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Ligation of patent ductus arteriosus through left anterior mini-thoracotomy in preterm infants

Published online by Cambridge University Press:  25 May 2022

Yiğit Kılıç Open the ORCID record for Yiğit Kılıç [Opens in a new window] ,
Ahmet Kuddusi Irdem ,
Onur Doyurgan Open the ORCID record for Onur Doyurgan [Opens in a new window] ,
Gül Özlem ,
Hasan Balik ,
Esra Aktiz Bıcak ,
Fikret Salik  and
Bedri Aldudak
Yiğit Kılıç*
Affiliation:
Department of Pediatric Cardiac Surgery, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Ahmet Kuddusi Irdem
Affiliation:
Department of Pediatric Cardiac Surgery, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Onur Doyurgan
Affiliation:
Department of Pediatric Cardiac Surgery, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Gül Özlem
Affiliation:
Department of Pediatric Cardiology, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Hasan Balik
Affiliation:
Department of Pediatric Cardiology, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Esra Aktiz Bıcak
Affiliation:
Department of Anesthesiology and Reanimation, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
Fikret Salik
Affiliation:
Department of Anesthesiology and Reanimation, Dicle University Medical Faculty, Diyarbakir, Turkey
Bedri Aldudak
Affiliation:
Department of Pediatric Cardiology, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey
*
Author for correspondence: Yigit Kilic, Department of Pediatric Cardiac Surgery, Dr. Gazi Yasargil Training and Research Hospital, Diyarbakir, Turkey. E-mail: [email protected]
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Abstract

Objective:

Patent ductus arteriosus is an important cause of morbidity and mortality, especially in very low birth weight infants. The aim of the study is to report our single-centre short-term results of preterm patients who underwent ligation through left anterior mini-thoracotomy .

Methods:

Data of 27 preterm infants operated by the same surgeon who underwent Patent ductus arteriosus (PDA) closure with left anterior mini-thoracotomy technique between November 2020 and January 2022 at a single institution were reviewed. The patients were divided into two groups according to their weight at the time of surgery. Data on early postoperative outcomes and survival rates after discharge were collected.

Results:

Twenty-seven patients with a mean (±SD) gestational age of 25.8 (±2.0) weeks and a mean birth weight of 1027 (±423) g were operated using left anterior mini-thoracotomy technique. The lowest body weight was 480 g. Complications such as bleeding, abnormal healing of incision, or pneumothorax were not seen. There were 8 mortalities after the operation (29,6 %). The causes of the deaths were sepsis, necrotising enterocolitis, hydrops fetalis, hepatoblastoma, and intracranial bleeding. There was no statistically significant difference in the rates of complication between the groups.

Conclusions:

Left anterior mini-thoracotomy technique can be performed as the first choice when transcatheter intervention cannot be applied in preterm infants. It provides easy access to the PDA, a good exposure, minimal contact with the lungs, good cosmetic results in early and mid-term and shortens the operation time, especially in very low birth weight preterm babies. However, early ligation may be helpful to minimise the complications related to PDA.

Keywords

Patent ductus arteriosusPrematureMinimally invasive surgery
Type
Original Article
Information
Cardiology in the Young , Volume 33 , Issue 1 , January 2023 , pp. 113 - 118
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Copyright
© The Author(s), 2022. Published by Cambridge University Press

Patent ductus arteriosus (PDA) is one of the most common congenital anomalies of the neonates. Reference Kitterman, Edmunds, Gregory, Heymann, Tooley and Rudolph1Reference Lee, Lee and Park3 Persistence of this fetal connection leads to left ventricular volume overload, pulmonary hypertension, increased mechanical ventilatory support, hypotension requiring inotropic support, oliguria/renal failure, or feeding intolerance/failure to gain weight. Surgical closure is considered when medical therapy fails. In preterm infants, surgical closure technique is especially important as you deal with congested lungs. Minimally invasive techniques are more and more used in this manner. Reference Baruteau, Hascoet and Baruteau4,Reference Jin, Liang and Wang5 Among different minimally invasive strategies that have emerged in the last decades, left anterior mini-thoracotomy has been recognised as a safe, efficient, and less expensive technique. Reference Leon-Wyss, Vida and Veras6Reference Demirturk, Güvener, Coşkun and Tünel9 In this study, we tried to evaluate the effects of the less invasive left anterior mini-thoracotomy technique and share our results.

