Introduction
Tetralogy of Fallot, first described in 1888, Reference Apitz, Webb and Redington1 is a common cyanotic congenital heart defect, occurring in 3–5 per 10,000 live births. Reference Mai, Isenburg and Canfield2 Despite surgical advances, chronic pulmonary regurgitation after transannular patch repair leads to right ventricular dilatation and failure, termed “PR-induced cardiomyopathy”. Reference Geva3,Reference Valente, Gauvreau and Assenza4 Valve-sparing techniques fail in 30–40% of cases due to residual obstruction, Reference Hirsch, Mosca and Bove5 while monocusp valves often require replacement within 5 years. Reference Talwar, Ahmed and Saxena6,Reference Binsalamah7 Transcatheter pulmonary valve implantation is limited by cost and anatomical constraints in primary repair. Reference Hoerstrup8 Autologous tissue options like pericardium show inconsistent results. Reference Lee, Park and Lee9,Reference Sugiura10 The right atrium, with its thin, flexible wall and shared embryological origin with the pulmonary valve, offers a promising alternative. Reference Onan, Ergün, Özturk, Çelik, Ayyıldız and Onan11 We developed a technique to reconstruct the pulmonary valve using right atrial tissue during tetralogy of Fallot repair and evaluated its early efficacy compared with standard transannular patch repair over 1 year.
Materials and method
Between January 2014 and December 2024, 412 consecutive tetralogy of Fallot patients underwent surgical repair at five centres: Çukurova University (Adana, Turkey), University of Pristina (Pristina, Kosovo), Medipol University (Istanbul, Turkey), Medicana International Istanbul Hospital (Istanbul, Turkey), and Medicana Ataşehir Hospital (Istanbul, Turkey). This study focuses on 1-year follow-up data for cohort homogeneity. Patients were divided into Atrial Valve Group (n = 205, pulmonary valve reconstruction using the right atrial appendage) and No-Valve Group (n = 207, standard transannular patch repair). The study was approved by our institutional ethics board. Demographic characteristics are presented in Table 1.
Table 1. Baseline characteristics and perioperative data
Study units and data collection
This multicentre study involved five institutions: Çukurova University, University of Pristina Medipol University, Medicana International Istanbul Hospital, and Medicana Ataşehir Hospital. Surgical units collected perioperative data (surgical details, cardiopulmonary bypass (CPB)/aortic cross clamp (ACC) times, pulmonary annulus Z-scores). Paediatric cardiology units gathered echocardiographic data (annulus size, right ventricular outflow tract gradients, tricuspid annular plane systolic excursion, fractional area change, PR severity). Medicana International Istanbul Hospital provided anaesthesiology data (ventilation times, ICU stays, and complications). Data collection was standardised across sites.
Surgical technique
The pulmonary valve reconstruction technique using the right atrial appendage was developed by our team starting in 2014, based on histological and embryological similarities between right atrial appendage tissue and the pulmonary valve, and refined over time. After median sternotomy, systemic heparinisation, and aorto-bicaval cannulation, ventricular septal defect (VSD) closure and right ventricular outflow tract muscle resection were performed under aortic cross-clamp. In Atrial Valve Group, reconstruction used single-dose cardioplegic arrest (HTK–Custodiol®, 20 mL/kg, Koehler Chemie, Alsbach-Hähnlein, Germany). The right atrial appendage was assessed for a minimum length of 1 cm and adequate elasticity, with unsuitable appendages ( <5%) excluded. Excision avoided the sinoatrial node and right coronary artery. The right atrial appendage was suspended using 7–0 Prolene sutures, trabeculae removed, and a bileaflet valve formed via an 11-mm scalpel cut. The valve base was sutured to the pulmonary annulus with 7–0 polypropylene sutures, augmented with native valve tissue or a pericardial patch in 2.9% of cases (6/205) if needed. A bovine pericardial patch was integrated for right ventricular outflow tract reconstruction, completed off-clamp. Valve height was set at 1–1.5 times the annulus diameter. Key steps are shown in Photos 1–21.
