1Division of Pediatric Cardiology, University Children's Hospital, Steinwiesstr. 75, CH-8032 Zurich, Switzerland
2Division of Congenital Cardiovascular Surgery, University Children's Hospital, Zurich, Switzerland
3Division of Diagnostic Imaging, University Children's Hospital, Zurich, Switzerland
Received 17 January 2005; revised 29 August 2005; accepted 15 September 2005; online publish-ahead-of-print 7 October 2005.
* Corresponding author. Tel: +41 1 266 7382; fax: +41 1 266 7981. E-mail address: emanuela.valsangiacomo{at}kispi.unizh.ch
See page 2614 for the editorial comment on this article (doi:10.1093/eurheartj/ehi613)
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Abstract |
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Methods and results Twenty children with severe pulmonary regurgitation and RV dilatation and mean age 13.9±3 years underwent CMR evaluation 5.6±1.8 months before and 5.9±0.6 months after PVR. PVR was performed when the RV end-diastolic volume exceeded 150 mL/m2, as measured by CMR. The time interval between primary repair and PVR was 12±3 years. Post-operative CMR demonstrated a significant reduction of the RV end-diastolic volume from 189.8±33.4 to 108.7±25.8 mL/m2 (P<0.0001), of the RV end-systolic volume from 102.4±27.3 to 58.2±16.3 mL/m2 (P<0.0001), and of the RV mass from 48.7±12.3 to 35.8±7.7 g/m2 (P<0.0001). The RV ejection fraction did not change significantly.
Conclusion Prompt RV remodelling, with reduction of RV volume and mass, is observed after performing PVR if the RV end-diastolic volume exceeds 150 mL/m2. Early PVR may prevent the detrimental complications of severe pulmonary regurgitation.
Key Words: Tetralogy of Fallot Right ventricle Remodelling Magnetic resonance imaging
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Introduction |
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With this prospective study, we sought to assess the RV remodelling after early PVR using cardiovascular magnetic resonance (CMR) in children with chronic pulmonary regurgitation after repair of tetralogy of Fallot.
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Methods |
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PVR was indicated in the presence of severe pulmonary valve regurgitation and RV dilatation both at CMR and echocardiography and of a RV end-diastolic volume exceeding 150 mL/m2 and/or more than double the end-diastolic volume of the left ventricle (LV) as measured by CMR, independent of the clinical status of the patient. The value of RV end-diastolic volume >150 mL/m2 was defined on the basis of CMR data reported for adults with chronic pulmonary valve regurgitation and adapted for the paediatric age group and corresponded to 150% of the normal upper limit for RV end-diastolic volume in children, which is 100 mL/m2.8,9 Remodelling of the RV was defined by significant changes in RV volume, mass, and function.
Permission to proceed with this study was granted by our institutional Ethics Review Board. Informed consent was obtained from all patients.
Surgical technique
Cardiopulmonary bypass was established using external iliac vessel cannulation prior to repeat sternotomy, with limb cooling to 16°C. Minimum dissection was performed to separate the heart from the sternum and to free the right side of the heart. When the procedure was limited to the reconstruction of the RV outflow tract, including enlargement of the pulmonary arteries, it was performed on a beating, continuously perfused heart. If a concomitant procedure was necessary, a more complete dissection of the heart was performed: the aorta was cross-clamped and cardioplegia given to obtain cardiac arrest. The RV outflow tract was opened longitudinally and the bifurcation was completely transected. Patch enlargement of the intrapericardial part of the pulmonary artery was performed as needed. A valved conduit was sutured on the pulmonary bifurcation with a running prolene suture. Proximally, the graft was inserted on the conal septum and then the infundibulum was modelled to fit the inlay part of the conduit. A reduction plasty of the dilated RV infundibulum was performed if necessary and consisted in complete resection of the old infundibular patch. At times, a purse-string stitch was placed inside the RV outflow tract proximal to the graft and tightened to further reduce the size discrepancy. Post-operatively, prophylactic acetyl-salicylic-acid in a dose of 35 mg/kg/day was given to all patients during 6 months to prevent formation of thrombotic clots on the conduit valve.10
Cardiac magnetic resonance
Image acquisition
CMR studies were performed with a 1.5 T System (Signa MR/I Echo Speed; General Electric Medical Systems, Milwaukee, WI, USA), using a phased-array cardiac coil. The CMR protocol included cine steady-state free precession sequences in the axial plane for evaluation of the anatomy and in short axis planes to assess the ventricular volumes and mass. Velocity-encoded phase contrast sequences were performed for calculation of blood flow velocity and volume in the main pulmonary artery. Contrast-enhanced CMR angiography was performed for assessment of the anatomy of the pulmonary arteries. The images were acquired during breath holding in all patients.
