricular ejection fraction of >50% with those with an ejection fraction of <50%.

Right atrial performance after surgical correction of tetralogy of Fallot as measured by cross-sectional echocardiography

Right ventricular dysfunction secondary to pulmonary regurgitation or residual obstruction to the right ventricular outflow tract is frequently observed in the long-term follow-up of patients after corrective surgery for tetralogy of Fallot.¹⁴ Recent studies in adults have demonstrated that left atrial function is a crucial determinant of ventricular filling in patients with impaired left ventricular relaxation,^{6, 7} and that the left atrium plays an important role during the course of evolving cardiac failure.^{8, 9} Information about right atrial function among patients with right ventricular dysfunction, however, such as after surgical correction of tetralogy of Fallot, is sparse. In this study, we showed that the right atrial pump function, expressed as the fractional area of active emptying, was reduced in such patients. This can be explained by the preoperative hypoxic state combined with the surgical damage to the right atrial myocardium.¹⁵

Abnormal right ventricular relaxation has also been reported after correction of tetralogy of Fallot. Indeed, in our study we found that the ratio between active and passive emptying was significantly higher in the surgically corrected patients than in the normal subjects. This may indicate that, compared to the right atrium in normal subjects, the atrium in patients following corrective surgery for tetralogy of Fallot has to contribute more in the process of ventricular filling, although its pump function is already reduced.

Regional right atrial performance as quantified by tissue Doppler strain rate

Previous studies focusing on the right ventricle showed reduced regional, as well as global, right ventricular function following corrective surgery for tetralogy of Fallot.^{16, 17} Our results show that the regional deformation of the right atrial wall as assessed by tissue Doppler strain rate is also reduced in these patients. The reduced systolic and early diastolic peaks revealed by this technology may reflect the decreased right ventricular function and increased atrial stiffness, since the right atrium has no active motion during the ventricular systolic and early diastolic periods. In contrast, the reduced late diastolic peak shown by the atrial strain rate may indicate reduced atrial pump function. This finding is consistent with the result obtained from cross-sectional echocardiography.

Relation between right atrial pump function and right ventricular systolic function in patients following corrective surgery for tetralogy of Fallot

Our data show that the patients with reduced right ventricular systolic function have a relatively enhanced longitudinal atrial myocardial shortening, indicating increased atrial pump function. This may be an adaptive compensatory mechanism of the right atrium to prevent further deterioration of the right ventricular haemodynamics. A similar compensatory mechanism of the left atrium has been reported in patients with left ventricular dysfunction.^{6, 7, 18} We did not find a significant difference in the right atrial active emptying fraction, which serves as a global parameter, when comparing the right ventricular ejection fraction between the normal and operated groups. Changes in the regional myocardial function may occur before any global alteration is apparent, and could explain our findings.

Right ventricular restrictive physiology as indicated by Doppler detectable antegrade forward flow in the pulmonary artery in late diastole is an important phenomenon after repair of tetralogy of Fallot.^{4, 19} Only five of our patients had restrictive right ventricular physiology, which makes impossible statistical comparison of atrial function between the restrictive and non-restrictive groups. Since atrial performance is inversely influenced by its after-load, nonetheless, we assume that the right atrial pump function would be reduced when facing a restrictive right ventricle. In this situation the compensating mechanism between right atrium and right ventricle could be hampered. Further data addressing this point are needed to confirm this assumption.