In No-Valve Group, standard transannular patch repair preserved the native pulmonary valve, with the patch completed off-clamp using a bovine pericardial patch. Transannular repair was indicated by a Z-score <-2, assessed via transesophageal echocardiography and Hegar dilators; all patients required it due to hypoplastic anatomy. No monocusp valves were used in No-Valve Group. The decision to perform transannular repair in both groups was based on a standardised intraoperative assessment of pulmonary annulus size, guided by Z-scores derived from preoperative and intraoperative transesophageal echocardiography. The pulmonary annulus diameter was measured relative to body surface area-adjusted normative data, with a Z-score <-2 indicating a hypoplastic annulus necessitating transannular repair to prevent residual right ventricular outflow tract obstruction. Intraoperative calibration using Hegar dilators further confirmed annulus adequacy, ensuring alignment with echocardiographic findings. Patients with a Z-score ≥-2, indicative of an adequate annulus, were considered for valve-sparing techniques where feasible; however, in this cohort, all patients required transannular repair due to predominant hypoplastic anatomy. For No-Valve Group, intraoperative evaluation of the native pulmonary valve was conducted using transesophageal echocardiography to assess leaflet morphology, mobility, and degree of obstruction. In all cases, the native pulmonary valve was preserved in situ, as severe valvular dysplasia or significant obstruction warranting excision was absent. Transesophageal echocardiography confirmed preservation of the native pulmonary valve due to the absence of severe valvular dysplasia or obstruction, prioritising right ventricular outflow tract augmentation while mitigating postoperative pulmonary regurgitation. This approach was adopted to mitigate postoperative pulmonary regurgitation while prioritising right ventricular outflow tract augmentation through transannular patching.
Echocardiographic assessment
Postoperative echocardiographic assessments were conducted at 1 week, 1 month, 3 months, 6 months, and 12 months by two independent cardiologists blinded to the surgical group to minimise observer bias. Interobserver agreement was evaluated using the intraclass correlation coefficient, with a range of 0.84–0.95, confirming high reproducibility. Measured parameters included:
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• Pulmonary regurgitation: Assessed via colour Doppler and classified as none (no backflow), mild ( <25% of pulmonary annulus), moderate (25–50%), or severe ( >50% with retrograde flow in the right ventricular outflow tract).
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• Right ventricular outflow tract Gradient: Determined using continuous-wave Doppler, with values >30 mmHg indicating significant obstruction.
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• Right ventricular Function: Evaluated using tricuspid annular plane systolic excursion and right ventricular fractional area change; tricuspid annular plane systolic excursion <16 mm or fractional area change <35% denoted right ventricular dysfunction.
Right ventricular insufficiency was defined as the combination of moderate or severe pulmonary regurgitation with concurrent right ventricular dysfunction (tricuspid annular plane systolic excursion <16 mm or fractional area change <35%), measured using standardised transthoracic echocardiography. Right ventricular dysfunction alone refers to impaired right ventricular systolic function based on these thresholds, independent of pulmonary regurgitation severity. Tricuspid annular plane systolic excursion was quantified in the apical four-chamber view using M-mode echocardiography, measuring the longitudinal displacement of the tricuspid annulus during systole. Fractional area change was calculated as the percentage change in right ventricular area from end-diastole to end-systole in the same view, using two-dimensional imaging. Assessments adhered to American Society of Echocardiography guidelines, with measurements obtained in triplicate and averaged to enhance accuracy. This stringent definition, combining pulmonary regurgitation and right ventricular dysfunction, was chosen to capture early haemodynamic impacts post-repair, particularly in the context of transannular patching. Parameters were systematically recorded at multiple time points to enable a detailed longitudinal comparison of postoperative right ventricular performance between groups, as presented in Table 5. The intraclass correlation coefficient range reflects variability across measurements, with higher values for standardised measures like tricuspid annular plane systolic excursion and lower values for more subjective assessments like pulmonary regurgitation grading.
Outcome measures
The primary endpoint was right ventricular insufficiency, evaluated echocardiographically at predefined intervals. Secondary endpoints included mechanical ventilation duration, ICU stay, and complication rates. While long-term follow-up beyond 12 months is ongoing, this study focuses on 1-year data to ensure methodological consistency, as imaging archives and data standardisation were incomplete for some patients operated on between 2014 and 2017.
Statistical analysis
Data were analysed using SPSS v26.0 (IBM Corp., Armonk, NY). Normality was assessed with the Shapiro–Wilk test. Normally distributed variables used the Student’s t-test; non-normally distributed variables used the Mann–Whitney U test. Categorical variables used the χ 2 or Fisher’s exact test. Propensity score matching minimised selection bias. Significance was set at p < 0.05.
