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All issues > Volume 60(6); 2017

Shin, Lee, Lee, Choi, and Hong: Individualized ibuprofen treatment using serial B-type natriuretic peptide measurement for symptomatic patent ductus arteriosus in very preterm infants

Individualized ibuprofen treatment using serial B-type natriuretic peptide measurement for symptomatic patent ductus arteriosus in very preterm infants

Jeonghee Shin, MD, Eun Hee Lee, MD, Jee Hyun Lee, MD, PhD, Byung Min Choi, MD, PhD, Young Sook Hong, MD, PhD
Corresponding author: Byung Min Choi, MD, PhD. Department of Pediatrics, Korea University Ansan Hospital, Korea University College of Medicine, 123 Jeokgeum-ro, Danwon-gu, Ansan 15355, Korea. Tel: +82-31-412-6557, Fax: +82-31-405-8591, cbmin@korea.ac.kr
Received November 22, 2016       Revised March 13, 2017       Accepted April 11, 2017
Abstract
Purpose
Purpose
Plasma level of B-type natriuretic peptide (BNP), an emerging, sensitive, and specific biomarker of hemodynamically significant patent ductus arteriosus (PDA), rapidly decreases in infants receiving cyclooxygenase inhibitors for ductal closure. We investigated the usefulness of serial BNP measurement as a guide for individual identification of early constrictive responses to ibuprofen in preterm infants with symptomatic PDA (sPDA).
Methods
Methods
Before March 2010, the standard course of pharmacological treatment was initiated with indomethacin (or ibuprofen) and routinely followed by 2 additional doses at intervals of 24 hours. After April 2010, individualized pharmacological treatment was used, starting with the first dose of ibuprofen and withholding additional ibuprofen doses if the BNP concentration was <600 pg/mL and clinical symptoms of PDA improved.
Results
Results
The BNP-guided group received significantly fewer doses of ibuprofen than the standard group did during the first course of treatment and the entire study period. The need for further doses of cyclooxygenase inhibitors and for surgical ligation was not significantly different between the 2 groups. No significant differences were seen in clinical outcomes and/or complications related to sPDA and/or pharmacological treatment.
Conclusion
Conclusion
Individualized BNP-guided pharmacological treatment may be used clinically to avoid unnecessary doses of cyclooxygenase inhibitors without increasing the ductal closure failure and the short-term morbidity related to sPDA.
Introduction
Introduction
Management of patent ductus arteriosus (PDA) including the most appropriate drug, the optimal timing and duration and the proper dosing regimens for pharmacological approach is still a matter of debate. Traditionally, 3 doses of ibuprofen or indomethacin have been given at regular intervals. However, ductal closure is observed by the time the second or third dose is given1,2), hence, some investigators have used echocardiography-guided medical treatment to limit unnecessary exposure to cyclooxygenase inhibitors in preterm infants with PDA3,4,5).
Plasma B-type natriuretic peptide (BNP) measurement have been proposed as a tool for the prediction and diagnosis of symptomatic PDA (sPDA) in preterm infants, especially using commercially available bedside testing kit6,7,8,9). A recent systematic review evaluating the diagnostic accuracy of BNP for hemodynamically significant PDA (hsPDA) suggests that plasma BNP measurement seems to be an accurate test for identifying hsPDA in preterm infants10).
We investigated the usefulness of serial BNP measurement as a guide for individual identification of early constrictive responses to ibuprofen. We hypothesized that BNP-guided pharmacological treatment can reduce the number of ibuprofen doses without affecting its efficacy and safety in very preterm infants with sPDA.
Materials and methods
Materials and methods
This observational study was conducted in the neonatal intensive care unit (NICU) at Korea University Ansan Hospital from April 2008 to March 2014. Very preterm infants of <32 weeks gestation, who required respiratory support, received initial screening echocardiography within 24 hours of birth and were monitored for clinical symptoms of PDA.
Details of echocardiographic studies and diagnosis and mangement of sPDA in this study have been reported previously6,8). The clinical signs of hsPDA was based on the following features: (1) the presence of a systolic or continuous murmur, (2) a bounding pulse or a hyperactive precordial pulse, (3) difficulty in maintaining the blood pressure, i.e., hypotension (the lower limit of normal mean arterial pressure was regarded to corrected gestational age) without response to loading fluid and infusion of dopamine, (4) a worsening ventilator status, and (5) chest radiographic evidence, i.e., pulmonary congestion or cardiomegaly (a cardiothoracic ratio >60%) with increased pulmonary flow.
sPDA was defined as the presence of 2 of these 5 signs with the confirmation of a large left to right ductal flow by color-flow Doppler echocardiography. The policy of management to PDA in our NICU was that cyclooxygenase inhibitor was administered intravenously after confirming the diagnosis of sPDA. If the sPDA failed to close with at least 2 courses of cyclooxygenase inhibitors or if pharmacological treatment was contraindicated, surgical ligation was performed immediately.
During Era 1 (before March 2010), the standard course of pharmacological treatment was initiated with indomethacin (or ibuprofen) and routinely followed by 2 additional doses of indomethacin (or ibuprofen) at intervals of 24 hours. During Era 2 (after April 2010), individualized pharmacological treatment was used, starting with the first dose of ibuprofen and witholding of additional ibuprofen doses if the BNP concentration was <600 pg/mL and clinical signs of hsPDA were improved before the next scheduled dose of ibuprofen.
Infants who received cyclooxygenase inhibitors prophylactically, who had ≥grade 3 intraventricular hemorrhage (IVH) prior to pharmacological treatment and who had congenital heart disease or other congenital disease were excluded.
Echocardiography was conducted at 72 hours after the initiation of pharmacological treatement to confirm early ductal closure after the first course of treatment. And repeated echocardiographies were conducted for evaluations of ductal closure at discharge and final ductal clousre at 3 months after discharge. The response to pharmacological treatment is defined as an improvement of clinical symptoms of PDA and a decreased or no ductal shunt by echocardiography after the first or second course of treatment.
The BNP levels were assessed using a commercial kit (Triage BNP test; Alere Triage Meterpro, San Diego, CA, USA) by a fluorescence immunoassay at the bed side9) and were measured before the first dose of pharmacological treatment and before the next scheduled dose of ibuprofen during Era 2.