Materials and methods

This study involved a retrospective review of the clinical and operative records of 27 preterm infants (gestational age < 37 weeks) who had surgical closure of PDA with left anterior mini-thoracotomy technique between November 2020 and January 2022 at a single institution. 27 patients underwent PDA closure with this technique (9 male, 18 female). Same paediatric surgeon operated all the patients. PDA was closed in premature infants who had congestive heart failure despite medical treatment or showed a large left to right shunt on echocardiogram causing increased mechanical ventilatory support, hypotension requiring inotropic support, oliguria/renal failure, or feeding intolerance/failure to gain weight The range of the weight at operation was 480–2700 g. Preoperatively, 26 infants were ventilator-dependent.

Data on early postoperative outcomes and survival rates after discharge were collected. Baseline information of patients is shown in Table 1. The data collected include medical treatment time, preoperative mechanical ventilation support(days), PDA closure with clip or ligation, operation time, intraoperative blood loss, conversion to sternotomy or thoracotomy, use of inotropic agents, surgery-related complications, postoperative length of stay(days), hospital length of stay(days), transfer to another hospital, postoperative mechanical ventilation time(days), complications in the ICU, hospital mortality, and number of patients still alive. All operations were performed in the operating room of our hospital.

Table 1. Patient characteristics in all cases

MV: Mechanical ventilation, LOS: Length of stay.

Surgical technique

In the operating room, three-lead electrocardiography and pulse oximetry were used for routine monitoring. The patient was under a heater until the operation started. Central venous catheter or invasive arterial monitoring were not used routinely. Adrenalin infusion was started routinely. In left anterior mini-thoracotomy technique, approximately 2–3 cm incision was made through the second intercostal space. The incision was limited to left internal mammarian artery. The lung was retracted with a small rolled gauze gently. A longitudinal incision 1 cm above the phrenic nerve was made. Then, a stay suture was placed at pericardium to visualise the ductus and the pulmonary arteries. After the dissection of the lateral surfaces of the ductus was completed, a clip was placed on the PDA or the PDA was ligated with a 2-0 silk suture. Especially in the case of fragile and thin-walled PDAs, single clip was preferred. The surgical incision was closed with interrupted 4/0 prolene sutures without a chest tube (Fig 1). The study was conducted in accordance with the principles of the Declaration of Helsinki and was approved by the ethics committee. Permission for this study was granted by the Dr Gazi Yasargil Training and Research Hospital Ethical Committee of Clinical Researches with the decision number 26 and date 11.02.2022.

Figure 1. Clip ligation of PDA in a 480 g preterm infant.Clip-ligated PDA is shown with black arrow.

Routine postoperative care

We transferred all the preterms back to the neonatal ICU. Fentanyl infusion was commenced. Epinephrine infusion was gradually decreased and stopped according to the mean arterial pressure. Mean arterial pressure of less than that for corrected gestational age was defined as hypotension. One hour after the procedure, all preterms had a chest X-ray to exclude possible haemothorax or pneumothorax.

