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Title
Hypotension following patent ductus arteriosus ligation: the role of adrenal hormones.

Permalink
https://escholarship.org/uc/item/76g1z28h

Journal
The Journal of pediatrics, 164(6)

ISSN
0022-3476

Authors
Clyman, Ronald I
Wickremasinghe, Andrea
Merritt, T Allen
et al.

Publication Date
2014-06-01

DOI
10.1016/j.jpeds.2014.01.058
 
Peer reviewed

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Hypotension following patent ductus arteriosus ligation: the role
of adrenal hormones

Ronald I. Clyman, MD1, Andrea Wickremasinghe, MD1, T. Allen Merritt, MD, MHA2, Tabitha
Solomon, MD2, Patrick McNamara, MD3, Amish Jain, MD3, Jaideep Singh, MD, MPH4,
Alison Chu, MD4, Shahab Noori, MD5, Krishnamurthy Sekar, MD5, Pascal M. Lavoie, MD,
PhD6, Joshua T. Attridge, MD7, Jonathan R. Swanson, MD7, Maria Gillam-Krakauer, MD8,
Jeff Reese, MD8, Sara DeMauro, MD, MSCE9, Brenda Poindexter, MD10, Sue Aucott, MD11,
Monique Satpute, MD11, Erika Fernandez, MD12, and Richard J. Auchus, MD13 on behalf of
the Patent Ductus Arteriosus Ligation/Hypotension Trial Investigators*

1Departments of Pediatrics and 1Cardiovascular Research Institute, University of California San
Francisco

2Department of Pediatrics, Loma Linda University, Loma Linda, CA

3Department of Pediatrics, Hospital for Sick Children, Toronto, Canada

4Department of Pediatrics, University of Chicago, Chicago, IL

5Department of Pediatrics, University of Oklahoma, Oklahoma City, OK

6Department of Pediatrics, Children’s & Women’s Health Centre of British Columbia, Vancouver,
Canada

7Department of Pediatrics, University of Virginia, Charlottesville, VA

8Department of Pediatrics, Vanderbilt University, Nashville, TN

9Department of Pediatrics, Children’s Hospital of Philadelphia and University of Pennsylvania
Perelman School of Medicine, Philadelphia, PA

10Department of Pediatrics, Indiana University, Indianapolis, IN

11Department of Pediatrics, Johns Hopkins University, Baltimore, MD

12Department of Pediatrics, University of New Mexico, Albuquerque, NM

13Department of Pediatrics, Department of Medicine, University of Michigan, Ann Arbor, MI

© 2014 Mosby, Inc. All rights reserved.

Corresponding author: Ronald I. Clyman, M.D., Box 0544, HSW 1408, University of California, San Francisco, 513 Parnassus Ave,
San Francisco, CA 94143-0544, Phone: (415) 476-4462, Fax: (415) 502-2993, clymanr@peds.ucsf.edu.
*A list of members of the PDA Ligation/Hypotension Trial Investigators is available at www.jpeds.com (Appendix).
Reprint request author: Ronald I. Clyman, M.D.

The authors declare no conflicts of interest.

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NIH Public Access
Author Manuscript
J Pediatr. Author manuscript; available in PMC 2015 June 01.

Published in final edited form as:
J Pediatr. 2014 June ; 164(6): 1449–1455.e1. doi:10.1016/j.jpeds.2014.01.058.

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Abstract

Objective—To test the hypothesis that an impaired adrenal response to stress might play a role in
the hypotension that follows patent ductus arteriosus (PDA) ligation.

Study design—We performed a multicenter study of infants born at <32 weeks gestation who
were about to undergo PDA ligation. Serum adrenal steroids were measured three times: before

and after a cosyntropin (1.0 microgram/kg) stimulation test (performed prior to the ligation), and

at 10–12 hours after the ligation. A standardized approach for diagnosis and treatment of

postoperative hypotension was followed at each site. A modified Inotrope Score (1 x dopamine

(μg/kg/min) + 1 x dobutamine) was used to monitor the catecholamine support an infant received.

Infants were considered to have catecholamine-resistant hypotension if their highest Inotrope

Score was >15.

Results—Of 95 infants enrolled, 43 (45%) developed hypotension and 14 (15%) developed
catecholamine-resistant hypotension. Low post-operative cortisol levels were not associated with

the overall incidence of hypotension following ligation. However, low cortisol levels were

associated with the refractoriness of the hypotension to catecholamine treatment. In a multivariate

analysis: the odds ratio for developing catecholamine-resistant hypotension was OR=36.6,

CI=2.8–476, p=0.006. Low cortisol levels (in infants with catecholamine-resistant hypotension)

were not due to adrenal immaturity or impairment; their cortisol precursor concentrations were

either low or unchanged and their response to cosyntropin was similar to infants without

catecholamine-resistant hypotension.

Conclusion—Infants with low cortisol concentrations following PDA ligation are likely to
develop postoperative catecholamine-resistant hypotension. We speculate that decreased adrenal

stimulation, rather than an impaired adrenal response to stimulation, may account for the

decreased production.

