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Clinical outcome of transcatheter closure of patent ductus arteriosus in small children weighing 10 kg or less.
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PMID:  21253316     Owner:  NLM     Status:  PubMed-not-MEDLINE    
PURPOSE: Transcatheter closure has become an effective therapy in most patients with patent ductus arteriosus (PDA). However, there are difficulties in transcatheter closure of PDA in small children. We reviewed clinical outcomes of transcatheter closure of PDA in children weighing less than 10 kg in a single center.
METHODS: Between January 2003 and December 2009, 314 patients with PDA underwent transcatheter closure in our institute. Among them, 115 weighed less than 10 kg. All of these patients underwent transcatheter closure of PDA using either COOK Detachable Coil®, PFM Nit-Occlud®, or Amplatzer duct occluder®. A retrospective review of the treatment results and complications was performed.
RESULTS: The mean age of patients was 9.1±5.9 months (median, 8 months), and mean weight was 7.6±1.8 kg (median, 7.8 kg). The mean diameter of PDA was 3.2±1.4 mm (median, 3 mm). Complete occlusion occurred in 113 patients (98%). One patient was sent to surgery because of a failed attempt at device closure, and another patient had a small residual shunt after device placement. The average mean length of hospital stay was 3.0±3.3 days, and mean follow-up duration was 21.0±19.6 months. There were no major complications in any of the patients.
CONCLUSION: Transcatheter closure of PDA is considered safe and efficacious in infants weighing less than 10 kg. With sufficient experience and further effort, transcatheter closure of PDA can be accepted as the gold standard of treatment for this group of patients.
Young A Park; Nam Kyun Kim; Su-Jin Park; Bong Sic Yun; Jae Young Choi; Jun Hee Sul
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Publication Detail:
Type:  Journal Article     Date:  2010-12-31
Journal Detail:
Title:  Korean journal of pediatrics     Volume:  53     ISSN:  2092-7258     ISO Abbreviation:  Korean J Pediatr     Publication Date:  2010 Dec 
Date Detail:
Created Date:  2011-01-21     Completed Date:  2011-07-14     Revised Date:  2013-05-29    
Medline Journal Info:
Nlm Unique ID:  101215374     Medline TA:  Korean J Pediatr     Country:  Korea (South)    
Other Details:
Languages:  eng     Pagination:  1012-7     Citation Subset:  -    
Division of Pediatric Cardiology, Severance Cardiovascular Hospital, Yonsei University Health System, Seoul, Korea.
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Journal Information
Journal ID (nlm-ta): Korean J Pediatr
Journal ID (publisher-id): KJP
ISSN: 1738-1061
ISSN: 2092-7258
Publisher: The Korean Pediatric Society
Article Information
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Copyright © 2010 by The Korean Pediatric Society
Received Day: 15 Month: 9 Year: 2010
Revision Received Day: 08 Month: 10 Year: 2010
Accepted Day: 26 Month: 10 Year: 2010
Print publication date: Month: 12 Year: 2010
Electronic publication date: Day: 31 Month: 12 Year: 2010
Volume: 53 Issue: 12
First Page: 1012 Last Page: 1017
ID: 3021727
PubMed Id: 21253316
DOI: 10.3345/kjp.2010.53.12.1012

Clinical outcome of transcatheter closure of patent ductus arteriosus in small children weighing 10 kg or less
Young A Park, M.D.A1
Nam Kyun Kim, M.D.A1
Su-Jin Park, M.D.A1
Bong Sic Yun, M.D.A1
Jae Young Choi, M.D.A1
Jun Hee Sul, M.D.A1
Division of Pediatric Cardiology, Severance Cardiovascular Hospital, Yonsei University Health System, Seoul, Korea.
Correspondence: Corresponding author: Jae Young Choi, M.D. Division of Pediatric Cardiology, Severance Cardiovascular Hospital, Yonsei University Health System, 250 Seongsanno, Seodaemun-gu, Seoul 120-752, Korea. Tel: +82.2-2228-8473, Fax: +82.2-312-9538,