Statistical analysis

Patient cohort was divided into two groups according to their weight at the time of surgery: Group 1 < 1000 g and Group 2 ≥ 1000 g. The SPSS statistical programme for Windows, version 22 (SPSS, Inc., Chicago, IL, United States of America) was used for data analysis. The Shapiro–Wilk test was used for the analysis of compliance with normal distribution. Normally distributed continuous data are presented as a mean ± standard deviation together with its ranges in brackets, and nominal variables are presented as counts and/or percentages. Non-normally distributed continuous data are presented as a mean ± standard deviation and the median parameters with their interquartile ranges in brackets. For statistical comparison of group data, Student’s t-test was used for normally distributed continuous variables and Mann–Whitney U-test for non-normally distributed continuous variables. Complication and death incidences for both groups were tested for significance using the Ki-Kare ve Fisher’s exact test. All statistical tests were two-sided. A p value of < 0.05 was considered statistically significant

Results

Twenty-seven patients with a mean (±SD) gestational age of 25.8 (±2.0) weeks and a mean birth weight of 1027 (±423) g were operated using left anterior mini-thoracotomy technique. Eighteen were females (66 %), 9 were males (33 %). 17 (62 %) were born at ≤ 26 weeks, and 17 were ≤ 1000 g. According to their weight at the time of operation, the patients were separated into two groups: Group 1 ≤ 1000 g (n: 13) and Group 2 > 1000 g (n: 14). Mean weight of all the patients on operation day was 1188 (±553) (480-2700 g). In Group 1, it was 822 (±169) g, and in Group 2, it was 1528 (±573) g. Statistical difference was significant between Group 1 and 2 : 822 (±169) g, 1528 (±573) g, respectively( p: 0.000). Mean age of all the patients on operation day was 29,7 ± 16,1 days. In Group 1, it was 23 (±12), and in Group 2, it was 36 (±20) days, respectively (p: 0.079). Statistical difference was not significant between Group 1 and 2. Each group had some limitations as all the patients in group 1 were very low birth weight, 7 patients in group 2 were very low birth weight. All of the cases were completed without cardiopulmonary bypass. There was no blood loss during the cases, no surgery-related mortality or no significant difference in operation time between the cases. As the patients had no drainage tube, they had no drainage after the operation. Complications such as bleeding, abnormal healing of incision, or pneumothorax were not seen. Patients’ preoperative conditions were analysed in Table 2. Additional comorbidities of the patients before the surgery were 8 bacterial sepsis (29,6 %), 3 necrotising enterocolitis(11 %),1 hydrocephalus (0,3 %), 4 intracranial haemorrhage (14,8%). All of the patients had congestive heart failure and five had a pulmonary infection. A clip was placed on the PDA in 16 patients and PDA was ligated with a 2-0 silk suture in 11 patients. Mean operation time was 18.7 (±5.5) minutes (range, 10–40 minutes). After a day of postoperative follow-up, we sent the patients back to centres they came from. We transferred all the 13 patients back to centres they came from. The remaining patients’ postoperative mean mechanical ventilatory support time was 29.5 (±42.6) days (range, 1–165 days), mean hospital stay was 71.5 (±56.0) days (range, 7–193 days) and the mean postoperative length of stay was 47.4 (±44.2) days (range, 6–165 days). There were 8 mortalities after the operation (29,6 %). Five were due to sepsis, one was due to necrotising enterocolitis, one was due to hydrops fetalis and one was due to renal failure with hepatoblastoma. There was no internal thoracic artery injury or no need for conversion to thoracotomy or sternotomy. All patients except one were ventilator-dependent before surgery. That patient had rapidly progressive renal failure before the surgery. There were 16 (59%) postoperative complications (8 in Group 1 and 8 in Group 2) during intensive unit care stay. In addition, there were 6 (22%) deaths in the postoperative first 30 days and 4 (14,8%) deaths between the postoperative first month and first year. Two patients died after discharge. The causes of the deaths were sepsis, necrotising enterocolitis, hydrops fetalis, hepatoblastoma and intracranial bleeding. Left diaphragmatic elevation developed in 1 patient, and plication was performed. Three percent (one patient) of all patients needed reoperation because of a significant residual patent ductus arteriosus. This patient was reoperated on postoperative day 1 through the same thoracotomy incision. Other residual shunt closed spontaneously. 17 of all patients are still alive (Table 3).

