Background Neonates with pulmonary hypertension have been treatedwith inhaled nitric oxide because of studies suggesting thatit is a selective pulmonary vasodilator. We conducted a randomized,multicenter, controlled trial to determine whether inhaled nitricoxide would reduce mortality or the initiation of extracorporealmembrane oxygenation in infants with hypoxic respiratory failure.
Methods Infants born after a gestation of >34 weeks who were14 days old or less, had no structural heart disease, and requiredassisted ventilation and whose oxygenation index was 25 or higheron two measurements were eligible for the study. The infantswere randomly assigned to receive nitric oxide at a concentrationof 20 ppm or 100 percent oxygen (as a control). Infants whosepartial pressure of arterial oxygen (PaO2) increased by 20 mmHg or less after 30 minutes were studied for a response to 80-ppmnitric oxide or control gas.
Results The 121 infants in the control group and the 114 inthe nitric oxide group had similar base-line clinical characteristics.Sixty-four percent of the control group and 46 percent of thenitric oxide group died within 120 days or were treated withextracorporeal membrane oxygenation (P = 0.006). Seventeen percentof the control group and 14 percent of the nitric oxide groupdied (P not significant), but significantly fewer in the nitricoxide group received extracorporeal membrane oxygenation (39percent vs. 54 percent, P = 0.014). The nitric oxide group hadsignificantly greater improvement in PaO2 (mean [±SD]increase, 58.2±85.2 mm Hg, vs. 9.7±51.7 mm Hgin the controls; P<0.001) and in the oxygenation index (adecrease of 14.1±21.1, vs. an increase of 0.8±21.1in the controls; P<0.001). The study gas was not discontinuedin any infant because of toxicity.
Conclusions Nitric oxide therapy reduced the use of extracorporealmembrane oxygenation, but had no apparent effect on mortality,in critically ill infants with hypoxic respiratory failure.
Hypoxic respiratory failure in neonates born at or near term(at >34 weeks' gestation) may be caused by conditions suchas primary persistent pulmonary hypertension, respiratory distresssyndrome, aspiration of meconium, pneumonia or sepsis, and congenitaldiaphragmatic hernia.1,2 Conventional therapy, short of extracorporealmembrane oxygenation, involves support with oxygen, mechanicalventilation, and the induction of alkalosis, neuromuscular blockade,and sedation.3,4,5,6 None of these therapies have been foundto reduce mortality or the need for extracorporeal membraneoxygenation. To date, selective pulmonary vasodilators freeof systemic side effects have not been studied in large trialsof neonates.7
Nitric oxide, or endothelium-derived relaxing factor, is importantin regulating vascular muscle tone.8,9,10,11,12,13 In newbornlambs with pulmonary hypertension induced by hypoxia, the inhalationof 40 to 80 parts per million (ppm) of nitric oxide reversedpulmonary vasoconstriction without affecting the systemic circulation.14,15,16Two recent studies of neonates with severe persistent pulmonaryhypertension have shown that inhaled nitric oxide rapidly improvedpreductal oxygen saturation, without detectable toxic effects.17,18A prospective study of multiple randomized doses of inhalednitric oxide in infants referred for extracorporeal membraneoxygenation did not find a correlation between the dose of nitricoxide and the degree of improvement in oxygenation.19 We conducteda prospective, multicenter, randomized, controlled, double-blindtrial to evaluate whether inhaled nitric oxide would reducemortality or the need for extracorporeal membrane oxygenationin infants born at or near term who had hypoxic respiratoryfailure that was unresponsive to aggressive conventional therapy.
Methods
Study Hypotheses
The primary hypothesis in the study was that administering inhalednitric oxide to infants born at 34 or more weeks of gestationwho had hypoxic respiratory failure and an oxygenation indexof 25 or higher would reduce the risk of death by day 120 orthe initiation of extracorporeal membrane oxygenation from 50percent in control infants to 30 percent in infants given nitricoxide, a relative reduction of 40 percent. The oxygenation indexwas calculated as the mean airway pressure times the fractionof inspired oxygen (FiO2) divided by the partial pressure ofarterial oxygen (PaO2) times 100.