BPD was defined according to the National Institutes of Health consensus definition 11). IVH was classified according to Papile et al.12). NEC was classified according to Bell's classification, modified by Kliegman and Walsh13).
Informed consents were obtained from all parents of infants included during Era 2. The study was approved by the local research ethics committee of Korea University Ansan Hospital.
The chi-square test or Fisher exact test was used to compare categorical variables and the Student t test or the Mann-Whitney rank sum U test to compare continuous variables. A P value below 0.05 was considered statistically significant.
Results
Results
Forty-seven infants in Era 1 (standard group) and 45 infants in Era 2 (BNP-guided group) were eligible for the final analysis (Fig. 1). Perinatal demographic variables were similar in the 2 groups (Table 1).
The BNP-guided group received significantly fewer doses of ibuprofen than the standard group during the first course of treatment and the entire study period (Table 2). Although the echocardiographic ductal closure rate at discharge was lower in the BNP-guided group, as compared to the standard group, there was no significant difference in the incidence of reappearance of sPDA after the first and/or second course of treatment. The need for further doses of cyclooxygenase inhibitors and the need for surgical ligation were not significantly different between the 2 groups. No significant differences were seen in clinical outcomes and/or complications related sPDA and/or pharmacological treatment, such as IVH, necrotizing enterocolitis, oliguria, bronchopulmonary dysplasia, and mortality. However, there was a significantly lower incidence of increased creatinine levels in the BNP-guided group.
The comparative efficacy and safety of the early constrictive response to cyclooxygenase inhibitors in the BNP-guided group, as compared with the standard group was determined by subanalysis for responders to the first course of treatment in both groups (Table 3). Of 38 infants who responded to the first course of treatment in the standard group, 3 infants with incomplete dosing (2 doses) due to contraindications of the medication were excluded.
Discussion
Discussion
Previous clinical trials showed that PDA treatment decisions based on serial echocardiographic assessment of ductal diameter3) or flow pattern4) was associated with reduction in total drug doses without compromising efficacy and safety. Recently, a randomized controlled clinical trial5) for echocardiography-guided medical treatment for PDA in preterm infants showed that echocardiography-guided treatment is feasible and reduces unnecessary doses of ibuprofen without increasing the reopening rate. However, coherent echocardiographic evaluation by skilled clinicians is difficult to perform routinely, and the hemodynamic effects of PDA may be difficult to determine even with typical echocardiographic features.
Plasma BNP, emerging as a sensitive and specific biomarker of sPDA, rapidly decreases in infants as a response to cyclooxygenase inhibitors for ductal closure9,10,14). Attridge et al.15) reported that BNP levels can be used as a guide for the treatment of PDA and BNP-guided treatment reduces the number of indomethacin doses during the first course of treatment without any changes in the rate of PDA closure or complications. Furthermore, our study showed that, in addition to reducing the ibuprofen doses during the first course of treatment, BNP-guided treatment can reduce the total number of ibuprofen doses during the study periods without affecting the efficacy and safety for sPDA in very preterm infants.
In our subanalysis for responders to first course of treatment (Table 3) to identify the efficacy and safety of the early constrictive response to ibuprofen in the BNP-guided group, clinical symptoms of PDA were improved earlier and BNP concentrations were rapidly decreased after the first or second dose of ibuprofen in the incomplete dosing group, as compared to the complete dosing groups. Echocardiographic early ductal closure rate (63.3%, 19 of 30) was higher in the incomplete dosing group, as compared to the complete dosing group. Three infants in the incomplete dosing group had recurrence of sPDA and received the further dose of ibuprofen after the first course of ibuprofen. Finally 2 infants required surgical ligation because the clinical symptoms were aggravated despite additional 2 and 4 doses of ibuprofen, respectively.
The incidences of early ductal closure and ductal closure at discharge were significantly lower in the incomplete dosing group and the complete dosing group in the BNP-guided group, as compared with the complete dosing group of the standard group. Nevertheless, there were no significant differences in the incidence of reappearance of sPDA, the need for a further dose of cyclooxygenase inhibitors and surgical ligation and the final ductal closure rate between the responders to first course of treatment in the BNP-guided group as compared with that of the standard group.
This is an observational study demonstrating that BNP-guided pharmacological treatment may be used clinically to avoid unnecessary doses of cyclooxygenase inhibitors. However, in addition to a cutoff level <600 pg/mL of BNP, the clinical improvement of symptoms of PDA was concurrently used for individualized pharmacological treatment of sPDA in our study. We assumed that even if the clinical symptoms of PDA are improved, the high BNP level represent that the infant still have an hsPDA and is required additional dose of medication.
Moreover, we estimated that a BNP level lower than 600 pg/mL, half value of the best cutoff BNP levels (1,100 pg/mL) for the diagnosis of sPDA in our previous study6), was used as a guide for individualized treatment. To further investigate the diagnostic utility of a rapid BNP assay for the identification of the early constrictive response to ibuprofen, the best cutoff value of BNP should be determined by the follow-up study in the BNP-guided group.
In conclusion, serial BNP measurement during the management of sPDA can be used as a guide for early constrictive responses to cyclooxygenase inhibitors. Individualized BNP-guided pharmacological treatment may be used clinically to avoid the unnecessary use of cyclooxygenase inhibitors in infants without increasing the incidence of ductal closure failure and the short-term morbidity related sPDA. A large multicenter randomized controlled trial, especially, with long-term follow-up on developmental outcomes is needed to determine if this approach should be a standard management practice for sPDA.
Acknowledgments