Keywords

cortisol; hydrocortisone; surgery; dopamine; newborn

Between 25-to-35% of preterm infants having surgical ligation of the patent ductus

arteriosus (PDA) develop systemic hypotension and hemodynamic deterioration

approximately 8-to-14 hours after the surgical procedure (1–3). The factors responsible for

postoperative hypotension are unclear. Retrospective studies have not identified differences

in the surgical, anesthetic, or intraoperative fluid management among the infants who

develop postoperative hypotension (1, 4). Indices of impaired myocardial performance are

often observed prior to the development of hypotension (5–8), and prophylactic

administration of milrinone, begun shortly after the surgery, appears to reduce the incidence

of postoperative cardiorespiratory instability. However, some infants continue to develop

post-ligation hypotension despite early treatment of low ventricular output with milrinone

(7, 8).

Treatment with volume expanders and catecholamine infusions can usually correct the post-

ligation hypotension. However, approximately 15% of infants develop catecholamine-

resistant hypotension. In these infants, a “low stress-dose” of hydrocortisone can normalize

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their blood pressure (3, 5, 6). Currently, there is no information about the ability of the

premature infant to increase cortisol production after surgery.

Preterm infants are known to have an altered adrenal response to hypotension and postnatal

stress during the first week of life: in 30% the cortisol levels are increased with postnatal

stress (9, 10) but in 70% the levels are either similar to or lower than those of healthy infants

(11–15). The low cortisol concentrations do not appear to be due to low corticosteroid

binding globulins (16), Nor are they explained by a diminished pituitary response to stress in

hypotensive preterm infants because corticotropin releasing hormone causes a robust

increase in ACTH, but only a blunted cortisol response in the same infants (14, 17–19).

These findings suggest that the premature adrenal gland might not respond appropriately to

elevated ACTH levels (15, 20, 21). Sick preterm infants have high circulating concentrations

of 17-hydroxyprogesterone, 11-deoxycortisol, and cortisone. This pattern suggests that the

activity of the enzymes that convert cortisol precursors to cortisol or from cortisol to

cortisone may be altered (22–25). Although adrenal function usually returns to normal by 14

days after birth (17, 18), several reports suggest that the abnormal accumulation of cortisol

precursors and impaired production of cortisol may persist for several weeks in preterm

infants (15, 20).

Two reports suggest that infants at risk for developing peri-operative hypotension may have

depressed cortisol responses to cosyntropin (ACTH1–24) stimulation (8, 26). Therefore, we

designed a prospective study to test the following hypotheses: 1) infants who develop

hypotension after PDA ligation have a diminished post-operative cortisol response

compared with infants who are normotensive; 2) infants who develop catecholamine-

resistant hypotension have the most diminished cortisol response and have a limited ability

to convert cortisol precursors to cortisol (or a more rapid conversion of cortisol to

cortisone); and, 3) preoperative measurements of cortisol precursors or metabolites (before

and after cosyntropin stimulation) will be able to predict which infants are likely to develop

post-ligation cardiopulmonary deterioration.

Methods

Between May 2009, and February 2012, 95 infants were enrolled at 12 sites with

Institutional Review Board approval and parental consent. Infants were eligible for the study

if they were: (1) delivered between 231/7 – 31 6/7 weeks gestation; and (2) scheduled for

PDA ligation. The criteria to determine the need for ligation were not standardized between

the centers. The decision to perform the ligation was made by the clinical care teams. Infants

were excluded from the trial if they had: (1) major or lethal congenital or chromosomal

abnormalities; (2) congenital heart defects (excluding patent ductus arteriosus and small

atrial or ventricular septal defects); or (3) had received hydrocortisone or dexamethasone

within 5 days of the planned surgery.

The PDA left-to-right shunt was scored (moderate or large) with an echocardiogram prior to

ligation as previously described (27). The following clinical measures of cardiorespiratory

status were recorded prospectively (starting 24 hour prior to surgery, until 96 hours after

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surgery): arterial blood gases, blood pressures, heart rates, hematocrits, number of fluid

boluses, and the amount, duration and type of vasopressor support, and the anesthetics,

analgesics and sedatives the infants received.

Steroid Measurements

Three serum samples (0.7 ml blood/sample) were collected for steroid metabolite

measurements. Two samples were obtained no more than 48 hours before the surgery as part

of a cosyntropin (ACTH1–24) stimulation test: 1) a baseline value, and 2) a value obtained

60 minutes after intravenous cosyntropin (1.0 microgram/kg). Previous studies found that

90% of healthy preterm infants have normal stimulated cortisol responses 60 minutes after

this dose of cosyntropin whereas sick, ventilated infants have significantly lower cortisol

responses (13, 15, 28).

A third serum sample for steroid metabolites was obtained between 10–12 hours after the

surgery. This time-point was chosen because post-ligation hypotension usually is present by

8-to-14 hours after the ligation (1–3). (Note: the third sample was collected before the first

hydrocortisone dose, if hydrocortisone was started before the 10–12 hour sample time point.