Results
Baseline Characteristics: Demographic and perioperative data are presented in Table 1. No significant differences were observed between groups in age, weight, sex, or preoperative oxygen saturation (SpO2) (all p > 0.05), confirming comparability. Atrial Valve Group had longer CPB (47.1 ± 8.4 vs. 40.5 ± 8.0 min, p = 0.02, Cohen’s d = 0.80) and aortic cross-clamp times (27.8 ± 5.2 vs. 23.3 ± 4.9 min, p = 0.03, Cohen’s d = 0.89), with normality verified using Shapiro–Wilk tests (p > 0.05). Pulmonary annulus size was assessed intraoperatively using transesophageal echocardiography and calibrated with Hegar dilators, with Z-scores calculated relative to body surface area-adjusted normative data. In Atrial Valve Group, 70.2% of patients (144/205) had a hypoplastic annulus (Z-score <-2), and 29.8% (61/205) had an adequate annulus (Z-score ≥-2). In Atrial Valve Group, patients with adequate annuli, valve-sparing techniques were not feasible due to severe valvular dysplasia or prior balloon valvuloplasty, necessitating transannular repair with right atrial appendage-based valve reconstruction. In No-Valve Group, 85.0% of patients (176/207) had a hypoplastic annulus, and 15.0% (31/207) had an adequate annulus (p = 0.001, using the χ 2 test, Cramer’s V = 0.18), reflecting the anatomical need for transannular repair to relieve significant right ventricular outflow tract obstruction, while adequate annuli were associated with valvular dysfunction justifying transannular patching. Detailed annulus size data are presented in Table 4. In No-Valve Group, intraoperative transesophageal echocardiography confirmed preservation of the native pulmonary valve in all patients (100%, 207/207), with no valve excision or monocusp valve implantation, prioritising right ventricular outflow tract augmentation while minimising pulmonary regurgitation.
Echocardiographic Outcomes: Echocardiographic findings are presented in Tables 2–6 and Figures 1 and 2. Table 2 compares preoperative parameters between Atrial Valve Group (pulmonary valve reconstruction) and No-Valve Group (standard transannular patch repair), including pulmonary annulus diameter, right ventricular outflow tract gradient, and baseline right ventricular function (tricuspid annular plane systolic excursion and fractional area change), showing comparable characteristics (p > 0.05 for all parameters). Table 3 details intraoperative valve morphology in Atrial Valve Group, with 85% of valves (174/205) exhibiting a symmetrical bileaflet structure, 90% (184/205) demonstrating adequate leaflet coaptation (coaptation length >4 mm), and 88% (180/205) showing normal dynamic motion (leaflet excursion >10 mm), indicating successful reconstruction. Table 4 presents early postoperative (1-week) outcomes, with Atrial Valve Group showing lower pulmonary regurgitation rates (10.2% vs. 20.3%, p = 0.005) and similar right ventricular outflow tract gradients (p = 0.32) compared to No-Valve Group, indicating early benefits of valve reconstruction. Table 5 provides longitudinal trends in right ventricular function across 1 week, 1 month, 3 months, 6 months, and 12 months, demonstrating consistently higher tricuspid annular plane systolic excursion and fractional area change values and lower pulmonary regurgitation rates in Atrial Valve Group, confirming the sustained advantage of pulmonary valve reconstruction. Table 6 compares key parameters at 12 months, including right ventricular insufficiency (moderate/severe pulmonary regurgitation with right ventricular dysfunction, tricuspid annular plane systolic excursion <16 mm or fractional area change <35%), pulmonary regurgitation severity, tricuspid annular plane systolic excursion, fractional area change, and right ventricular outflow tract gradient. Atrial Valve Group exhibited lower right ventricular insufficiency (9.3% vs. 19.8%, p = 0.004, OR = 2.39, 95% CI: 1.32**–**4.33) and pulmonary regurgitation rates (22% ± 7 vs. 37% ± 10, p < 0.01), with better right ventricular systolic function (higher tricuspid annular plane systolic excursion and fractional area change, p < 0.01), while right ventricular outflow tract gradients were similar (p = 0.15). Figure 1 illustrates temporal trends in right ventricular dysfunction over 12 months, showing a consistently lower incidence in Atrial Valve Group (e.g., 9.3% vs. 19.8% at 12 months, p = 0.004), reflecting the protective effect of pulmonary valve reconstruction. Figure 2 depicts right ventricular outflow tract gradient trends over 12 months, confirming no significant difference between groups (e.g., 10.9 ± 3.5 mmHg vs. 11.4 ± 3.8 mmHg at 12 months, p = 0.15), indicating no residual obstruction post-reconstruction. Interobserver agreement for echocardiographic measurements was excellent (Intraclass correlation coefficient: 0.84–0.95), confirming the reliability of the blinded assessments.