The secondary hypothesis was that 30 minutes after the startof treatment, inhaled nitric oxide would increase PaO2 and decreasethe oxygenation index and the alveolar–arterial oxygengradient. We hypothesized that among the surviving infants,treatment with inhaled nitric oxide would shorten hospitalizationwithout increasing the duration of assisted ventilation or theincidence of air leakage, bronchopulmonary dysplasia, or neurodevelopmentaldisability at 18 to 24 months.
Study Patients
Infants born at 34 or more weeks of gestation who required assistedventilation for hypoxic respiratory failure and had an oxygenationindex of at least 25 on two measurements made at least 15 minutesapart were eligible for the trial. Hypoxic respiratory failurewas caused by persistent pulmonary hypertension, meconium aspiration,pneumonia or sepsis, respiratory distress syndrome, or suspectedpulmonary hypoplasia associated with oligohydramnios and prematurerupture of the membranes. All the infants were required to havean indwelling catheter and to undergo echocardiography beforerandomization. Echocardiographic evidence of pulmonary hypertensionwas not required, because studies have shown that inhaled nitricoxide improves the matching of ventilation with perfusion andmay reduce intrapulmonary shunting in the absence of a directintracardiac shunt.20,21
Infants were considered ineligible for the study if they weremore than 14 days old, had a congenital diaphragmatic hernia,or were known to have congenital heart disease, or if it hadbeen decided not to provide full treatment. The study centersattempted to obtain a cranial ultrasonogram before enrollingan infant in the study. Consent was obtained from the parentsor guardians before the infants underwent randomization, andeach study center obtained approval from the institutional reviewboard before enrollment began. Copies of the study protocolare available from the authors on request.
Guidelines for Management
The approach to care before enrollment was not specified bythe study protocol. Each participating center developed generalmanagement guidelines to be used throughout the study and agreedto use the most aggressive forms of conventional therapy beforerandomization. These guidelines included the maintenance ofa mean arterial blood pressure above 45 mm Hg, the inductionof alkalosis (range of target pH, 7.45 to 7.6), and treatmentwith bovine surfactant (BLES, BLES Biochemicals, London, Ont.,Canada; or Survanta, Abbott Laboratories, Columbus, Ohio) beforethe start of treatment with the study gas. The protocol specifiedthat the mode of ventilation (conventional or high frequency)could not be changed after randomization, except as part ofweaning from assisted ventilation.
Randomization
The infants were stratified according to study center and randomlyassigned by telephone to receive either 100 percent oxygen (thecontrol treatment) or nitric oxide according to a permuted-blockdesign developed and implemented by the coordinating center.
Administration and Monitoring of Study Gas
If treatment with the study gas could be started within 15 minutesafter the second qualifying oxygenation-index score was obtained,the arterial-blood gas values from that measurement served asthe base-line values in assessing the response to the studytreatment. If the treatment could not be started within the15-minute period, a third measurement of arterial-blood gas,obtained before the administration of the study gas, was usedto determine the base-line value. Primary-grade nitric oxidewas supplied in a concentration of 800 ppm in balanced nitrogen(Canadian Liquid Air, Montreal; and Ohmeda, Liberty Corner,N.J.); the gas was certified to be within ±1 percentof the stated nitric oxide content and to contain less than5 ppm of nitrogen dioxide. The gas mixture was sampled afterit entered the injection site of the inspiratory circuit andbefore it reached the infant's endotracheal tube and was analyzedcontinuously for nitric oxide and nitrogen dioxide with chemiluminescence(model 42H, Thermo Environmental Instruments, Franklin, Mass.;and model CLD 700AL, ECO Physics, Durten, Switzerland) or withelectrochemical analyzers (Pulmonox II, Pulmonox, Tolfield,Alta., Canada; and Dräger Prac II, Dräger, Chantilly,Va.). Quality-control procedures ensured accurate calibrationand prevented the supply tank of nitric oxide gas from beingcontaminated.
Except when the treatment was initiated and when the concentrationof the study gas was changed, the infants were cared for byclinical teams unaware of each infant's treatment assignment;the randomization was performed, the gas administered, and safetymonitored by designated persons who were not involved in theclinical care. Levels of inspired oxygen, nitric oxide, andnitrogen dioxide were recorded every two hours and after thesettings of the ventilator were changed. We kept the clinicalteams unaware of the treatment assignments by making mock adjustmentsin the case of the control infants, covering the analyzer readingsand the gas tanks, and sampling the supply of oxygen beforethe injection site of the study gas.
