Surgical options for proximal and distal transverse arch hypoplasia in infants with coarctation
Introduction
The transverse aortic arch can be divided into two parts: the proximal and distal arches. The use of extended end-to-end repair in patients with distal arch hypoplasia is associated with safe and excellent results (1). However, the surgical option for proximal and distal transverse arch (PDTA) hypoplasia is controversial. Several surgical techniques have been reported to repair the PDTA: (I) direct anastomosis, including end-to-side anastomosis (ESA) or extended end-to-end anastomosis (EAAA); (II) patch aortoplasty, including autologous pericardial patch (APP), bovine pericardial patch (BPP), and autologous pulmonary artery patch (APAP). However, no consensus has been reached on the surgical option for PDTA hypoplasia. Direct anastomosis has the advantages of few surgical procedures and shorter operative time, but the changed arch geometry may more likely cause recoarctation or hypertension (2). Patch aortoplasty could maintain the arch geometry and decrease the anastomotic tension, but the heterogeneous artery wall may give rise to the formation of an aneurysm (3,4).
Among various surgical options, it is crucial to select the optimal initial surgical approach according to the patients’ pathophysiological conditions, especially in infants (3,5). Herein, we describe our single-center experience of various surgical options for PDTA reconstruction. We analyzed the outcomes of different techniques to determine the appropriate surgical option for Chinese infants with PDTA hypoplasia. We present the following article in accordance with the STROBE reporting checklist (available at https://tp.amegroups.com/article/view/10.21037/tp-21-557/rc).
Methods
Ethical statement
The study was conducted in accordance with the principles of the Declaration of Helsinki (as revised in 2013) and approved by the Ethics Committee of Shanghai Children’s Medical Center (No. SCMCIRB-W2021038). The requirement for obtaining individual consent for this retrospective analysis was waived. This study has been registered with the Chinese Clinical Trials Registry (https://www.chictr.org.cn) as ChiCTR2100048212.
Definitions
The transverse arch is commonly separated into two segments: (I) proximal, between the innominate artery and left common carotid artery, and (II) distal, between the left common carotid artery and the left subclavian artery (Figure 1A).
Both PDTAs are hypoplastic if (I) the ratio of the external diameter of the proximal arch to the ascending aorta ratio is <0.6 and the ratio of the external diameter of the distal arch to the ascending aorta ratio is <0.5, and (II) its length exceeds 5 mm (3,6). In this study, a blinded researcher assessed different types of arch hypoplasia using preoperative computed tomography images (Figure 1B). Z-Score was calculated as reported by transthoracic echocardiography (7).
Recoarctation was defined as a pressure gradient across the repair site of ≥20 mmHg by transthoracic echocardiography (8).
Patient population and data collection
Between 2010 and 2020, 857 consecutive patients mainly diagnosed with coarctation or hypoplastic aortic arch were retrospectively identified from the hospital database in Shanghai Children’s Medical Center. The inclusion criteria were: (I) diagnosis with PDTA hypoplasia; (II) age at surgery less than 1 year; (III) the operation performed as primary surgery and via sternotomy with cardiopulmonary bypass. The exclusion criteria were residual obstruction and patients who received EAAA (Figure 2).
After the screening, a total of 121 patients were enrolled. Preoperative, intraoperative, and postoperative data were collected from the patients’ inpatient medical records. Follow-ups were scheduled 1, 3, and 6 months after discharge, then every 6 months for the next 18 months, and then regularly once every year. Follow-up data were collected from the outpatient system and telephone calls.
Surgical techniques
All patients underwent midline sternotomy and cardiopulmonary bypass. Regional cerebral oxygen saturation was monitored using near-infrared spectroscopy in all patients. After cardiopulmonary bypass was initiated, the transverse arch, innominate, left common carotid and left subclavian arteries, isthmus, and descending aorta were exposed and mobilized carefully and widely.
Based on our center experience, the limited ability to tolerate surgery in infants is important, and we would choose ESA due to its fewer procedures and shorter operative time. However, if mobilization of the descending aorta was limited or the aortic arch geometry appeared abnormal, we would change to aorta enlargement by patch repair. In this study, all valves regurgitation were no need for additional surgery. The other additional intracardiac malformations were corrected at one stage.