Steroid assays were performed by ultra-performance liquid chromatography tandem mass

spectrometry as previously described (29). Cortisol, cortisone, 17-hydroxyprogesterone, 11-

deoxycortisol, 21-deoxycortisol, deoxycorticosterone, corticosterone, progesterone, and

androstenedione were assayed simultaneously in a single run. Values measured by this

technique have correlation coefficients between 0.8 and 0.99 when compared with those

obtained by radioimmunoassy (30).

Serum cortisol concentrations had a skewed distribution in our population. Therefore, we

expressed the cortisol values as both absolute and log (base 10) transformed values. Because

the adequacy of an infant’s cortisol response for maintaining blood pressure depends on both

the circulating cortisol level and the stress experienced by the infant, we defined a

“decreased cortisol response” after ligation as one in which the cortisol level was in the

lower-third (tertile) of the postoperative cortisol concentrations found in the study

population. In our study, all infants underwent the same operation. Therefore, by using this

definition we could match the appropriateness of the cortisol response to the level of stress

that the infant was experiencing.

Surgical and Postoperative Management

All infants received a muscle relaxant (pancuronium, rocuronium, vecuronium or

cisatracurium) and fentanyl anesthesia (8 infants also received ciboflurane, propofol, or

ketamine). Left mid-axillary thoracotomies were performed through the fourth intercostal

space and the ductus were ligated using metal clips. Morphine or fentanyl infusions were

begun after the ligation and tapered over 6 to 24 hours depending on an infant pain profile

score. At one study site (7 infants), a milrinone infusion was started shortly after the ligation

as part of an institutional protocol designed to prevent postoperative hypotension (7, 8).

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Management of Hypotension in Study Infants

Because vasopressor management of hypotension was the primary outcome, the hypotension

treatment regimen needed to be directive rather than at the discretion of the clinicians. A

standardized approach that determined when volume expanders and vasopressors would be

initiated, and the rate at which they would be increased, was agreed upon by all participating

centers. Blood pressure (BP) was measured directly with an arterial line and transducer, or

noninvasively using the oscillometric method. An arterial line and transducer were used to

measure blood pressure continuously in all infants receiving catecholamine infusions or

hydrocortisone for blood pressure support.

Hypotension was defined as “mean BP less than the 3rd percentile for postmenstrual age (31,

32) that lasted more than 15 minutes”. Operationally this meant that infants were considered

to be hypotensive, and require treatment for their hypotension, if their mean blood pressure

was less than [(postmenstrual age in mm Hg) − (3 to 4 mm Hg)].

When infants failed to maintain an adequate BP (defined as “BP greater than the

hypotensive range”), no more than 3 fluid boluses (isotonic saline 10 mL/kg per dose) could

be given initially to correct presumed hypovolemia. If the fluid boluses were unsuccessful in

maintaining an adequate BP, catecholamine support could be added. The choice of

dopamine or dobutamine was left to the clinical neonatologist. Infusion of dopamine or

dobutamine was started at a rate of 5 μg/kg/min. The dose could be increased by 2.5

μg/kg/min every 15 minutes until an adequate BP was achieved. Combinations of dopamine

and dobutamine could also be used.

We used a modified Inotrope Score (33) to measure the amount of catecholamine support

that an infant received to maintain an adequate BP. The modified Inotrope Score was

calculated as the sum of all catecholamines corrected for potency: (1 x dopamine (μg/kg/

min) + 1 x dobutamine + 100 x epinephrine).

If a combination of dopamine and/or dobutamine (with an Inotrope Score >15) failed to

maintain an adequate BP, epinephrine and/or a “low stress dose” of hydrocortisone could be

added. The “low stress dose” of intravenous hydrocortisone could not be used unless the

catecholamine infusion rates had an Inotrope Score >15. Hydrocortisone was started at 1

mg/kg/day and could be increased up to 3 mg/kg/day to maintain an adequate BP. The

results of the steroid measurements were not available during the study and were not used in

the decision to start hydrocortisone treatment.

The severity of the hypotension was defined by the maximum support needed to maintain an

infant’s BP above the hypotensive range: minimal = volume boluses alone; mild = maximum

Inotrope Score less than 10; moderate = maximum Inotrope Score 10-to-15; and severe (or

catecholamine-resistant) hypotension = maximum Inotrope Score greater than 15.

Catecholamine resistant hypotension was classified as an Inotrope Score >15 based on the

study centers’ experience prior to the study (namely, that infants who failed to maintain an

adequate BP with dopamine infusions ≤15 μg/kg/min usually required dopamine infusions >

20 μg/kg/min). As a result, most infants who failed to maintain an adequate BP with

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dopamine infusions ≤15 μg/kg/min were started on hydrocortisone for additional treatment

rather than increase the amount or number of catecholamine infusions.

Statistical Analyses

The χ2 test was used to compare categorical risk factors and outcomes, and the Student t-
test or Mann-Whitney test was used to compare the means or medians of continuous

variables.