Ventricular volumes were measured from a multi-section image set of 1012 contiguous slices parallel to the plane of the atrioventricular valves (ventricular short axis), covering the full length of both ventricles.11 The acquisition parameters of the steady-state free precession images were TE minimum, flip angle 45°, bandwidth 125 kHz, matrix 224x224, number of excitations 1, field of view 3045 cm, slice thickness 68 mm with 12 mm gap depending on the body size, and retrospective gating with 20 images reconstructed per cardiac cycle.
Velocity mapping was performed in a double oblique plane perpendicular to the main pulmonary artery. The images were acquired halfway between the pulmonary valve and the pulmonary bifurcation. Acquisition parameters were TE minimum, flip angle 15°, matrix 256x128, bandwidth 31.25 kHz, views per segment 46 depending on the heart rate, number of excitations 1, slice thickness 4 mm, field of view adequate for patient's size, and retrospective electrocardiographic gating. Twenty phases per cardiac cycle were reconstructed by a standard interpolation technique.12 The upper velocity range was set 25% higher than the expected peak velocity, on the basis of Doppler echocardiography, to optimize measurement accuracy while avoiding aliasing.
Image analysis
All images were analysed off-line on a commercially available workstation (SUN Microsystems Inc., Mountain View, CA, USA).
The volumetric data of the ventricles and RV mass were calculated with the MASS software package (Magnetic Resonance Analytical Software System Version 4.0, MEDIS, Medical Imaging Systems, Leiden, The Netherlands). The endocardial contours were traced manually as previously described.11 For RV mass calculation, the epicardial and endocardial contours were traced in the end-systolic phase; the moderator band and the trabeculations were included into the mass. We chose the end-systolic phase for more reliable delineation of the RV free wall, which in children in the end-diastolic phase would be very thin to be traced consistently. The myocardial volume mass was multiplied by the specific density of the myocardium (1.05 g/m3). The RV ejection fraction was calculated as RV end-diastolic volumeRV end-systolic volume/RV end-diastolic volumex100. A RV ejection fraction >50% was considered as normal.13 Flow data were analysed with the FLOW V2.0 software package (MEDIS, Medical Imaging Systems, by tracing the contours of the main pulmonary artery in each time frame.14
Echocardiography
Pre- and post-operative echocardiographic assessment was performed with a Sonos 5500 ultrasound imaging system (Philips Medical Systems, Andover, MN, USA) in the generally accepted standard views. The RV dimensions were evaluated by measuring the RV diameter on the two-dimensional images in the four-chamber view. The degree of pulmonary regurgitation was evaluated semi-quantitatively using colour Doppler and pulsed-wave Doppler mapping. Pulmonary regurgitation was classified as severe (retrograde diastolic flow into the branch pulmonary arteries), moderate (retrograde diastolic flow in the main pulmonary artery), and mild (regurgitant jet detectable in the RV outflow tract but no retrograde diastolic flow in pulmonary trunk).15 The contractility of the right ventricle was described qualitatively by the cardiologist performing echocardiography.