A response to treatment was defined according to the changefrom base line in the PaO2 30 minutes after the initial exposureto the study gas (a complete response was defined as an increaseof more than 20 mm Hg; a partial response, as an increase of10 to 20 mm Hg; and no response, as an increase of less than10 mm Hg) when the two measurements were made at comparablesampling sites. When an infant had a complete response, treatmentwith the study gas (either nitric oxide at a concentration of20 ppm or 100 percent oxygen) was continued. When an infanthad less than a complete response, the treatment was stoppedfor 15 minutes if the stoppage was tolerated, the arterial-bloodgases were measured again, and then the study gas was administeredat a maximal concentration of 80 ppm. Arterial-blood gases weremeasured again 30 minutes later. Infants who had complete responsesto the maximal concentration continued to be treated at thatconcentration; in infants with partial responses, treatmentwas continued at the lowest concentration of gas that producedat least a partial response. If an infant had no response witheither the 20-ppm or the 80-ppm concentration of gas, treatmentwas discontinued. Gas was also discontinued in any infant whosecondition deteriorated (absolute decrease in oxygen saturation,>10 percent) before the end of the initial phase of administrationat either the high or the low concentration, and such infantswere classified as having no response. When an infant did notrespond to the initial administration of the study gas, thetreatment could be attempted again as many as three times atsix-hour intervals. No crossover between study groups was allowed.
If an infant continued to receive the study gas after the initialdosing algorithm, the gas was monitored in an unmasked fashionby designated persons who were not involved with the infant'sclinical care. The protocol suggested algorithms for weaninginfants from the study gas, escalating the dose of gas afterthe occurrence of clinical deterioration, and starting treatmentagain after successful weaning. The study protocol permittedtreatment with the study gas for a cumulative maximum of 336hours (14 days). Decisions about initiating extracorporeal membraneoxygenation were made by the blinded clinical team on the basisof center-specific criteria.
Monitoring of Safety
Blood methemoglobin concentrations were measured 1, 3, 6, and12 hours after the start of treatment with the study gas andevery 12 hours thereafter until 24 hours after the treatmentended. Methemoglobin levels of 5 to 10 percent were managedby reducing the concentration of study gas by half until thelevel fell below 5 percent. The study gas was discontinued ifthe methemoglobin level exceeded 10 percent. If the concentrationof nitrogen dioxide exceeded 7 ppm, the study gas was discontinued;the gas was decreased by half if the concentration was 5 to7 ppm.
The infants were monitored for signs of bleeding. Cranial ultrasonographywas performed before randomization and 24 hours after the finaldiscontinuation of the study gas. All the readings were doneby local ultrasonographers.22
Statistical Analysis
According to the data from the participating centers, we estimatedthat mortality or the use of extracorporeal membrane oxygenationin infants with an oxygenation-index score between 25 and 40would be 50 percent. To demonstrate a 40 percent reduction inthe primary outcome with a power of 0.90 and a two-tailed alphaof 0.05, 125 patients were required in each group. The primaryanalysis was an intention-to-treat analysis.
Continuous variables were compared by t-tests or Wilcoxon tests,and discrete variables were compared by chi-square tests. TheGart test was used to evaluate the homogeneity of relative risks.23
The trial was monitored by an independent Data Safety and MonitoringCommittee, which planned evaluations after approximately onethird and two thirds of the study patients were enrolled. Toreduce the overall probability of a type I error as much aspossible, significance was tested at each interim analysis bythe group-sequential method of Lan and DeMets with the O'Brien–Flemingspending function.24 Results are presented as means ±SD.
Results
The trial was terminated at the recommendation of the Data Safetyand Monitoring Committee after the second planned review ofdata, which showed that the z value had crossed the predeterminedboundary of statistical significance. After the recommendationwas reviewed and accepted by the National Institute of ChildHealth and Human Development and the investigators, recruitmentceased on May 2, 1996.
Base-Line Characteristics
Two hundred thirty-five infants were enrolled in the trial.There were no significant differences between the study groupsin the characteristics of the patients (Table 1), treatmentmethods, or status at the time of randomization (Table 2). Seventy-twopercent of the controls and 71 percent of the treated infantsreceived surfactant before randomization, and 50 percent and49 percent, respectively, received it within six hours beforerandomization. High-frequency ventilation, primarily oscillatory,was used in 55 percent of both groups; 37 percent of the controlsand 32 percent of the treated infants received such treatmentat randomization. Over 90 percent of all the infants receivedvolume support, vasopressor support, neuromuscular blockade,and sedation before randomization (Table 2).