An adjusted multivariable logistic regression model was used to determine the effects of

specific predictive variables on the outcome of interest. We first identified the perinatal and

neonatal risk factors that were most associated with hypotension using bivariate analyses

(Table I). A model was built for hypotension through forward selection. Variables were

added to the model in order of increasing statistical significance. Variables were dropped

from the model if their p-value rose to ≥ 0.1 after the addition of other variables.

After the models were built, the steroid predictive variables were individually forced into the

models to evaluate their effect when adjusted by the other predictors. Odds ratios (OR) and

95% confidence intervals (CI) were calculated using the multivariable model. A p-value of

<0.05 for the predictive variables was considered significant. All analyses were performed

using STATA 12 (College Station, TX) statistical software.

Results

Ninety-five infants were enrolled in the study prior to PDA ligation; 52 infants were

normotensive throughout the post-operative period, and 43 infants developed hypotension:

14 infants had minimal hypotension (i.e., were treated with volume boluses alone (18±6 ml/

kg)); 29 also received catecholamines (dopamine-alone, 72%; dobutamine-alone, 7%;

dopamine and dobutamine, 21%). Six infants had mild, 9 moderate, and 14 severe/

catecholamine-resistant hypotension. Twelve of the14 infants with catecholamine-resistant

hypotension were treated with hydrocortisone. Peak Inotrope Scores occurred during the

first 6 hours after surgery in 6 infants (21%), between 6–12 hours in 10 (34%), between 12–

24 hours in 9 (31%), and between 24–48 hours in 4 (14%).

Infants who developed hypotension were more likely to be younger, weigh less, and be

receiving dopamine at the time of ligation. They were also more likely to have received

prolonged resuscitation at birth (10 min Apgar ≤5) (Table I).

There was a significant increase in cortisol concentrations following the ligation among

infants who remained normotensive during the post-operative period (median cortisol pre-

ligation (interquartile range) = 10.2 (6.2–16.6) ng/ml; post-ligation = 14.5 (10.4–42.7)

ng/ml, p<0.05). This was also true for the study population as a whole (median cortisol pre-

ligation (interquartile range) = 10.8 (6.9–27.7) ng/ml; post-ligation = 20.8 (9.3–47) ng/ml,

p<0.05).

We hypothesized that hypotensive infants would have lower post-operative cortisol

concentrations than normotensive infants. However, we found no significant difference in

postoperative cortisol concentrations between the two groups (Table II). In fact, infants who

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developed minimal/mild or moderate hypotension had significantly higher post-operative

cortisol concentrations than normotensive infants (Table II).

Although low post-operative cortisol concentrations were not associated with the overall

incidence of hypotension, they were associated with its severity and resistance to

catecholamine treatment. Infants who developed catecholamine-resistant hypotension had

significantly lower cortisol concentrations than normotensive infants or infants with milder

degrees of hypotension (Table II). In our multivariable analysis (that included the previously

defined nonsteroidal risk factors; Table I), low cortisol concentrations at 10–12 hour after

ligation was a significant and independent risk factor for developing catecholamine-resistant

hypotension (ORcortisol lower tertile =36.6, CI=2.8–476, p=0.006). Similarly, the risk for

developing catecholamine-resistant hypotension decreased significantly with increasing

postoperative cortisol concentration (ORcortisol (log10) =0.06, CI=0.01–0.50, p=0.009).

We hypothesized that infants with catecholamine-resistant hypotension would have

increased concentrations of cortisol precursors and metabolites during the postoperative

period. However, we found just the opposite: post-ligation precursor and metabolite levels

were either unchanged or significantly decreased (11-deoxycortisol, 21-deoxycortisol,

cortisone) in infants who developed catecholamine-resistant hypotension (Table III).

Neither the cortisol nor other steroid measurements, performed prior to ligation (at baseline

or after the cosyntropin stimulation test), were predictive of which infants would be at risk

for developing post-ligation catecholamine-resistant hypotension (Table III).

Discussion

We hypothesized that an immature or impaired adrenal response to stress (with low levels of

cortisol and high levels of cortisol precursors) might be responsible for the post-operative

hypotension that often follows PDA ligation. Our findings do not support this hypothesis. In

fact cortisol concentrations in infants who developed post-operative hypotension (responsive

to catecholamine or volume resuscitation) were significantly higher than cortisol

concentrations measured in normotensive infants (Table II). Although low cortisol levels do

not appear to be associated with the overall incidence of hypotension, they do appear to be

related to the refractoriness of the hypotension to catecholamine treatment. Infants who

developed hypotension that was resistant to catecholamine treatment had significantly lower

cortisol concentrations than normotensive infants or infants with milder degrees of

hypotension (that responded to catecholamine and volume resuscitation) (Table II).