Transcatheter closure is widely considered as treatment of choice for patients diagnosed with patent ductus arteriosus (PDA). Since the first experience of the transcatheter occlusion of PDA by Porstmann et al. in 19671), technical improvements over the years have increased the proportion of patients who undergo successful transcatheter closure2, 3). Despite the advancement in the procedure, there are limitations in transcatheter closure of PDA in small children. There is the difficulty in advancing the tighter curves through the right heart with a large tubular sheath in small children4). Left pulmonary artery stenosis due to protrusion of device into the left pulmonary artery has been detected with the greater frequency in the smaller children5-7). The procedure was generally recommended only for children weighing over 7 to 8 kg because the size of the patients' femoral vessel was relatively smaller than the size of the required delivery system. In the past when a larger device was used, the procedure was only recommended for patients weighing over 10 to 12 kg8). We reviewed our experience to determine the efficacy and safety of transcatheter PDA closure in infants weighing less than 10 kg, with regard to rates of success and complications.

Materials and methods
1. Subjects

A total of 314 patients underwent transcatheter occlusion of PDA at Severance Cardiovascular Hospital from January, 2003 to December, 2009. Among them, 115 (37%) patients (male 49, female 66), weighing less than 10 kg, were enrolled in this study. We retrospectively analyzed medical records, echocardiographic findings, angiographic findings, hemodynamic data and follow-up results of these patients.

2. Echocardiographic and cardiac catheterization parameters

After confirming left to right shunting through the PDA, the size of PDA was measured on color Doppler echocardiography. The left ventricular end-diastolic dimension (LVEDD) was measured in each patient on M-mode echocardiogram. Hemodynamic studies were performed, and the ratio of pulmonary blood flow to systemic flow (Qp/Qs ratio) was obtained in each patient during cardiac catheterization. Aortograms were obtained in the right anterior oblique 30 degree and lateral view. The maximum diameter of the narrowest portion of the ductus was measured on frozen image and balloon occlusion sizing was performed, if needed. The residual shunt was identified by aortogram, 10 to 15 minutes after the implantation of the device.

3. Follow-up protocol

Chest X-ray and transthoracic echocardiography were conducted at 24 hours after the procedure to evaluate the shape and position of the device. The patients underwent clinical evaluation and echocardiography at 1 week, 1, 3, 6 and 12 months after the procedure and then annually thereafter. All patients were followed according to this protocol. Major complications investigated during the research included failure of device implantation, embolization of device, residual shunt, significant obstruction of aortic arch or left pulmonary artery, infective endocarditis and massive blood loss. Mild narrowing (peak velocity under the 1.5 m/sec) of left pulmonary artery or aorta and transient weak arterial pulse were regarded as minor complications. A peak velocity over the 1.5 m/sec of the left pulmonary artery or descending aorta was considered as acquired stenosis. The difference in the LVEDD before and after PDA closure was evaluated.

4. Statistical analysis

All data are expressed as mean±standard deviation. A P-value less than 0.05 was considered as statistically significant. Comparisons of mean LVEDD between before and after procedure were done using the paired T-test.

1. Characteristics of subjects

The patients' mean age was 9.1±5.9 months (range: 1-36 months), 49 were male and 66 were female, the mean weight was 7.6±1.8 kg (range: 3.2-10 kg). The mean diameter of PDA was 3.2±1.4 mm (range: 1.2 to 8 mm), the mean pulmonary blood flow to systemic flow (Qp/Qs) ratio was 2.0±0.9, and the mean fluoroscopic time was 13.4±3.8 minutes. The mean procedure time was 48.6±23.0 minutes (range: 12 to 115 minutes) (Table 1). The patients who were performed concomitant procedure such as percutaneous transluminal angioplasty (PTA) or percutaneous pulmonary valve angioplasty (PPV) have also been included in the study. PDA was presented as an isolated lesion in 75 (63%) patients, associated heart lesions were as follows: ventricular septal defect (VSD, n=13), atrial septal defect (ASD, n=11), coarctation of aorta (CoA, n=9), congenital aortic valve stenosis (AS, n=3), hypoplastic left pulmonary artery (n=3) and endocardial cushion defect (n=1). Some patients had one or more comorbidities (Table 2). Four patients had Down syndrome.