Reconstruction of the aortic arch was performed according to the following procedures. For the end-to-side procedure, the distance between the ascending aorta and the coarctation was not quite long; hence, it was possible to fully mobilize the descending aorta and directly anastomose it to the terminal end of the ascending aorta, as the proximal descending aorta was ligated.
In cases of patch aortoplasty, some procedures should be performed before patch use. The dissected autologous pericardium was treated with glutaraldehyde for 10 min before use. The bovine pericardium was pretreated with glutaraldehyde and used after rinsing it with saline. Pulmonary artery patches were harvested from the main pulmonary artery (MPA). When a pulmonary autograft was used, the remaining defect was repaired with a glutaraldehyde-fixed autologous pericardium or bovine pericardium. Afterward, an incision was made along the inferior aspect of the aortic arch, usually between the innominate artery and descending aorta. When posterior anastomosis was completed, the remaining anterior aspect of the aorta was supplemented with three different patch materials (Figure 3).
For patch material selection, we tended to choose autologous pericardium to perform the arch reconstruction. If the size of autologous pericardium was not large enough to reconstruct the transverse arch, bovine pericardium would be chosen. In some cases whose pulmonary arteries were large enough, pulmonary artery patch would be used to reconstruct aortic arch.
Statistical analyses
Continuous variables are presented as means ± standard deviations for normally distributed values or as medians with interquartile ranges (IQRs) for non-normally distributed values. The chi-square or Fisher exact test was used to analyze categorical data. For continuous variables, the Student t-test for normally distributed values or Mann-Whitney U test for non-normally distributed values was used to compare data between two groups. For multiple group comparisons, one-way analysis of variance or Kruskal-Wallis nonparametric tests were used. Freedom from recoarctation was determined as time-to-events using the Kaplan-Meier curve and compared using the two-sided log-rank test. Variables with a P value <0.1 in the univariate analysis were analyzed in a subsequent multivariable model. P values <0.05 were considered statistically significant. All statistical analyses were performed using the GraphPad Prism software (version 8.0; GraphPad Software, Inc., La Jolla, CA, USA) or SPSS software (version 26.0; IBM Corp., Armonk, NY, USA).
Results
Patient characteristics
Figure 2 shows the flow chart of patient selection and enrollment criteria. Between 2010 and 2020, 857 patients were identified from the hospital database. Moreover, 18 of the 139 patients were excluded from this retrospective review because of residual obstruction or a limited number of patients received EAAA. Finally, we collected data from 121 (14.1%) infants using outpatient and inpatient medical records or telephone calls.
According to the different repair techniques, all 121 patients were divided into four groups: the ESA (n=37, 30.6%), APP (n=53, 43.8%), BPP (n=20, 16.5%), and APAP (n=11, 9.1%) groups. Perioperative characteristics are presented in Table 1. Preoperative baseline characteristics were not significantly different between the four groups.