Our findings also do not support the hypothesis that impaired adrenal production might be

responsible for low cortisol values in infants who develop catecholamine-resistant

hypotension. Cortisol precursors and metabolites were significantly decreased, rather than

increased, in infants who developed catecholamine-resistant hypotension (Table III). In

addition, infants who developed catecholamine-resistant hypotension had the same increase

in cortisol and cortisol-precursors after cosyntropin (exogenous ACTH1–24) as infants who

never developed catecholamine-resistant hypotension (Table III). In hindsight, these

findings should not be so surprising because the blunted, immature adrenal response to

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cosyntropin, seen shortly after birth in preterm infants, usually normalizes by the end of the

second week (17, 18). In our study, the average age at ligation was 4 weeks (70% of the

infants who developed post-ligation catecholamine-resistant hypotension were more than 2

weeks old when they were ligated). We suggest that decreased adrenal stimulation (perhaps

secondary to poor integration of cerebral signals or decreased hypothalamic or pituitary

output) is a better explanation for the low postoperative cortisol concentrations observed in

infants with catecholamine-resistant hypotension.

Because we found that postoperative catecholamine-resistant hypotension was not caused by

adrenal impairment, it should come as no surprise that the tests performed prior to the

ligation (e.g., cosyntropin stimulation and cortisol precursor measurements), which were

designed to identify infants with adrenal impairment, did not identify infants at risk for

developing postoperative catecholamine-resistant hypotension.

Our study has certain limitations. The size of the PDA was not a criterion for study entry,

and pre-ligation echocardiograms were not interpreted by the same sonographer. This design

might have altered our ability to detect a relationship between PDA size and postoperative

hypotension (if one existed). However, previous single center retrospective studies have not

detected a relationship between these two variables. Because we investigated a single

surgical procedure and a specific anesthesia regimen, our findings may not be applicable to

other surgeries in the newborn period.

Our study was not a controlled treatment trial, and therefore our data cannot tell us whether

low cortisol values play a role in the development of catecholamine-resistant hypotension or

simply are predictive of its occurrence. We speculate that when post-operative hypotension

occurs, low cortisol concentrations contribute to its refractory nature and lead to the

development of catecholamine-resistant hypotension: 12 of the 14 infants with Inotrope

Scores greater than 15 were treated with hydrocortisone (1.5±1.0 mg/kg/d); the Inotrope

Scores in these infants dropped by 16±10 points (from 21±8 to 5±6) during the next 6 hours.

In contrast, 2 other infants with Scores greater than 15, and 8 infants with Scores between

10–15, were not treated with hydrocortisone at the same time after ligation; their Inotrope

Scores either did not change or increased during the next 12 to 24 hours (from 14±4 to

15±10) (p<0.01). Only a future, prospective controlled trial will elucidate the contribution of

low cortisol production to the severity of postoperative hypotension.

In conclusion, we found that low postoperative cortisol concentrations were not associated

with the incidence of postoperative hypotension following PDA ligation. They were,

however, associated with the severity of hypotension when it occurred, and its resistance to

catecholamine treatment. We speculate that decreased adrenal stimulation, rather than

adrenal immaturity or impairment, may be responsible for the decreased cortisol

concentrations in these hypotensive infants.

Acknowledgments

Supported by the Thrasher Research Fund, National Institutes of Health/National Center for Research Resources
(CTSI UL 1 TR000004 through the University of California, San Francisco), and the Jamie and Bobby Gates
Foundation. Mass spectrometry was supported by the Michigan Nutrition Obesity Center (DK089503) and
Michigan Regional Comprehensive Metabolomics Research Core (U24DK097153).

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Abbreviations

PDA Patent ductus arteriosus

RSS Respiratory severity score

BP Blood pressure

ACTH Adrenocorticotropic hormone

References

1. Moin F, Kennedy KA, Moya FR. Risk factors predicting vasopressor use after patent ductus
arteriosus ligation. Am J Perinatol. 2003; 20:313–320. [PubMed: 14528401]

2. Harting MT, Blakely ML, Cox CS Jr, Lantin-Hermoso R, Andrassy RJ, Lally KP. Acute
hemodynamic decompensation following patent ductus arteriosus ligation in premature infants. J
Invest Surg. 2008; 21:133–138. [PubMed: 18569433]

3. Teixeira LS, Shivananda SP, Stephens D, Van Arsdell G, McNamara PJ. Postoperative
cardiorespiratory instability following ligation of the preterm ductus arteriosus is related to early
need for intervention. J Perinatol. 2008; 28:803–810. [PubMed: 18615091]

4. Lemyre B, Liu L, Moore GP, Lawrence SL, Barrowman NJ. Do intra-operative fluids influence the
need for post-operative cardiotropic support after a PDA ligation? Zhongguo Dang Dai Er Ke Za
Zhi. 2011; 13:1–7. [PubMed: 21251376]

5. Noori S, Friedlich P, Seri I, Wong P. Changes in myocardial function and hemodynamics after
ligation of the ductus arteriosus in preterm infants. J Pediatr. 2007; 150:597–602. [PubMed:
17517241]