We thank the physicians and nursing staff working in the NICU of Korea University Ansan Hospital for their enthusiastic support and cooperation.

Notes

Conflict of interest: No potential conflict of interest relevant to this article was reported.

References
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Fig. 1
Flow diagram of study subject enrollment and responses of patent ductus arteriosus (PDA) to the first and second course of medical treatment during Era 1 (before March 2010; standard group) and Era 2 (after April 2010; BNP-guided group).
kjped-60-175-g001
Table 1
Perinatal demographic variables of standard treatment and individualized BNP-guided treatment groups
kjped-60-175-i001
Variable Standard treatment (n=47) Individualized BNP-guided treatment (n=45) P value
Gestational age (wk) 27.9±2.1 28.0±2.3 0.940
Birth weight (g) 1,019±299 1,105±369 0.225
Male sex 23 (48.9) 17 (37.8) 0.280
Cesarean section 31 (66.0) 34 (75.6) 0.312
Apgar score
 1 Minute 4 (3–6) 5 (3–6) 0.912
 5 Minutes 7 (5.5–8) 7 (5.5–8) 0.418
PROM ≥ 18 hours 6 (12.8) 12 (26.7) 0.093
Preeclampsia 14 (29.8) 7 (15.6) 0.104
Completed antenatal steroid 18 (38.3) 22 (48.9) 0.306
Surfactant treatment 43 (91.5) 45 (100) 0.117
Noninvasive ventilation at the 1st dose of treatment 5 (10.6) 5 (11.1) 0.942
Invasive ventilation at the 1st dose of treatment 42 (89.4) 40 (88.9) 0.942

Values are presented as mean±standard deviation, number of infants (%), or median (interquartile range).

BNP, B-type natriuretic peptide; PROM, premature rupture of membrane.