Statistics
Descriptive data are presented as mean±SD or median (range) as appropriate. All ventricular volumetric data and mass were indexed for body surface area. The sample size of the study was determined after preliminary analysis of the results of 20 patients, which showed already significant results; power calculation demonstrated a power of 0.9 for detecting a volume difference of 30 mL/m2, which we considered medical relevant. The two-tailed paired Student's t-test was used to compare the intra-individual pre-operative and post-operative data, without adjustment for multiplicity, as this was judged not appropriate.16 A P-value less than 0.05 was considered statistically significant.
The results of 10 randomly selected patients, five pre-operatively and five post-operatively, were used for calculation of the intra- and inter-observer variability by determining the mean difference (SD) and the limits of agreement between measurements.17 The intra-observer variability was assessed by comparison of ventricular volume measurements by one observer (E.R.V.) on two separate occasions, at least 3 months apart. The inter-observer variability was assessed by comparison of the results of two independent observers (E.R.V. and C.J.K.).
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Results |
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Haemodynamic results
Cardiovascular magnetic resonance
The haemodynamic changes after PVR are summarized in Table 2. Pre-operatively, all patients presented moderate-to-severe pulmonary regurgitation with corresponding severe RV dilatation. Six months after PVR, a significant reduction of the RV dimensions (P<0.0001) was observed in all patients and a significant reduction of RV mass (P<0.0001) was measured in 19 of 20 patients (Figure 1). In one patient, the images obtained were of insufficient quality for determining RV mass. The RV ejection fraction remained unchanged. Normalization of the RV end-diastolic volume to a value <105 mL/m2 occurred in 8 of 12 patients (66%), who presented with a pre-operative end-diastolic volume <200 mL/m2; in two cases, a RV reduction plasty was performed. In contrast, in eight patients with a pre-operative end-diastolic volume 200 mL/m2, normalization of RV dimensions occurred in only one, who underwent RV reduction plasty.
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Echocardiography
Pre-operatively, severe pulmonary regurgitation and significant RV dilatation, with RV diameters larger than LV diameters (mean 40.9±6.3 vs. 38.3±4.6 mm), were observed in all patients. Similar to the CMR results, a significant reduction of the RV dimensions was measured post-operatively; the mean RV end-diastolic diameter decreased from 40.9±6.3 to 33.9±6.7 mm (P<0.0001) after PVR. Pre-operatively, the RV function was judged as normal in 17 patients and as diminished in three. After PVR, normal RV function was described in all but one patient. Moderate tricuspid regurgitation was found in five of 20 patients pre-operatively and in one of 20 post-operatively.
Arrhythmias
Ventricular arrhythmias were recorded in 13 patients pre-operatively and improved post-operatively in seven of them. Particularly, two of the three patients with arrhythmias Lown Class 4a totally normalized (Lown Class 0) and one improved into Lown Class I.
In the 18 children with right bundle branch block, post-operative QRS duration did not change significantly, as measured by standard ECG (150±18 ms pre-operatively vs. 148±17 ms post-operatively).
Valve function
Echocardiography demonstrated a good function of the valved graft in all patients. Colour Doppler showed no pulmonary regurgitation in four, trivial regurgitation in 14, and mild regurgitation in two patients. Flow acceleration within the RV outflow tract, with a mean velocity of 270±10 cm/s, was measured using spectral Doppler in 13 patients.
CMR detected regurgitant flow in the pulmonary conduit in seven patients, with a mean regurgitation fraction of 9.2±7.3%.
Intra- and inter-observer variability
Intra- and inter-observer variability is summarized in Table 3. Normalized to the mean value of the volume data, the mean difference corresponded to a variability range from <1 to 5% for intra-observer measurements and from <1 to 13% for inter-observer measurements. Inter-observer variability was slightly higher for measurements of the RV volumes than for measurements of the LV volumes.
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Discussion |
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The haemodynamic effects of PVR have been reported in adults and in children, by assessing functional class, exercise tolerance, and volumetric changes at echocardiography and nuclear angiocardiography.4,13,18,19 Two authors used CMR for assessing ventricular volumetric and functional changes after valve replacement in adults.8,20 This study reports the use of CMR to demonstrate remodelling of the RV after PVR in children, by describing the changes occurring in RV volume, mass, and function.