6. McNamara PJ, Stewart L, Shivananda SP, Stephens D, Sehgal A. Patent ductus arteriosus ligation is
associated with impaired left ventricular systolic performance in premature infants weighing less
than 1000 g. J Thorac Cardiovasc Surg. 2010; 140:150–157. [PubMed: 20363478]

7. Jain A, Sahni M, El-Khuffash A, Khadawardi E, Sehgal A, McNamara PJ. Use of targeted neonatal
echocardiography to prevent postoperative cardiorespiratory instability after patent ductus arteriosus
ligation. J Pediatr. 2012; 160:584–589. e581. [PubMed: 22050874]

8. El-Khuffash A, McNamara PJ, Lapointe A, Jain A. Adrenal function in preterm infants undergoing
patent ductus arteriosus ligation. Neonatology. 2013; 104:28–33. [PubMed: 23635520]

9. Aucott SW, Watterberg KL, Shaffer ML, Donohue PK. Do cortisol concentrations predict short-
term outcomes in extremely low birth weight infants? Pediatrics. 2008; 122:775–781. [PubMed:
18829801]

10. Thomas S, Murphy JF, Dyas J, Ryalls M, Hughes IA. Response to ACTH in the newborn. Arch
Dis Child. 1986; 61:57–60. [PubMed: 3006603]

11. Watterberg KL, Scott SM. Evidence of early adrenal insufficiency in babies who develop
bronchopulmonary dysplasia. Pediatrics. 1995; 95:120–125. [PubMed: 7770288]

12. Heckmann M, Wudy SA, Haack D, Pohlandt F. Serum cortisol concentrations in ill preterm infants
less than 30 weeks gestational age. Acta Paediatr. 2000; 89:1098–1103. [PubMed: 11071092]

13. Huysman MW, Hokken-Koelega AC, De Ridder MA, Sauer PJ. Adrenal function in sick very
preterm infants. Pediatr Res. 2000; 48:629–633. [PubMed: 11044483]

14. Ng PC, Lam CW, Fok TF, Lee CH, Ma KC, Chan IH, Wong E. Refractory hypotension in preterm
infants with adrenocortical insufficiency. Arch Dis Child Fetal Neonatal Ed. 2001; 84:F122–124.
[PubMed: 11207229]

15. Watterberg KL, Gerdes JS, Cook KL. Impaired glucocorticoid synthesis in premature infants
developing chronic lung disease. Pediatr Res. 2001; 50:190–195. [PubMed: 11477202]

16. Hanna CE, Jett PL, Laird MR, Mandel SH, LaFranchi SH, Reynolds JW. Corticosteroid binding
globulin, total serum cortisol, and stress in extremely low-birth-weight infants. Am J Perinatol.
1997; 14:201–204. [PubMed: 9259928]

Clyman et al. Page 9

J Pediatr. Author manuscript; available in PMC 2015 June 01.

N
IH

-P
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u
th

o
r M

a
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-P

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a
n
u
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-P

A
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u
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o
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a
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t



17. Ng PC, Lam CW, Lee CH, Ma KC, Fok TF, Chan IH, Wong E. Reference ranges and factors
affecting the human corticotropin-releasing hormone test in preterm, very low birth weight infants.
J Clin Endocrinol Metab. 2002; 87:4621–4628. [PubMed: 12364445]

18. Ng PC, Lee CH, Lam CW, Ma KC, Fok TF, Chan IH, Wong E. Transient adrenocortical
insufficiency of prematurity and systemic hypotension in very low birthweight infants. Arch Dis
Child Fetal Neonatal Ed. 2004; 89:F119–126. [PubMed: 14977894]

19. Hanna CE, Keith LD, Colasurdo MA, Buffkin DC, Laird MR, Mandel SH, Cook DM, LaFranchi
SH, Reynolds JW. Hypothalamic pituitary adrenal function in the extremely low birth weight
infant. J Clin Endocrinol Metab. 1993; 76:384–387. [PubMed: 8381799]

20. Masumoto K, Kusuda S, Aoyagi H, Tamura Y, Obonai T, Yamasaki C, Sakuma I, Uchiyama A,
Nishida H, Oda S, Fukumura K, Tagawa N, Kobayashi Y. Comparison of serum cortisol
concentrations in preterm infants with or without late-onset circulatory collapse due to adrenal
insufficiency of prematurity. Pediatr Res. 2008; 63:686–690. [PubMed: 18520332]

21. Hochwald O, Holsti L, Osiovich H. The use of an early ACTH test to identify hypoadrenalism-
related hypotension in low birth weight infants. J Perinatol. 2012; 32:412–417. [PubMed:
22402482]

22. Bolt RJ, Van Weissenbruch MM, Popp-Snijders C, Sweep FG, Lafeber HN, Delemarre-van de
Waal HA. Maturity of the adrenal cortex in very preterm infants is related to gestational age.
Pediatr Res. 2002; 52:405–410. [PubMed: 12193676]

23. Fujitaka M, Jinno K, Sakura N, Takata K, Yamasaki T, Inada J, Sakano T, Horino N, Kidani K,
Ueda K. Serum concentrations of cortisone and cortisol in premature infants. Metabolism. 1997;
46:518–521. [PubMed: 9160817]