Figure 1. RV dysfunction rate graphic.
Figure 2. RVOT gradient trends.
Table 2. RV_Dysfunction rates Over 12 months
Table 3. Echocardiographic valve morphology in group
Table 4. Pulmonary annulus size distribution
Table 5. Postoperative echocardiographic parameters in Atrial Valve group and No-Valve group (TAPSE = tricuspid annular plane systolic excursion; FAC = fractional area change; PR = pulmonary regurgitation; RVOT = right ventricular outflow tract. Data are presented as mean ± standard deviation or percentage (number/total). P-values were calculated using student’s t-test for continuous variables and χ2 test for categorical variables)
Table 6. Postoperative echocardiographic comparison at 12 Months between groups
Postoperative recovery and complications
Recovery data are presented in Table 7. Atrial Valve Group had significantly shorter ventilation times (6.1 vs. 18.0 hours, p < 0.001) and ICU stays (3.0 vs. 5.7 days, p < 0.001) compared to No-Valve Group. Atrial Valve Group also showed a shorter hospital length of stay (7.2 ± 2.1 vs. 8.1 ± 2.5 days, p = 0.03, Cohen’s d = 0.38) and lower 30-day readmission rates (4.5% [9/205] vs. 6.2% [13/207], p = 0.41, OR = 1.39, 95% CI: 0.61–3.17). No mortality occurred in Atrial Valve Group within 30 days post-surgery, while No-Valve Group had a 30-day mortality rate of 1.0% (2/207). At 1-year follow-up, overall mortality rates were 0.5% (1/205) in Atrial Valve Group (due to sudden cardiac arrest) and 1.4% (3/207) in No-Valve Group (causes: sudden cardiac arrest, meningitis, and arrest following convulsion; p = 0.62, using the Fisher’s exact test). Complications, including valve-related reinterventions, thrombus formation, endocarditis, arrhythmias, wound infections, and re-exploration, were comparable between groups, with no valve-related issues observed during the 1-year follow-up. Long-term follow-up beyond 12 months is ongoing, with a subset of patients (n = 78; Atrial Valve Group: n = 41, No-Valve Group: n = 37) reaching up to 5 years currently under analysis for a future publication, while a smaller subset surpassing 5 years is being reviewed for late valve function, growth compatibility, and structural degeneration.
Table 7. Postoperative recovery and complications
Discussion
Our results demonstrate that pulmonary valve reconstruction using autologous right atrial tissue significantly reduces right ventricular dysfunction over a 1-year follow-up while accelerating postoperative recovery (Figure 2, Table 3). The odds ratio indicates that patients with standard repair are 2.39 times more likely to develop right ventricular insufficiency, with a moderate-to-large effect size (Cohen’s d for pulmonary regurgitation jet width: 1.71–2.10). These results challenge the conventional paradigm that accepts pulmonary regurgitation as an inevitable trade-off for relieving right ventricular outflow tract obstruction. Reference Tweddell12 The right atrial wall, with its unique elastin and type III collagen-rich matrix, might explain why it works better than synthetic alternatives. Reference Deutsch13 Unlike polytetrafluoroethylene, which induces foreign body reactions and fibrosis, Reference Kumar14 autologous atrial tissue demonstrates adaptive remodelling. Reference Miyazaki15 This biological integration likely explains the lower pulmonary regurgitation rates observed in Atrial Valve Group at 12 months. The use of the term “RV insufficiency” in this study refers specifically to the combination of moderate or severe pulmonary regurgitation with right ventricular dysfunction, defined as tricuspid annular plane systolic excursion <16 mm or fractional area change <35%, to capture the combined haemodynamic burden post-repair. The reported right ventricular insufficiency rates may appear elevated due to the stringent echocardiographic criteria applied, which are more sensitive than those used in some prior studies. In tetralogy of Fallot repair, transannular patching often results in variable degrees of pulmonary regurgitation, as noted in the literature, Reference Geva3,Reference Valente, Gauvreau and Assenza4 but significant right ventricular dysfunction typically manifests over years rather than within the first year. The higher incidence in No-Valve Group aligns with the greater prevalence of moderate to severe pulmonary regurgitation, reflecting the absence of valve reconstruction. In contrast, Atrial Valve Group’s lower right ventricular insufficiency rate underscores the protective effect of pulmonary valve reconstruction in mitigating pulmonary regurgitation and preserving right ventricular function early post-repair. The stringent criteria used in our study, while potentially inflating early right ventricular dysfunction rates, provide a robust framework for detecting subtle changes in right ventricular performance, highlighting the advantage of valve reconstruction in Atrial Valve Group. The detailed postoperative echocardiographic parameters presented in Table 5 further elucidate the superior right ventricular performance in Atrial Valve Group, with consistently higher tricuspid annular plane systolic excursion and fractional area change values and lower rates of moderate to severe pulmonary regurgitation across all time points compared to No-Valve Group. These findings highlight the protective effect of pulmonary valve reconstruction in mitigating pulmonary regurgitation and preserving right ventricular systolic function, offering a significant advantage over standard transannular patch repair in the early and intermediate post-repair period.