Timing PVR and ventricular remodelling
Clinical symptoms, including exercise intolerance, onset of ventricular arrhythmias, and echocardiographic findings such as progressive RV dilatation and onset of tricuspid regurgitation, have been used so far as indicators for re-intervention.21 However, Therrien et al.13 suggested that post-operative RV resizing after PVR may not occur in all patients, if PVR was performed on the basis of clinical symptoms. Other authors demonstrated that in spite of good clinical conditions, mild or moderate pulmonary regurgitation has considerable negative effects on global RV performance and cardiac reserve and that RV contractile function is reduced in relation to the degree of pulmonary regurgitation.22,23 The clinical experience teaches us that children may develop clinical symptoms lately, when the ventricular function is already seriously impaired. Moreover, CMR is the first imaging modality providing exact quantification of regurgitant volume and RV ventricular volume and mass. This information may allow us to look for new quantitative indicators for PVR and facilitate the management of these patients.3
Our data demonstrate that remodelling of the right ventricle can be achieved within 6 months post-operatively, if PVR is performed in a timely fashion (Figure 2). Using a RV end-diastolic volume >150 mL/m2 as indication for PVR, we observed not only a significant reduction of the RV volume but also a decrease in RV mass, which may represent a better indicator for remodelling. RV mass is independent of loading conditions and of surgical interventions such as RV reduction plasty, because in this technique, only fibrous tissue or patch material, but no cardiac muscle, is resected in the RV outflow tract. The RV ejection fraction did not show any changes after PVR. However, the pre-operative data may represent an overestimation of the effective ejection fraction, because a regurgitation of the pulmonary or tricuspid valve leads to an increase of the end-diastolic volume and therefore to a higher ejection fraction. Thus, if the effects of regurgitation on the measurement of ejection fraction are taken into consideration, the real RV output may have improved after valve replacement.8 In addition, the post-operative increase in LV end-diastolic volume and the trend towards improvement of the LV function may reflect an enhanced RV output, increased net-flow in the main pulmonary artery, and a more favourable right-to-left ventricular interaction.24
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Reproducibility
The intra- and inter-observer variability indicates a good reproducibility of the CMR volume measurements. Our results are within the variability range of 515% previously reported in the literature, but single cases show limits of agreement of as high as 24 mL/m2.7,27 This variability can be accepted in this study group as, in contrast to the accepted validation studies, we did not evaluate normal-shaped ventricles, and in children, breath-holding may not be always optimally performed, thus the image quality may not be always maximal. As reported in other studies, a higher variability was found for RV volume measurements than for LV volume measurements, owing to the complex geometry of the right ventricle and the difficulties in defining the correct plane of the tricuspid valve in the most basal slice and in delineating the RV endocardial border and owing to the thin RV free wall, the increased trabeculations, and other structures such as the moderator band.27,28 Nevertheless, CMR still offers a superior reproducibility when compared with echocardiography, because CMR is not dependent on suitable acoustic window for echo or geometric assumption.28
Limitations
The most important limitation of this study is the lack of a control group. We could demonstrate that prompt remodelling of the RV is observed in children, if PVR is performed in patients with a RV end-diastolic volume >150 mL/m2. Even though we used a higher cut-off in children than in the one proposed for the adult population, our data indicate that we are not operating too late.8 However, we could not provide evidence for or against a hypothesis that delayed cardiac surgery would not result in similar remodelling. Nevertheless, the fact that none of the patients with a pre-operative RV end-diastolic volume >200 mL/m2 showed normalization of the RV volume within 6 months may be an helpful indicator for defining an upper limit for re-intervention. Further prospective CMR studies comparing different timing for valve replacement and providing longer follow-up may help to understand the influence of pulmonary regurgitation on RV haemodynamics over time and to define clearer limits for intervention. Moreover, long-term results of new valved conduits used for reconstruction of the RV outflow tract would help to unburden the concerns existing about the need for repeated pulmonary valve surgery.
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Conclusions |
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Acknowledgement |
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Conflict of interest: none declared.
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References |
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