24. Hingre RV, Gross SJ, Hingre KS, Mayes DM, Richman RA. Adrenal steroidogenesis in very low
birth weight preterm infants. J Clin Endocrinol Metab. 1994; 78:266–270. [PubMed: 8106610]

25. al Saedi S, Dean H, Dent W, Cronin C. Reference ranges for serum cortisol and 17-
hydroxyprogesterone levels in preterm infants. J Pediatr. 1995; 126:985–987. [PubMed: 7776113]

26. Fernandez EF, Montman R, Watterberg KL. Adrenal function in newborns undergoing surgery. J
Perinatol. 2010; 30:814–818. [PubMed: 20237483]

27. Chen S, Tacy T, Clyman R. How useful are B-type natriuretic peptide measurements for
monitoring changes in patent ductus arteriosus shunt magnitude? J Perinatol. 2010; 30:780–785.
[PubMed: 20376057]

28. Watterberg KL, Shaffer ML, Garland JS, Thilo EH, Mammel MC, Couser RJ, Aucott SW, Leach
CL, Cole CH, Gerdes JS, Rozycki HJ, Backstrom C. Effect of dose on response to
adrenocorticotropin in extremely low birth weight infants. J Clin Endocrinol Metab. 2005;
90:6380–6385. [PubMed: 16159938]

29. Taylor LK, Auchus RJ, Baskin LS, Miller WL. Cortisol Response to Operative Stress with
Anesthesia in Healthy Children. J Clin Endocrinol Metab. 2013

30. Kulle AE, Welzel M, Holterhus PM, Riepe FG. Implementation of a liquid chromatography
tandem mass spectrometry assay for eight adrenal C-21 steroids and pediatric reference data.
Horm Res Paediatr. 2013; 79:22–31. [PubMed: 23328487]

31. Zubrow AB, Hulman S, Kushner H, Falkner B. Determinants of blood pressure in infants admitted
to neonatal intensive care units: a prospective multicenter study. Philadelphia Neonatal Blood
Pressure Study Group. J Perinatol. 1995; 15:470–479. [PubMed: 8648456]

32. Watkins AM, West CR, Cooke RW. Blood pressure and cerebral haemorrhage and ischaemia in
very low birthweight infants. Early Hum Dev. 1989; 19:103–110. [PubMed: 2737101]

33. Skippen PW, Krahn GE. Acute renal failure in children undergoing cardiopulmonary bypass. Crit
Care Resusc. 2005; 7:286–291. [PubMed: 16539583]

Appendix

Additional members of the PDA Ligation/Hypotension Trial Investigators include:

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Study Coordinating Center--University of California San Francisco, San Francisco, CA:

Scott Fields, PharmD, and Neonatal Clinical Research Center nurses.

Steroid Measurement Center--University of Michigan, Ann Arbor, MI: Susan Matthews,

PhD, Robert Chomic, MS, Stephen C. Brown, PhD.

Study Sites--Hospital for Sick Children, Toronto, Canada: Afif El-Khuffash MD, Jenny Luc,

RRT; University of Chicago, Chicago, IL: Michael Schreiber, MD; University of Oklahoma,

Oklahoma City, OK: Michael McCoy, MS, APRN; Children’s & Women’s Health Centre of

British Columbia, Vancouver, Canada: Jennifer Claydon, MSc, Nadine Lusney, RN, Kristi

Finlay, RN; University of Virginia, Charlottesville, VA: Amy E. Blackman, RN; Vanderbilt

University, Nashville, TN: Amy Law-Beller, RN; Indiana University, Indianapolis, IN:

Leslie Dawn Wilson, BSN, CCRC; University of New Mexico, Albuquerque, NM: Kristi

Watterberg, MD, Theresa Wussow RN; Duke University, Durham, NC: Michael Cotten,

MD, Kim Fisher, Ph.D., FNP-BC, IBCLC.