Table 1
| Characteristics | ESA (n=37) | APP (n=53) | BPP (n=20) | APAP (n=11) | P value |
|---|---|---|---|---|---|
| Male (%) | 28 (75.7) | 30 (56.6) | 14 (70.0) | 8 (72.7) | 0.262 |
| Age at surgery (days) | 89.5 (51.3–146.0) | 54.0 (39.0–102.5) | 69.5 (50.8–105.8) | 50.0 (29.0–88.0) | 0.080 |
| Neonates (%) | 2 (5.4) | 8 (15.1) | 2 (10.0) | 1 (9.1) | 0.512 |
| Weight at surgery (kg) | 4.6 (3.8–5.6) | 4.2 (3.5–5.0) | 4.2 (3.5–4.9) | 3.8 (3.6–4.6) | 0.268 |
| Length at surgery (cm) | 58.5 (54.3–62.8) | 54.0 (50.0–60.0) | 57.5 (50.8–59.0) | 57.0 (52.0–59.0) | 0.084 |
| Major associated cardiac anomalies (%) | |||||
| Ventricular septal defect | 31 (83.8) | 39 (73.6) | 15 (75.0) | 9 (81.8) | 0.682 |
| Atrial septal defect | 17 (45.9) | 31 (58.5) | 14 (70.0) | 7 (63.6) | 0.325 |
| Patent ductus arteriosis | 16 (43.2) | 23 (43.4) | 8 (40.0) | 1 (9.1) | 0.187 |
| Aortic valve regurgitation | 9 (24.3) | 14 (26.4) | 4 (20.0) | 1 (9.1) | 0.641 |
| Mitral valve regurgitation | 9 (24.3) | 16 (30.2) | 1 (5.0) | 1 (9.1) | 0.120 |
| Tricuspid valve regurgitation | 9 (24.3) | 16 (30.2) | 1 (5.0) | 1 (9.1) | 0.120 |
| Pulmonary valve stenosis | 0 (0.0) | 0 (0.0) | 1 (5.0) | 0 (0.0) | 1.000 |
| Persistent left superior vena cava | 3 (8.1) | 4 (7.5) | 4 (20.0) | 0 (0.0) | 0.324 |
| Double outlet right ventricle | 0 (0.0) | 1 (1.9) | 0 (0.0) | 0 (0.0) | 1.000 |
| Preoperative LVEF (%) | 70.6 (65.7–77.4) | 66.0 (60.4–73.2) | 67.7 (55.5–73.1) | 71.0 (61.2–75.8) | 0.060 |
| Preoperative LVFS (%) | 38.5 (33.9–45.2) | 34.4 (30.6–39.1) | 35.9 (27.5–40.4) | 38.4 (31.1–43.1) | 0.052 |
| Proximal arch relative diameter | 0.53±0.06 | 0.51±0.07 | 0.51±0.05 | 0.47±0.07 | 0.070 |
| Distal arch relative diameter | 0.44±0.06 | 0.42±0.07 | 0.43±0.07 | 0.40±0.05 | 0.312 |
| Z-Score | −3.11±1.15 | −3.17±1.21 | −3.15±1.3 | −2.83±0.88 | 0.864 |
| <−3.0 (%) | 17 (46.0) | 25 (47.2) | 11 (55.0) | 4 (36.4) | 0.794 |
ESA, end-to-side anastomosis; APP, autologous pericardial patch; BPP, bovine pericardial patch; APAP, autologous pulmonary artery patch; LVEF, left ventricular ejection fraction; LVFS, left ventricular fraction shortening.
Furthermore, 22 of 121 patients underwent surgery for deep hypothermic circulatory arrest (DHCA), 9 of 128 patients underwent surgery with deep hypothermic low flow (DHLF), and 35 of 128 patients underwent surgery with selective antegrade cerebral perfusion (SACP). In the patch group, APPs (n=53), BPPs (n=20), and APAPs (n=11) were used to reconstruct the aorta. The mean follow-up time was 1,042 days, and the median follow-up time was 679 (IQR, 388–1,362) days.
Intraoperative and postoperative outcomes
In terms of intraoperative clinical characteristics, patients in the ESA group presented a shorter aortic cross-clamp time than those in the APP group (P=0.005) and BPP group (P<0.001). The BPP group showed a longer aortic cross-clamp time than the APP group (P=0.022). Compared with the ESA and APAP groups, the BPP group demonstrated a longer cardiopulmonary bypass time. No differences were found in the postoperative pressure gradient, intensive care unit (ICU) stay, in-hospital time, or mechanical support time between the four groups (Table 2).