Table 2. Patient characteristics in both groups

NEC: Necrotising enterocolitis, CHF: Congestive heart failure, ARF: Acute renal failure, RDS: Respiratory distress syndrome, ROP: Retinopathy of prematurity, MV: Mechanical ventilation.

Table 3. Outcome data of both groups

MV: Mechanical ventilation, LOS: Length of stay.

Discussion

PDA is one of the most common CHDs. Excessive blood flow to the lungs caused by PDA results in pulmonary congestion, pulmonary oedema, and respiratory failure. Reference Benitz10 This patency may also cause cerebral, renal, or mesenteric hypoperfusion that leads to serious complications in ICU. Reference Overmeire and Chemtob11 Medical management, surgical ligation, or percutaneous closure of PDA are treatment methods used currently for preterm infants. Percutaneous closure of PDA has really limited place among the treatment methods although transcatheter technology advances. Reference Moore, Greene and Palomares12Reference Sathanandam, Agrawal and Chilakala15

Indomethacin or ibuprofen is used for the medical treatment of PDA. If medical treatment is unsuccessful, surgical closure is performed. These drugs have various side effects and may cause thrombocytopenia, necrotising enterocolitis, pulmonary oedema and bleeding, renal failure. Reference Mercanti, Boubred and Simeoni16 There are even publications suggesting early surgery instead of medical therapy to save the patients from complications of PDA and medications. Reference Avsar, Demir, Celiksular and Zeybek17,Reference Ko, Chang, Chiu, Chen, Huang and Hsieh18

Rapid development of science and technology new occlusion devices serve to close PDA in appropriately selected preterms. It is still not routinely occluded in very small infants with birth weight ≤ 2 kg and still there is a lack of experience. Reference Moore, Greene and Palomares12 . However, Pouldar et al reported percutaneous PDA closure with a 3/2 mm Amplatzer Piccolo Occluder Device in a 790 g preterm in their case report. Procedure did not require moving the patients to cardiac catheterisation laboratory or operating room. Reference Pouldar, Wong, Almeida-Jones, Zahn and Lubin19 As it is safe and successful, transcathater closure of PDA receives more attention, but there are some concerns about vascular access, risk of residual shunt, providing the suitable device, possibility of device migration or embolisation and contrast administration in preterm infants. Reference Weisz and Giesinger20,Reference Nealon, Rivera and Cua21

In 1938, Gross was first to ligate PDA successfully. Reference Susheel Kumar22 With the improvement in cardiovascular surgery, better cosmetic results and less harm to lung tissue became more important. For this purpose, several minimally invasive techniques have been tried by surgeons instead of the conventional methods without affecting the operative results. Reference Susheel Kumar22,Reference Garcia and Lukish23

Lateral thoracotomy has been procedure of choice for PDA closure in preterm infants for over five decades, but it doesn’t have the qualities that left anterior mini-thoracotomy technique has. Lung injury and potential long-term spinal and chest wall deformities are potential risks of lateral thoracotomy. Reference Verhaegh, Accord and Kooi24,Reference Bal, Elshershari, Celiker and Celiker25

Verhaegh et al compared lateral thoracotomy with sternotomy for PDA closure in preterm infants, and they found that the postoperative pulmonary complication rate was significantly lower in the median sternotomy patients. This obviously shows that it is important not to touch lungs as much as possible during operation to avoid lung-related postoperative complications. Reference Verhaegh, Accord and Kooi24

Technically, left anterior mini-thoracotomy technique requires short surgical times (< 20 minutes), offering direct visualisation of the left recurrent laryngeal nerve, thus preventing complications secondary to its damage, guarantees good surgical exposure of the PDA (also in patients < 1,5 kg who are not routinely managed through catheterisation). In addition, less trauma to lung tissue reduces the risk of pulmonary complications. This technique also has good aesthetical results in early and mid-term follow-up. This is a simple technique and provides good exposure and the closest approach to the PDA when compared to the other thoracotomy incisions. The patient is in the supine position during the operation with the left chest elevated for anterior mini-thoracotomy. Supine position provides extra comfort for the surgeon and can be maintained easily in the operating room or in the ICU. In case of emergency (e.g. massive bleeding), you can easily convert to sternotomy.