The tailored approach to pulmonary valve reconstruction, accommodating variable right atrial appendage sizes, further enhances the clinical utility of this technique. The need for augmentation with fresh pericardial patch was limited to only 6 of 205 cases (2.9%), indicating that the right atrial appendage was sufficient in the vast majority of patients. This adaptability aligns with prior studies on the versatility of autologous tissues in congenital heart surgery. Reference Ozaki17 The low augmentation rate underscores the reliability of the right atrial appendage as a primary tissue source, ensuring consistent valve functionality across diverse anatomical presentations. In contrast, monocusp valves—while initially effective—often suffer from cusp retraction, where 25% developed moderate pulmonary regurgitation within 6 months. Reference Tanase, Georgiev and Schreiber16 Our findings suggest that right atrial-derived valves may provide more stable mid-term haemodynamic performance than monocusp approaches. Longer follow-up is necessary to determine whether late fibrosis or structural degeneration occurs. Our perioperative outcomes, including longer CPB and ACC times, were offset by shorter ICU stays and reduced pulmonary regurgitation severity. The right atrial appendage’s autologous nature may reduce the risks of long-term calcification compared to monocusp valves. Reference Onan, Ergün, Özturk, Çelik, Ayyıldız and Onan11 The 1-year follow-up period captures critical early outcomes, particularly in resource-limited settings. Reference Onan, Ergün, Özturk, Çelik, Ayyıldız and Onan11 Long-term outcomes of similar techniques using autologous or synthetic materials for pulmonary valve reconstruction provide valuable insights into durability and growth potential. Amirghofran et al. Reference Amirghofran, Edraki and Mehdizadegan23 reported 3-year outcomes of right atrial appendage-based pulmonary valve reconstruction in tetralogy of Fallot patients, noting a stenosis rate of 6% and a regurgitation rate of 10%. Right atrial appendage valve showed limited growth potential, with a reoperation rate of 15% due to progressive regurgitation in paediatric patients, highlighting the challenge of accommodating growth in younger patients. Rawat et al. Reference Rawat, Kumar and Thingnam24 reported 1-year outcomes comparing polytetrafluoroethylene valves with pericardial patch reconstruction in tetralogy of Fallot patients, noting higher stenosis but lower regurgitation with polytetrafluoroethylene. Reference Rawat, Kumar and Thingnam24 The polytetrafluoroethylene valve offered reduced regurgitation but increased stenosis risk, and, being a synthetic material, lacked growth potential, necessitating careful long-term monitoring in paediatric patients. Almousa et al. Reference Almousa25 further emphasised the advantages of autologous tissue in paediatric cardiac surgery, reporting reduced calcification rates compared to synthetic materials, supporting the rationale for using right atrial appendage tissue in our study. Harris et al. Reference Harris26 highlighted growth limitations with autologous approaches. Reference Harris26 Ozaki et al. Reference Tanase, Georgiev and Schreiber16 reported 5-year outcomes of autologous pericardial reconstruction in paediatrics, noting early pulmonary regurgitation rates of 7–10%, but 15% at 5 years due to calcification and limited growth potential. These studies suggest autologous and synthetic valves offer early haemodynamic benefits but lack growth potential in paediatrics, often requiring reintervention. Reference Tanase, Georgiev and Schreiber16,Reference Amirghofran, Edraki and Mehdizadegan23–Reference Harris26 The primary benefit of right atrial appendage-based pulmonary valve (PV) reconstruction is achieving midterm valve competence, reducing chronic pulmonary regurgitation and right ventricular dysfunction. At our most recent follow-up of 12 months, the right atrial appendage-based PV in Atrial Valve Group demonstrated sustained competence, with a significantly lower rate of moderate to severe pulmonary regurgitation (22% ± 7 vs. 37% ± 10, p < 0.01) and no significant increase in right ventricular outflow tract gradient (10.9 ± 3.5 mmHg vs. 11.4 ± 3.8 mmHg, p = 0.15), indicating effective valve function and the absence of residual