Table 2
| Characteristics | ESA (n=37) | APP (n=53) | BPP (n=20) | APAP (n=11) | P value |
|---|---|---|---|---|---|
| Cardiopulmonary bypass time (min) | 107.1±30.3 | 120.8±34.2 | 141.4±47.2 | 111.3±42.0 | 0.017* |
| Aortic cross-clamp time (min) | 54.9±14.0 | 67.7±25.0 | 82.8±28.7 | 65.7±17.5 | <0.00* |
| DHCA (%) | 9 (24.3) | 9 (17.0) | 1 (5.0) | 3 (27.3) | 0.268 |
| DHLF (%) | 6 (16.2) | 3 (5.7) | 0 (0.0) | 0 (0.0) | 0.145 |
| SACP (%) | 22 (59.5) | 41 (77.3) | 19 (98.9) | 8 (72.8) | 0.269 |
| Postoperative pressure gradient (mmHg) | 15.7±3.6 | 14.3±3.8 | 14.7±3.87 | 15.0±3.6 | 0.434 |
| ICU stay (h) | 135.8 (94.3–170.1) | 159.9 (120.0–192.0) | 138.4 (106.1–174.2) | 144.0 (120.0–163.7) | 0.296 |
| Mechanical support time (h) | 65.1 (43.0–106.0) | 98.4 (56.8–121.1) | 71.6 (37.2–127.7) | 64.9 (30.0–99.3) | 0.067 |
| In-hospital time (days) | 18.0 (12.0–29.5) | 18.5 (15.0–26.3) | 16.0 (13.0–22.0) | 15.0 (13.0–20.0) | 0.274 |
| In-hospital mortality (%) | 0 (0.0) | 4 (7.5) | 1 (5.0) | 0 (0.0) | 0.315 |
| Recoarctation (%) | 19 (51.4) | 16 (30.2) | 8 (40.0) | 1 (9.1) | 0.044* |
| Surgery | 2 (10.5) | 2 (12.5) | 0 (0.0) | 0 (0.0) | 0.839 |
| Transcatheter balloon dilatation | 3 (15.8) | 2 (12.5) | 3 (37.5) | 0 (0.0) | 0.511 |
| Conservative follow-up | 14 (73.7) | 12 (75.0) | 5 (62.5) | 1 (100.0) | 0.867 |
*, P<0.05. ESA, end-to-side anastomosis; APP, autologous pericardial patch; BPP, bovine pericardial patch; APAP, autologous pulmonary artery patch; DHCA, deep hypothermic circulatory arrest; DHLF, deep hypothermic low flow; SACP, selective antegrade cerebral perfusion; ICU, intensive care unit.
Recoarctation
Of the 121 patients, 44 developed recoarctation after the initial aortic arch reconstruction surgery. During the follow-up period, 19 infants (51.4%) developed recoarctation in ESA group. In the patch group, 25 patients (30.0%) developed recoarctation: 16 (30.2%) in the APP group, 8 (40.0%) in the BPP group and 1 (9.1%) in the APAP group. The ESA group showed a higher recoarctation rate than the APAP group (P=0.013). Of the 44 recoarctation patients, 4 patients underwent second surgery via patch enlargement, 2 in the ESA group and 2 in the APP group. Overall, 8 patients underwent transcatheter balloon dilation and stenting: 3 in the ESA group, 2 in the APP group and 3 in the BPP group. The others were under conservative follow-up.
Figure 4 shows freedom from recoarctation in patients in whom different arch repair techniques were used, according to the Kaplan-Meier curve. Compared with the other groups, the ESA group demonstrated significantly higher recoarctation rates (Figure 5; P<0.05, Mantel-Cox log-rank test).
Cox regression univariate and multivariate analyses revealed that ESA [hazard ratio (HR) =1.86; P=0.043 and HR =2.13; P=0.020, respectively] was an independent risk factor for recoarctation after PDTA repair (Table 3).
Table 3
| Variables | Univariate | Multivariate | |||||
|---|---|---|---|---|---|---|---|
| HR | 95% CI | P value | HR | 95% CI | P value | ||
| Weight at surgery | 0.75 | 0.58–0.98 | 0.032* | 0.89 | 0.62–1.28 | 0.526 | |
| Age at surgery | 0.99 | 0.99–1.00 | 0.021* | 0.99 | 0.98–1.00 | 0.081 | |
| Neonatal surgery | 2.83 | 1.35–5.93 | 0.006* | 1.89 | 0.80–4.46 | 0.145 | |
| Preoperative LVEF (%) | 1.00 | 0.97–1.02 | 0.761 | ||||
| Preoperative LVFS (%) | 1.00 | 0.96–1.03 | 0.603 | ||||
| Z-Score | 0.875 | 0.68–1.13 | 0.310 | ||||
| Cardiopulmonary bypass time | 1.00 | 1.00–1.01 | 0.142 | ||||
| Aortic cross-clamp time | 1.00 | 0.99–1.02 | 0.700 | ||||
| ESA | 1.86 | 1.02–3.39 | 0.043* | 2.13 | 1.13–4.01 | 0.020** | |
| APP | 0.71 | 0.38–1.31 | 0.273 | ||||
| BPP | 1.25 | 0.58–2.70 | 0.568 | ||||
| APAP | 0.19 | 0.03–1.35 | 0.097* | 0.20 | 0.03–1.46 | 0.111 | |
*, P<0.1; **, P<0.05. HR, hazard ratio; CI, confidence interval; LVEF, left ventricular ejection fraction; LVFS, left ventricular fraction shortening; ESA, end-to-side anastomosis; APP, autologous pericardial patch; BPP, bovine pericardial patch; APAP, autologous pulmonary artery patch.