We operated all of our patients in the operating room. Patient was under the heater till the beginning of the operation. Sometimes, even gentle traction of pulmonary artery for PDA dissection to have a better view caused bradycardia and hypotension so adrenaline infusion was administered routinely. Our operation time was generally under 20 minutes. Therefore, time under hypothermia was also not long. Our lightest baby was 480 g. Interestingly, we operated twins, two sisters, on the same day and discharged them to home one day apart.

In our study, we especially focused on advantages of the technique on time and lung-related complications and possible surgical complications related to PDA closure. In our cohort, we didn’t have any intraoperative bleeding, chylothorax, and chylomediastinum, but we had one left diaphragma elevation. Left diaphragma was plicated, and the patient was successfully discharged. Dissection of PDA for better view may be dangerous for some patients who have more fragile PDA tissue than the others. In these type of cases, we prefer clip ligation. In these cases, using a metallic vascular clip allows for limited dissection and safe occlusion. After the operation air was removed using the underwater drainage system, thoracotomy was closed without placing a chest tube. This may have improved the comfort of the patient after the operation.

48% Reference Francis, Singhi, Lakshmivenkateshaiah and Kumar13 of the patients were transferred to our centre for PDA closure. After the operation, we followed up the patients for one day in our neonatal ICU. The day after the operation all of the 13 patients were transferred back to their centres. Transfer of a preterm patient especially before the surgery is important. If the patient comes to the surgery in hypothermic condition with loss of intravenous lines or ventilation problems, this may increase the risk of the surgery.

Although there was no surgery-related mortality, our hospital mortality rate was 29,6 %. This is higher than most of the prior studies related to PDA closure in preterms. Reference Verhaegh, Accord and Kooi24Reference Lehenbauer, Fraser and Crawford26 As our cohort includes preterm patients with PDA and serious comorbidities, these mortality rates are connected to complications associated with prematurity, infection, and comorbidities. Five were due to sepsis, one was due to necrotising enterocolitis, one was due to hydrops fetalis, and one was due to renal failure with hepatoblastoma.

Of course, we have several limitations. First of all, a limited population was retrospectively studied. We only have early and mid-term results but not long-term results. Also, we cannot compare the technique with another technique as we did not have another group operated by another surgical technique. All of these avoid us claiming the superiority of the technique over other techniques. Also, our short- and mid-term results with left anterior mini-thoracotomy technique in preterm infants are promising.

To conclude, left anterior mini-thoracotomy technique can be performed as the first choice when transcatheter intervention cannot be applied in preterm infants. It provides easy access to the PDA, a good exposure, minimal contact with the lungs, good cosmetic results in early and mid-term and shortens the operation time, especially in very low birth weight preterm babies. However, early ligation may be helpful to minimise the complications related to PDA. Prospective randomised studies are needed to compare the technique’s safety and efficiency with other conventional techniques.

Acknowledgements

None.

Financial support

The authors received no financial support for the research and/or authorship of this article.

Conflicts of interest

None.

Ethical standards

The study was conducted in accordance with the principles of the Declaration of Helsinki and was approved by the ethics committee. Permission for this study was granted by the Dr Gazi Yasargil Training and Research Hospital Ethical Committee of Clinical Researches with the decision number 26 and date 11.02.2022. mentioned in material- methods.

References

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Figure 0

Table 1. Patient characteristics in all cases

Figure 1

Figure 1. Clip ligation of PDA in a 480 g preterm infant.Clip-ligated PDA is shown with black arrow.

Figure 2

Table 2. Patient characteristics in both groups

Figure 3

Table 3. Outcome data of both groups