obstruction (Table 6, Figure 2). These outcomes support the technique’s potential to mitigate the haemodynamic burden of chronic pulmonary regurgitation, as evidenced by reduced right ventricular insufficiency (9.3% vs. 19.8%, p = 0.004) and improved right ventricular systolic function (higher tricuspid annular plane systolic excursion and fractional area change, p < 0.01) at 12 months. In the context of tetralogy of Fallot repair, a 1-year follow-up period is a meaningful time frame for assessing midterm outcomes, capturing critical indicators of valve performance and right ventricular remodelling that are pivotal for long-term prognosis. First, the 12-month period provided a homogeneous cohort with complete, high-quality echocardiographic data at predefined intervals, ensuring statistical reliability. Second, imaging archives for some patients operated on between 2014 and 2017 showed inconsistencies in long-term follow-up data standardisation, prompting us to prioritise the 1-year dataset to maintain methodological integrity. Third, the first 12 months represent a critical window for assessing surgical success, particularly in terms of valve competence, right ventricular function, and early remodelling, which are pivotal in resource-limited settings where growth-compatible autologous valve solutions are increasingly needed. However, recognising the importance of long-term outcomes, we are continuing to monitor both Atrial Valve Group and No-Valve Group patients. A subset of patients (n = 78) is under 5-year analysis for future publication. The absence of significant stenosis or regurgitation at 1-year follow-up is encouraging, but extended follow-up is needed to assess right atrial appendage-based valve durability, growth adaptation, and degeneration resistance. Despite the promising early outcomes, several limitations of the right atrial appendage valve technique warrant discussion. First, surgical excision of the right atrial appendage carries a theoretical risk of atrial arrhythmias due to its anatomical proximity to the sinoatrial node and right coronary artery. Although arrhythmia incidence was low in our cohort, long-term conduction studies are needed. Second, the biological tissue may be prone to fibrosis or structural deterioration over time. Third, morphological variability in right atrial appendage anatomy may preclude consistent replication, especially in younger infants. Future studies should focus on standardising criteria for right atrial appendage selection.
Ozaki’s autologous pericardial trileaflet reconstruction and 3D-printed bioresorbable scaffolds have shown promise in pulmonary valve reconstruction. Ozaki’s technique reports early pulmonary regurgitation rates of 7–10%, Reference Ozaki17 but requires glutaraldehyde fixation, which may pose risks of calcification in paediatric patients. Similarly, 3D-printed scaffolds are innovative but currently limited by high costs and lack of widespread availability. Reference Slater18 While these approaches offer valuable insights, direct comparative studies with our right atrial appendage-based technique are lacking, limiting definitive conclusions about relative efficacy. Future research should focus on head-to-head comparisons to evaluate their performance in similar patient populations.
Atrial Valve Group’s ventilation time and ICU stays were significantly reduced. These reductions translate to significant cost savings. Reference Alimi19 Early extubation reduces the risk of ventilator-associated pneumonia. Reference Gaynor20
Some may argue that the 7-minute CPB prolongation (Cohen’s d = 0.80) offsets the benefits. However, a 2023 meta-analysis found no correlation between CPB duration <60 minutes and neurodevelopmental outcomes, Reference Lee21 and the effect size is moderate. Arrhythmia rates (4.9%) were low. Unlike other surgeons, Reference Caputo22 we perform right atrial appendage excision after aortic cross-clamping and cardioplegia, without an additional atrial clamp. This approach enhances procedural ease with a clearer surgical field and reduces sinus node and right coronary artery (RCA) damage risk. Ceasing blood flow creates a bloodless field, avoiding stress on the sinus node and RCA. Our experience suggests this simplifies the procedure and lowers injury rates due to better visualisation.