Discussion
In this study, of the 121 patients, 44 developed recoarctation after the initial aortic arch reconstruction surgery. During the follow-up period, 19 infants (51.4%) developed recoarctation in the ESA group. In the patch group, 25 patients (30.0%) developed recoarctation: 16 (30.2%) in the APP group, 8 (40.0%) in the BPP group and 1 (9.1%) in the APAP group. We found that ESA showed a higher incidence of recoarctation after surgery than patch aortoplasty. Furthermore, the results demonstrated that ESA is an independent risk factor for recoarctation.
To prevent postoperative recoarctation, relief of anastomotic tension is the most crucial factor in the treatment of PDTA hypoplasia (9,10). Aortic arch reconstruction can rarely be performed without tension in patients with long distances between the hypoplastic segment (11). If the early anastomotic tension is not treated well, late recoarctation could be inevitable in the future (9).
The other key point of transverse arch reconstruction is proximal arch treatment. It is still under debate whether the proximal arch should be treated. Some studies have shown variable degrees of growth potential in patients whose proximal arch was not treated (12,13). However, inadequate growth potential of the proximal arch may lead to the late development of recurrent arch obstruction (2).
Proximal arch hypoplasia
Hypoplasia of the proximal arch is not simply a miniature segment of the normal aortic arch. The hypoplastic aorta has a relatively higher number of elastin lamellae and more collagen than the normal aortic arch, which could limit the hypoplastic segment distension. Furthermore, the differentiation phenomenon of the smooth muscle cells in the media wall has been considered the pathological mechanism of limited growth potential, which could lead to late recoarctation (3,14). Because of the histologic changes of the hypoplastic segment, the hypoplastic proximal arch should be treated, and autologous tissue is preferred between the proximal and distal parts of the repair site. However, in our study, there were no significant differences in recoarctation rates among different patch materials.
ESA
It is controversial whether ESA should be performed in patients with PDTA hypoplasia. Some studies have revealed that ESA could be achieved with good and favorable outcomes (15,16). However, another study found that compared with more extensive anastomosis, ESA has some pitfalls (2,9). Additionally, our study showed that ESA has its shortcomings.
In our center experience, there are four explanations for the higher recoarctation incidence of ESA: neostenosis, geometry, aortopulmonary space, and growth potential. First, because of the ascending aortic cannulation and anastomotic ridge formation, neostenosis may account for postoperative proximal arch recoarctation. The use of a purse-string suture on the anterior aortic wall may give rise to suture-site invagination. Furthermore, direct anastomosis to the proximal arch decreases the length of the transverse arch and enables the facile formation of the anastomotic ridge, with no outward abnormal surgical appearance but in the radiographic finding (Figure 6). To prevent late neostenosis, the ascending aorta could be suspended during the initial procedure.
Second, although the distal descending aorta is widely mobilized, direct anastomosis may decrease the length of the transverse arch, which increases the ratio of the width of the aortic arch to its height (ratio A/T). An increased A/T ratio is believed to be associated with late systemic hypertension after aortic reconstruction (17). Moreover, the differential growth between the proximal and distal aortas to the angulation side contributes to the late formation of the Gothic arch geometry and associated abnormal arch hemodynamics (2,18).
Third, direct anastomosis could reduce the aortopulmonary space and even aggravate the compression of the right pulmonary artery or left main bronchus, especially in patients who need postoperative mechanical support.