Table 2
Neonatal outcomes of standard treatment group and individualized BNP-guided treatment group
kjped-60-175-i002
Variable Standard treatment (n=47) Individualized BNP-guided treatment (n=45) P value
Cyclooxygenase inhibitors treatment
 Indomethacin:Ibuprofen 32:15 0:45 <0.001
 Age at the 1st dose of treatment (hr) 48.1±17.9 48.4±16.5 0.912
 Doses during the 1st course 2.9±0.4 2.0±0.8 <0.001
 Total doses during the study period 3.5±1.2 2.9±2.2 <0.001
PDA outcomes
 Response to 1st course 38 (80.9) 40 (88.9) 0.283
 Response to 2nd course 2 (4.3) 2 (4.4) 0.999
 Reappearance of symptomatic PDA 3 (6.4) 5 (11.1) 0.481
 Need for further dose of treatment 2 (4.3) 7 (15.6) 0.087
 Need for surgical ligation 10 (21.3) 7 (15.6) 0.480
Echocardiographic examination
 Early ductal closure 28 (59.6) 20 (44.4) 0.146
 Ductal closure at discharge 46 (97.9) 38 (84.4) 0.029
 Final ductal closure after discharge 46 (97.9) 45 (100) 0.999
Clinical outcomes
 Duration of invasive ventilation (day) 12 (5–39) 9 (3–31) 0.444
 Duration of hospital (day) 76 (60–99) 76 (55–113) 0.553
 IVH, ≥grade 3 8 (17.0) 2 (4.4) 0.091
 NEC, ≥grade II 2 (4.3) 2 (4.4) 0.999
 Oliguria, <1 mL/kg/hr 2 (4.3) 1 (2.2) 0.999
 Creatinine, ≥1.2 mg/dL 19 (48.7) 8 (19.0) 0.005
 BPD, ≥moderate 24 (51.1) 16 (35.6) 0.134
 Mortality 2 (4.3) 2 (4.4) 0.999

Values are presented as mean±standard deviation, number of infants (%), or median (interquartile range).

BNP, B-type natriuretic peptide; PDA, patent ductus arteriosus; IVH, intraventricular hemorrhage; NEC, necrotizing enterocolitis; BPD, bronchopulmonary dysplasia.

Reappearance of sPDA after the first and/or second course of treatment; Need for further dose of cyclooxygenase inhibitors after the first and/or second course of treatment; Early ductal closure at 72 hours after the first dose of medical treatment.

Table 3
Outcomes of the responders to the first course of pharmacological treatment in the standard and individualized BNP-guided groups
kjped-60-175-i003
Variable Standard treatment Individualized BNP-guided treatment
1st course of cyclooxygenase inhibitors 1st course of ibuprofen 2nd course of ibuprofen
Complete dosing Incomplete dosing Complete dosing
3 Doses (n=35) 1 Dose (n=13) 2 Doses (n=17) 3 Doses (n=10) >3 Doses (n=5)
Cyclooxygenase inhibitors treatment
 Age at the 1st dose of treatment (hr) 49.1±18.1 52.4±11.0 47.3±10.9 53.9±26.7 31.2±6.3
 Doses during the 1st course 3 1 2 3 3
 Total doses during the study period 3.1±1.9 1.4±1.4 2.4±1.1 3.3±0.9 7.6±2.1
PDA outcomes
 Reappearance of symptomatic PDA 2 (5.7) 1 (7.7) 2 (11.8) 2 (20) -
 Need for further dose of cyclooxygenase inhibitors 2 (5.2) 1 (7.7) 2 (11.8) 1 (10) 3 (60)
 Need for surgical ligation 2 (5.2) 0 2 (11.8) 1 (10) 4 (80)
Echocardiographic examination
 Early ductal closure 27 (77.1) 10 (76.9) 9 (52.9) 1 (10) 0
 Ductal closure at discharge 35 (100) 11 (84.6) 15 (88.2) 7 (70) 4 (80)
 Final ductal closure after discharge 35 (100) 13 (100) 17 (100) 10 (100) 5 (100)
BNP concentrations (pg/mL)
 Before the 1st dose - 2,085±1,162 2,341±1,308 2,093±1,185 3,070±1,152
 After 24 hours after 1st dose - 201±193 654±937 1,182±1,129 3,200±1,769
 After 24 hours after 2nd dose - - 145±146 537±336 2,938±2,172
 After 24 hours after 3rd dose - - - 274±198 2,919±1,976

Values are presented as mean±standard deviation or number of infants (%),

BNP, B-type natriuretic peptide; PDA, patent ductus arteriosus.

Reappearance of sPDA after the first course of ibuprofen; Further doses of ibuprofen after the first or second course of ibuprofen; Early ductal closure at 72 hours after the first dose.

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