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Table 1

Patient demographics and risk factors associated with Postoperative hypotension

Hypotension

None (n=52) Minimal/mild/moderate/severe (n=43) p-value*

Gestation –wks 26.1 ± 2.1 25.6 ± 2.2 -

Gestation ≤25 wks (%) 50 72 0.029

Birth weight -gm 880 ± 295 791 ± 316 -

Sex – male (%) 60 56 -

Preterm labor (%) 73 79 -

PROM >18 hr (%) 20 28 -

Betamethasone > 24 hr (%) 42 37 -

Preeclampsia (%) 12 16 -

Chorioamnionitis (%) 21 21 -

Diabetes (%) 4 9 -

Race -caucasian (%) 25 33 -

Caesarean section (%) 65 72 -

Apgar Score (5 min) ≤3 (%) 24 26 -

Apgar Score (10 min) ≤5 (%) 4 21 0.011**

RDS (%) 98 98 -

Surfactant (%) 94 98 -

Pulmonary hemorrhage (%) 6 16 0.097

Dopamine during 1st 24 hr after birth (%) 23 45 0.023

Sepsis (onset ≤3 d) (%) 2 7 -

Sepsis (onset >4 d) (%) 20 14 -

Hydrocortisone treatment prior to study (%) 13 9 -

Indomethacin or Ibuprofen prior to study (%) 75 81 -

IVH ≥ grade 3 prior to study (%) 23 26 -

NEC/perforation prior to study (%) 19 14 -

ACTH stimulation test-time before surgery - hr 21 ± 22 25 ± 56 -

Postnatal age at ligation - wks 4.6 ± 2.7 2.8 ± 2.5 0.002

Postmenstrual age at ligation (wks) 30.6 ± 3.5 28.4 ± 3.3 0.002

Weight at ligation - gm 1330 ± 541 1026 ± 502 0.006**

PDA size (large) prior to ligation (%) 59 67 -

RSS prior to ligation 3.5 ± 2.4 2.8 ± 1.6 -

Inotrope Score preligation 0.3 ± 1.2 2.7 ± 6.2 0.008**

Fentanyl dose during ligation – μg/kg 15 ± 13 15 ± 13 -

Ligation duration - min 39 ± 21 33 ± 14 -

Values represent mean ± standard deviation or percent (%).

*
p-values ≥0.1 are not shown.

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**
Variables used in the final multivariable model for catecholamine-resistant hypotension.

Note: other variables were dropped from the model if their p-value rose to ≥ 0.1 during forward selection.

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Table 2

Postoperative Cortisol concentrations: Comparisons between different groups of Normotensive and

Hypotensive infants

Patient Groups

Postoperative Cortisol concentrations

Cortisol–ng/ml
(interquartile range)

Cortisol-log(10)
(±sd)

Cortisol
concentrations in

lower tertile

Cortisol
concentrations in

upper tertile

Normotension compared with Hypotension (minimal/mild/mod & catechol-resistant)

 Normotension (n=52) 14.9
(10–42)

1.31
(±0.55)

32% 28%

 Hypotension (minimal/mild/mod & catechol-
resistant) (n=43)

28
(8.6–55)

1.38
(±0.62)

36% 38%

Hypotension (minimal/mild/mod) compared with Normotension

 Hypotension (minimal/mild/mod) (n=29) 40.8 *

(12–69)
1.56 *

(±0.58)
18% 57% *

 Normotension (n=52) 14.9*

(10–42)
1.31 *

(±0.55)
32% 28% *

Hypotension (catechol-resistant) compared with Normotension

 Hypotension (catechol-resistant) (n=14) 8.9 *

(5.1–12)
1.03 *

(±0.57)
71% * 0%

 Normotension (n=52) 14.9*

(10–42)
1.31 *

(±0.55)
32% * 28%

Hypotension (catechol-resistant) compared with Hypotension (minimal/mild/mod)

 Hypotension (catechol-resistant) (n=14) 8.9 *

(5.1–12)
1.03 *

(±0.57)
71% * 0% *

 Hypotension (minimal/mild/mod) (n=29) 40.8*

(12–69)
1.56 *

(±0.58)
18% * 57% *

Hypotension (catechol-resistant) compared with Normotension or Hypotension (minimal/mild/mod)

 Hypotension (catechol-resistant) (n=14) 8.9 *

(5.1–12)
1.03 *

(±0.57)
71% * 0% *

 Normotension or Hypotension (minimal/mild/
mod) (n=81)

29.2 *

(11–54)
1.40 *

(±0.57)
27% * 38% *

Values represent median (interquartile range) of absolute cortisol values, mean (± standard deviation) of the log (base 10) transformed cortisol
values, or percent (%) of infants with cortisol values in the lower or upper third of the distribution of postoperative cortisol concentrations.

*
p-values <0.05 when comparing the two patient groups.

Hypotension severity is defined by the maximum support needed to maintain BP above the hypotensive range (see Methods): minimal = volume
boluses alone; mild = maximum Inotrope Score < 10; moderate = maximum Inotrope Score 10-to-15; and catecholamine-resistant hypotension =
maximum Inotrope Score > 15.

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ia

bl
es

. p
-v

al
ue

s 
≥

0.
1 

ar
e 

no
t 

sh
ow

n.

D
ef

in
it

io
ns

: 
pr

e,
 v

al
ue

s 
ob

ta
in

ed
 p

ri
or

 t
o 

A
C

T
H

 s
ti

m
ul

at
io

n 
te

st
 (

pr
io

r 
to

 l
ig

at
io

n)
; 

A
C

T
H

, v
al

ue
s 

ob
ta

in
ed

 6
0 

m
in

 a
ft

er
 A

C
T

H
 s

ti
m

ul
at

io
n 

(p
ri

or
 t

o 
li

ga
ti

on
);

 p
os

to
p,

 v
al

ue
s 

ob
ta

in
ed

 b
et

w
ee

n 
10

–1
2 

hr
 a

ft
er

li
ga

ti
on

.

J Pediatr. Author manuscript; available in PMC 2015 June 01.