2. Results of the procedures

Of the 115 patients, the device was successfully deployed in 114 patients (99%). COOK Detachable Coil® (COOK Medical Inc, Bloomington, IN, USA) (n=2, 2%), Nit-Occlud® (PFM AG, Cologne, Germany) (n=60, 52%) and Amplatzer duct occluder® (ADO, AGA Medical Corp., Plymouth, MN, USA) (n=53, 46%) were used (Fig. 1). Coils were favored in cases of a rather small ductus, and in cases of moderate to large ductus, ADO was used.

Sixty patients (52%) had increased LVEDD and 41 patients showed normalization at 1-week echocardiographic follow-up. The LVEDD had decreased from a mean of 31.2±4.7 to 28.8±4.6 mm at 1-month follow-up. The mean systolic pulmonary artery pressure was 34.6±1.4 mmHg (range: 15 to 85 mmHg). Pulmonary hypertension, evaluated during cardiac catheterization, was defined as pulmonary artery systolic pressure more than 40 mmHg9). Thirty-four patients had pulmonary hypertension. Pulmonary hypertension, evaluated using TR jet pressure and septal configuration on echocardiography, regressed in all 34 patients during follow-up. Among them, 11 patients had severe pulmonary hypertension with pulmonary artery systolic pressure of more than 60 mmHg. The clinical characteristics and treatment results of these patients are summarizes in Table 3. Most of them presented with large PDA, and seven patients had associated heart lesions; 2 had VSD, 2 had ASD, 1 had CoA and 1 had AS. Immediately after the procedure, 5 patients showed normalization of pulmonary artery pressure. Five patients showed normalization of pulmonary artery pressure at 1-month echocardiographic follow-up and the remaining patient showed normalization at 3-month follow-up.

3. Failure

Failure occurred in a 3-month-old infant weighting 5.8 kg with 4 mm ductus. The patient was also diagnosed as atrial septal defect and coarctation of aorta. Initially, the 6/4 ADO device was successfully deployed in this patient and was observed in the intensive care unit. However, position of device was unstable on follow-up echocardiography after one day. As a result, the patient was then referred for surgery.

4. Complication

The mean follow-up duration was 21.0±19.6 months (range: 3 to 82 months). Of the 114 patients with successful deployment of a device, residual shunt was noted in one patient at 3-year echocardiographic follow-up. The patient was a 3-month-old infant weighing 7.7 kg with 3 mm ductus. The PDA was closed using 6×5 mm Nit-Occlud®(pfm AG, Köln, Germany). There still remained a very small residual shunt of PDA at his last echocardiographic follow-up, 3 years after the procedure. There were no complications related to vascular access, hemolysis and massive blood loss in any of the patient. However, in two patients, after the implantation of the ADO, mild narrowing of descending aorta was noted. One of the patients, 1 month-old boy, weighing 3.2 kg, underwent transcatheter closure using 6/4 mm ADO. A peak velocity on Doppler echocardiography after the procedure was 1.5 m/sec, but the echocardiography revealed progressive narrowing of the aorta, resulting in a peak velocity ranging from 3.0 to 3.8 m/sec during follow-up at 2 months. PTA was performed for narrowing of the aorta 3 months after the initial intervention. Aortogram showed a significant decrease in peak velocity of aorta from 3.8 m/sec to 1.5 m/sec. The other patient was a 4 month-old girl, weighing 4.2 kg with an 8mm duct and the PDA was closed using 6/4 mm ADO. After the procedure, on the echocardiography, a peak velocity of 2.0 m/sec was seen. On the follow-up echocardiography after 12 months, a peak velocity of 1.9 m/sec was seen. These patients are under close observation at outpatient clinic without further intervention so far. Three patients showed mild narrowing of left pulmonary artery, but their peak velocity on left pulmonary artery only slightly increased (range: 1.3 m/sec to 1.5 m/sec). After the procedure, 2 patients had transient weak pulse on femoral artery, which was managed by continuous infusion of heparin, and they all recovered their femoral artery pulse tension the next day (Table 4).


PDA occurs in 5-10% of all congenital heart defects10). Once the diagnosis of the uncomplicated PDA is established, closure is recommended by surgery or catheter occlusion to avoid pulmonary overflow and prevent infective endocarditis10, 11). Transcatheter closure of PDA has been the mainstay of treatment in children and adults12). Fortescue et al. presented retrospective case series of 1808 patients with transcatheter closure of PDA in a report published in 2010. Overall PDA closure rate was 94 percent and major adverse events were 1.5 percent11). There have been only a few minor complications compared with the initial interventional data13, 14). Nevertheless, procedure-associated complications have been still described in different age groups, and they are relatively major in infants4-6). Information is also inadequate regarding safety and feasibility of transcatheter closure in infants15, 16). Few studies have investigated their usefulness in children weighing less than 10 kg17, 18).