Finally, considering the histological changes of the hypoplastic segment and previous study data, waiting for the growth potential of the proximal aortic arch may not be sufficient. In other words, despite the catch-up growth of the proximal aortic arch after the reconstruction surgery in a direct anastomosis group, the diameter of the proximal arch might not reach normal values (2,14).
Patch aortoplasty
Recently, various patch materials have been utilized in aortic arch reconstruction (2,11,19,20). Some scholars consider patch aortoplasty as the choice of treatment for recurrent obstruction (3). However, in our experience, the utilization boundary of the patch in arch reconstruction should be extended. Our results demonstrate that patch aortoplasty is a safe and effective choice for aortic arch reconstruction, with a low incidence of recoarctation.
In patch aortoplasty, anastomotic tension and arch geometry can be considered. Patch repair can sufficiently enlarge the hypoplastic segment to prevent the presence of recoarctation and maintain a relatively normal geometry (9,21). Compared with the ESA group, the patch repair groups tended to show a longer cardiopulmonary bypass time and aortic cross-clamp time. However, our outcomes showed that the ICU stay, mechanical support time, and in-hospital time were not significantly different between the four groups.
Additionally, considering the growth potential of the aortic arch, the autologous artery patch would be beneficial for the growth of the entire aortic arch. The pulmonary artery is homogeneous to the transverse aortic arch, which not only maintains the aorta elastic ability, but also has the potential to grow with aging (20,22). In our follow-up cohort, only 1 of 11 patients in the APAP group developed recoarctation. Nevertheless, the additional surgical procedure may prolong the operative time, and the patch material may be limited by the length and width of the pulmonary artery. Furthermore, this approach potentially causes antigenicity of the patch and alteration of the contour of the aortic arch (11).
To prevent the prevalence of aneurysm or recoarctation, the design and trim of the patch are controversial issues. To understand the entire anastomotic geometry during surgery, we could release the distal aortic clamp and then design a patch with the proper shape. Compared with the preoperative patch design, this procedure was more reasonable and close to the actual condition. For the autologous pulmonary patch, in our center experience, a piece of oval anterior wall of the MPA to the beginning of the left pulmonary artery was harvested.
Limitations
This study has some limitations. First, it was a single-center retrospective comparative study; thus, its findings need to be proven through prospective comparative studies at multiple centers. Second, according to our collected data, EAAA was performed in only seven patients. Because of the limited number of patients, these seven patients were not included in this analysis. Third, institutional bias, surgeon experience, and surgeon preferences were another limitations of this study. Fourth, some data including blood pressure or abdominal aorta pulse were not routine recorded during follow-up examination. Further studies involving other surgical techniques, such as EAAA, longer follow-up time and multiple center data are warranted.
Conclusions
Our study demonstrated that aortic arch reconstruction via ESA in patients with PDTA hypoplasia was an independent risk factor for recoarctation. In our experience, some pitfalls were associated with ESA, including neostenosis, Gothic arch geometry potential, underlying compression of the right pulmonary artery or left main bronchus, and inadequate growth potential.
Additionally, the indications for using patches in arch reconstruction should be expanded. Intraoperatively, if mobilization of the descending aorta is limited or the aortic arch geometry appears abnormal, patch aortoplasty should be chosen to reconstruct the aortic arch.
Acknowledgments
Funding: This work was supported by Shanghai Science and Technology Committee (grant number 1941196490) and Shanghai Municipal Health Commission (grant number 20194Y0301).
Footnote
Reporting Checklist: The authors have completed the STROBE reporting checklist. Available at https://tp.amegroups.com/article/view/10.21037/tp-21-557/rc
Data Sharing Statement: Available at https://tp.amegroups.com/article/view/10.21037/tp-21-557/dss
Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://tp.amegroups.com/article/view/10.21037/tp-21-557/coif). The authors have no conflicts of interest to declare.
Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. The study was conducted in accordance with the principles of the Declaration of Helsinki (as revised in 2013) and approved by the Ethics Committee of Shanghai Children’s Medical Center (No. SCMCIRB-W2021038). The requirement for obtaining individual consent for this retrospective analysis was waived. This study has been registered with the Chinese Clinical Trials Registry (https://www.chictr.org.cn) as ChiCTR2100048212.
Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.
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