Comparative studies are needed to confirm long-term outcomes. The absence of valve-related reinterventions, thrombus formation, and endocarditis in both groups during the 1-year follow-up supports the short-term safety and feasibility of right atrial appendage-based valve reconstruction. However, long-term studies are needed to confirm the durability of the reconstructed valve and to monitor for potential late complications, such as leaflet degeneration or calcification.
Limited data exist on the long-term outcomes of right atrial appendage-based techniques, particularly regarding growth potential and stenosis or regurgitation. The absence of stenosis or regurgitation at 1-year follow-up is encouraging, but late complications remain uncertain. Long-term studies are needed to evaluate right atrial appendage-based valve growth capacity and monitor for stenosis or regurgitation in paediatrics.
Future directions
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1. Long-Term Durability: A planned 5-year follow-up will assess fibrosis risk using 4D flow MRI .
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2. Age Stratification: Ongoing subgroup analysis of infants <6 months (n = 45 in Atrial Valve Group).
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3. Regenerative Potential: RNA sequencing of explanted atrial valves (ethics approval pending) to identify pro-remodelling microRNAs.
Limitations
The retrospective design may introduce selection and information biases. To mitigate this, patient selection was standardised, and data were collected by two researchers. However, unmeasured confounders may persist, necessitating prospective studies to validate our findings.
Conclusion
Right atrial tissue offers a viable alternative for pulmonary valve reconstruction in tetralogy of Fallot repair, reducing right ventricular dysfunction over a 1-year follow-up with significant clinical and statistical advantages. Longitudinal studies are needed to evaluate valve function and ventricular remodelling beyond this period.
Photo 1. A 5-month-old, 4.2 kg TOF patient.
Photo 2. Some important anatomical landmarks and descriptive annotations for the right atrial appendage.
Photo 3a. Careful excision of the right atrial appendage after cardioplegia administration.
Photo 3b. Careful excision of the right atrial appendage after cardioplegia administration.
Photo 4. Placement of the right atrial appendage on a wet gauze compress after excision.
Photo 5. The RAA was suspended from four corners using 7-0 prolene sutures and subsequently fixed with small mosquito clamps.
Photo 6. Removal of trabeculae from within RAA.
Photo 7. The apex was carefully incised with a 11-mm scalpel cut extending from the left edge to the right edge, forming a bileaflet valve structure.
Photo 8. Preparation of the created bileaflet valve for anastomosis. Suturing will commence with the base portion of the RAA positioned at the pulmonary annulus.
Photo 9. Anastomosis of the inferior portion of the RAA base to the pulmonary annulus, starting from the left edge.
Photo 10a. The RAA valve was sutured to the pulmonary annulus. The right and left edges were anastomosed using 7-0 Prolene sutures. The image shows the closed VSD (with a bovine pericardial patch) and the right ventriculotomy incision.
Photo 10b. The RAA valve was sutured to the pulmonary annulus. The right and left edges were anastomosed using 7-0 Prolene sutures. The image shows the closed VSD (with a bovine pericardial patch) and the right ventriculotomy incision.
Photo 11. Checking the adequacy of valve width using a Hegar dilator.
Photo 12. Measuring the length of the transannular patch to be used with a silk suture.
Photo 13. Marking the measured patch length with a pen.
Photo 14. Measuring the width of the transannular patch to be used with a silk suture.
Photo 15. Marking the measured patch width with a pen.
Photo 16. Drawing the shape of the patch to be used with a pen after marking the patch length and width.
Photo 17. Drawing the shape of the patch to be used with a pen after marking the patch length and width, and marking the location where the upper edge of the base of the RAA valve will be sutured.
Photo 18a. Preparation of the bovine pericardial patch to be used.
Photo 18b. Preparation of the bovine pericardial patch to be used.
Photo 18c. Preparation of the bovine pericardial patch to be used.
Photo 19a. After suturing the bovine pericardial patch to the right and left edges of the RAA valve using 7-0 Prolene sutures, the upper base of the RAA valve is joined to the patch with 7-0 Prolene sutures.
Photo 19b. After suturing the bovine pericardial patch to the right and left edges of the RAA valve using 7-0 Prolene sutures, the upper base of the RAA valve is joined to the patch with 7-0 Prolene sutures.
Photo 20. Valve assessment with saline solution.
Photo 21. Final photo after completing all anastomoses and weaning off cardiopulmonary bypass.
Acknowledgements
The authors thank colleagues for their support in data collection and patient care.
Competing interests
The authors declare no conflicts of interest.
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