Our current study is mainly focused on the clinical results in using either Nit-Occlud®, ADO or COOK Detachable Coil® for the transcatheter closure of PDA in children weighing less than 10 kg. Completely successful closure of PDA was achieved in 98% of the patients19). This confirms the safety of transcatheter closure of PDA in children weighing less than 10 kg. In previous report by Kim et al.2), mean age of 150 patients was 38 months and mean body weight was 15 kg in our center; however, current study focused on younger and smaller patients.

The incidence of PDA is higher in premature infants10). Jung20) reported that incidence in preterm infants with persistent patency of the ductus arteriosus is about 16 times more than full term infants. Delayed closure of the hemodynamically significant patent ductus arteriosus is related to the development of various morbidity in preterm infants21). Transcatheter closure of PDA can be considered as treatment option to avoid the risk of surgical ligation in these patients22).

The important factors for successful procedure are vascular accessibility, morphology of ductus, availability of device, and imaging modality. First of all, the vascular accessibility is an important variable. There is a high potential of thrombosis formation or interruption in femoral vessel related to vascular access, because the diameter of the femoral vessel in infants is small. Also, a more invasive approach such as cut-down of femoral vessel may be necessary during catheterization. Second, in addition to measurement of the diameter, the morphology of the ductus should also be assessed by echocardiography before procedure is performed. With careful regard to anatomic details and cautious planning of device deployment, procedural risks can be minimized and success rates can be maximized. Third, the miniaturization of device is also an important variable. Catheter manipulations within the heart have to be minimized to prevent injury and to avoid causing arrhythmias and hemodynamic instability. There is also the possibility of narrowing of adjacent aorta from protrusion of the aortic retention disc3). Further development in device can potentially improve the scope of catheter closure for ducts in preterm infants. Recently, Amplatzer duct occluder (ADO) II, a new device designed by the AGA Medical (Golden Valley, Minnesota) show successful PDA closure and decrease the risk in small patients23). Finally, the imaging modality is also an important factor. Because it is difficult for very small infants to maintain their vital signs such as body temperature and respiration without assistance, the procedure by the bedside maybe more suitable than at the catheterization laboratory. If portable imaging modality can be used during procedures, the risk of transcatheter closure for PDA will decrease in small infants.

Surgical ligation of PDA remains the treatment of choice in small children. Surgical morbidity, cost, and hospital length of stay have been decreased by the technique of video-assisted thoracoscopic ligation of the PDA24). However, through our current study transcatheter closure for PDA of infants has somewhat established its safety and efficacy. Carefully selected group of infants may be offered transcatheter closure as a treatment option with great caution.

With careful planning and improvement of imaging modality, transcatheter closure for PDA can be successfully accomplished in preterm infants. Furthermore, transcatheter closure of PDA can be accepted as the gold standard of treatment in patients of PDA weighing less than 10 kg in the near future soon.


The authors are grateful to Professor John Linton, International Health Care Center, Yonsei University Health System for language consultation.