Table 2. Treatment Variables and Status of the Patients at Randomization.
The causes of hypoxic respiratory failure are shown in Table 1.Forty-nine percent of all randomized infants had meconiumaspiration syndrome; 17 percent had persistent pulmonary hypertension.Echocardiography was performed before randomization in 228 infants(97 percent); of the 226 infants for whom complete data wereavailable, 78 percent had evidence of pulmonary hypertension(right-to-left or bidirectional shunting, tricuspid-valve regurgitation,or both). There was no difference in the prevalence of pulmonaryhypertension between the study groups.
Randomization occurred 1.7±2.3 days after birth for thecontrols and 1.7±1.8 days after birth for the treatedinfants (Table 2). Data from the first qualifying arterial-bloodgas measurement are also shown in Table 2; on the second qualifyingmeasurement, the oxygenation index was 46.3±19.9 in thecontrol group and 47.3±31.3 in the nitric oxide group.Sixty-two percent of the control group and 64 percent of thenitric oxide group had a third arterial-blood gas measurementbefore treatment with the study gas was begun. The median timefrom randomization to the administration of the study gas was10 minutes in the control group and 15 minutes in the nitricoxide group (Table 2). Five randomized infants (four in thecontrol group and one in the nitric oxide group) did not receivestudy gas.
Primary Outcome
The incidence of the primary outcome (death by 120 days of ageor the initiation of extracorporeal membrane oxygenation) wassignificantly lower in the nitric oxide group than in the controlgroup (46 percent vs. 64 percent; relative risk, 0.72; 95 percentconfidence interval, 0.57 to 0.91; P = 0.006, a significantdifference given the Lan–DeMets cutoff of 0.044) (Table 3).Thirty-six infants died, among whom 17 (9 in the controlgroup and 8 in the nitric oxide group) received extracorporealmembrane oxygenation. Among the other 19 infants who died, 10(5 in each group) had contraindications to extracorporeal membraneoxygenation; 5 (3 in the control group and 2 in the nitric oxidegroup) had their life support withdrawn; and 4 (3 and 1 in therespective groups) did not meet center-specific criteria forextracorporeal membrane oxygenation. There were no differencesbetween the groups in the causes of death. The infants in thenitric oxide group received extracorporeal membrane oxygenationless often (39 percent) than the controls (55 percent, P = 0.014)(Table 3). The median time from randomization to the initiationof extracorporeal membrane oxygenation was 4.4 hours in thecontrol group and 6.7 hours in the nitric oxide group (P = 0.04).
Table 3. Outcomes of Administration of the Study Gas, According to Group.
Secondary Outcomes
Among the surviving infants, there were no differences betweenthe groups with respect to the length of hospitalization, thenumber of days of respiratory support (assisted ventilation,continuous positive airway pressure, or oxygen), or the incidenceof air leakage or bronchopulmonary dysplasia (Table 3).
Thirty minutes after the administration of the study gas began,the infants in the nitric oxide group had a significantly greatermean increase in PaO2 than the controls (58.2±85.2 vs.9.7±51.7 mm Hg), a significantly greater change in theoxygenation index (a decrease of 14.1±21.1 as comparedwith an increase of 0.8±21.1), and a significantly greaterdecrease in the alveolar–arterial oxygen gradient (60.0±85.1vs. 6.7±57.5 mm Hg; P<0.001 for all three comparisons)(Table 3).
More infants in the nitric oxide group than in the control grouphad at least a partial response to the initial administrationof the study gas (66 percent vs. 26 percent, P<0.001) (Table 4).Of the 125 infants who had no response to 20-ppm nitricoxide or control gas, similar proportions of the nitric oxidegroup (18 percent [7 of 38]) and the control group (20 percent[17 of 87]) had at least partial responses to 80-ppm nitricoxide or control gas (P = 0.30). Of the 30 infants who had partialresponses to the study gas at 20 ppm, 29 percent of the nitricoxide group (5 of 17) and 8 percent of the control group (1of 13) had at least a partial response at 80 ppm (P = 0.34).Therefore, a majority of the infants who did not have completeresponses at the 20-ppm concentration and who were evaluatedat the 80-ppm concentration had no response to the study gasat the higher concentration (nitric oxide group, 77 percent[41 of 53]; control group, 81 percent [75 of 93]).