1. Porstmann W,Wierny L,Warnke H. Closure of persistent ductus arteriosus without thoracotomyGer Med MonYear: 1967122592616045537
2. Kim Y,Choi JY,Lee JK,Sul JH,Lee SK,Park YH,et al. Mid-term result of the transcatheter occlusion of patent ductus arteriosus with Duct-Occlud device and procedure-related problemsKorean J PediatrYear: 2004473643
3. Jang GY,Son CS,Lee JW,Lee JY,Kim SJ. Complications after transcatheter closure of patent ductus arteriosusJ Korean Med SciYear: 20072248449017596658
4. Fischer G,Stieh J,Uebing A,Grabitz R,Kramer HH. Transcatheter closure of persistent ductus arteriosus in infants using the Amplatzer duct occluderHeartYear: 20018644444711559687
5. Al-Ata J,Arfi AM,Hussain A,Kouatli AA,Jalal MO. The efficacy and safety of the Amplatzer ductal occluder in young children and infantsCardiol YoungYear: 20051527928515865830
6. Butera G,De Rosa G,Chessa M,Piazza L,Delogu A,Frigiola A,et al. Transcatheter closure of persistent ductus arteriosus with the Amplatzer duct occluder in very young symptomatic childrenHeartYear: 2004901467147015547030
7. Bilkis AA,Alwi M,Hasri S,Haifa AL,Geetha K,Rehman MA,et al. The Amplatzer duct occluder: experience in 209 patientsJ Am Coll CardiolYear: 20013725826111153748
8. Rashkind WJ,Mullins CE,Hellenbrand WE,Tait MA. Nonsurgical closure of patent ductus arteriosus: clinical application of the Rashkind PDA Occluder SystemCirculationYear: 1987755835923545534
9. McQuillan BM,Picard MH,Leavitt M,Weyman AE. Clinical correlates and reference intervals for pulmonary artery systolic pressure among echocardiographically normal subjectsCirculationYear: 20011042797280211733397
10. Schneider DJ,Moore JW. Patent ductus arteriosusCirculationYear: 20061141873188217060397
11. Fortescue EB,Lock JE,Galvin T,McElhinney DB. To close or not to close: the very small patent ductus arteriosusCongenit Heart DisYear: 2010535436520653702
12. Celiker A,Aypar E,Karagoz T,Dilber E,Ceviz N. Transcatheter closure of patent ductus arteriosus with Nit-Occlud coilsCatheter Cardiovasc IntervYear: 20056556957615973674
13. Jan SL,Hwang B,Fu YC,Chi CS. Transcatheter closure of a large patent ductus arteriosus in a young child using the Amplatzer duct occluderPediatr CardiolYear: 20052670370616378211
14. Choi DY,Kim NY,Jung MJ,Kim SH. The results of transcatheter occlusion of patent ductus arteriosus: success rate and complications over 12 years in a single centerKorean Circ JYear: 20104023023420514333
15. Magee AG,Huggon IC,Seed PT,Qureshi SA,Tynan M. Transcatheter coil occlusion of the arterial duct; results of the European RegistryEur Heart JYear: 2001221817182111549304
16. Kim SY,Lee SH,Kim NK,Choi JY,Sul JH. A new strategy for transcatheter closure of patent ductus arteriosus with recent-generation devicesKorean J PediatrYear: 200952488493
17. Faella HJ,Hijazi ZM. Closure of the patent ductus arteriosus with the amplatzer PDA device: immediate results of the international clinical trialCatheter Cardiovasc IntervYear: 200051505410973018
18. Sivakumar K,Francis E,Krishnan P. Safety and feasibility of transcatheter closure of large patent ductus arteriosus measuring >or=4 mm in patients weighing <or=6 kgJ Interv CardiolYear: 20082119620318312306
19. Wang JK,Wu MH,Lin MT,Chiu SN,Chen CA,Chiu HH. Transcatheter closure of moderate-to-large patent ductus arteriosus in infants using Amplatzer duct occluderCirc JYear: 20107436136420032563
20. Jung JW. Recent strategies and outcomes of transcatheter closure for patent ductus arteriosusKorean Circ JYear: 20104021621820514330
21. Lee HJ,Sim GH,Jung KE,Lee JA,Choi CW,Kim EK,et al. Delayed closure effect in preterm infants with patent ductus arteriosusKorean J PediatrYear: 20085110651070
22. Francis E,Singhi AK,Lakshmivenkateshaiah S,Kumar RK. Transcatheter occlusion of patent ductus arteriosus in pre-term infantsJACC Cardiovasc IntervYear: 2010355055520488412
23. Thanopoulos BV,Eleftherakis N,Tzannos K,Stefanadis C,Giannopoulos A. Further experience with catheter closure of patent ductus arteriosus using the new Amplatzer duct occluder in childrenAm J CardiolYear: 20101051005100920346321
24. Her K,Lee JW,Shin HK,Won YS. Video-Assisted Thoracoscopic Surgery for Patent Ductus ArteriosusKorean Circ JYear: 200434978982

Article Categories:
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Keywords: Patent ductus arteriosus, Infant, Catheterization, Device, Closure.

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