Table 4. Responses to the Initial Administration of 20-ppm Nitric Oxide or Oxygen, and Subsequent Responses to 80-ppm Concentrations of Study Gas by Infants Whose Responses to the Initial Treatment Were Less Than Complete.
According to the study protocol, three additional trials werepermitted, but only 10 infants (6 in the control group and 4in the nitric oxide group) underwent such trials. Twenty-eightinfants assigned to the control group (23 percent) receivedthe study gas for more than 24 hours, as compared with 64 infantsassigned to the nitric oxide group (56 percent) (median durationof gas administration, 2 hours vs. 40 hours; P<0.001). Amongthe infants who had responses to either the 20-ppm or the 80-ppmconcentration of study gas when it was first administered, 62percent of those in the nitric oxide group (50 of 81) were successfullyweaned, as compared with 40 percent of those in the controlgroup (19 of 47). Among the infants successfully weaned, threeof those in the control group and two of those in the nitricoxide group had the study gas administered again.
Post hoc subgroup analyses were performed to evaluate the relationsbetween each of several variables — the primary diagnosis,the presence or absence of echocardiographic evidence of pulmonaryhypertension, the first qualifying oxygenation-index score,and treatment with surfactant before randomization, the useof high-frequency ventilation at the time of randomization orearlier, or the use of both surfactant and ventilation —and the incidence of the primary outcome and a complete responseto the study gas (Table 5). Tests of homogeneity did not showsignificant differences between the relative risks. Therefore,there was no conclusive evidence, when the nitric oxide groupwas compared with the control group, that the relative riskeither of the primary outcome or of a complete response to nitricoxide was related to any of the variables studied in the subgroupanalysis.
The study gas was not discontinued in any infant because oftoxic effects. In the nitric oxide group, the mean peak levelof nitrogen dioxide was 0.8±1.2 ppm, and the mean peakmethemoglobin level was 2.4±1.8 percent. The concentrationof inhaled nitric oxide was reduced in 11 infants in the nitricoxide group because of elevated methemoglobin levels (5 to 10percent).
There were no significant differences between the groups afterrandomization in the overall incidence or severity of intracranialhemorrhage (total number, 19 in the control group and 18 inthe nitric oxide group; grade IV, 8 and 5, respectively). Therewere also no significant differences between the control groupand the nitric oxide group in the occurrence of periventricularleukomalacia (6 vs. 3), brain infarction (7 vs. 7), seizuresrequiring anticonvulsive therapy (16 vs. 24), and either pulmonary(4 vs. 6) or gastrointestinal (1 vs. 1) hemorrhage.
There were 21 deviations from the protocol. Two infants whowere ineligible for the study were randomized: one had a cysticadenomatoid malformation, and the other had a qualifying oxygenation-indexscore of 24.4. One infant randomly assigned to nitric oxidereceived oxygen, and six controls received nitric oxide. Twoinfants received doses of nitric oxide in excess of 80 ppm:100 ppm for 36 minutes in one, and 101 ppm for 60 minutes inthe other. The methemoglobin level in the latter was 6 percent,and the nitrogen dioxide concentration 5.1 ppm; these levelsdecreased when the dose of nitric oxide was lowered. Two infantsreceived 80-ppm nitric oxide in error, after having completeresponses to the 20-ppm concentration. There were eight episodesin which the patient's study assignment became apparent becauseof equipment leaks or elevated methemoglobin values.
Discussion
This trial demonstrated that nitric oxide therapy reduced theincidence of death or extracorporeal membrane oxygenation ina cohort of full-term and nearly full-term infants with hypoxicrespiratory failure who did not respond to aggressive conventionaltherapy. Furthermore, besides testing clinically important outcomes,the study was designed as a management trial whose findingscould serve as the basis of recommendations for practice. Althoughinhaled nitric oxide reduced the combined outcome of death orthe initiation of extracorporeal membrane oxygenation, it didnot significantly reduce mortality, which was 17 percent inthe control group and 14 percent in the nitric oxide group.The causes of death in the two groups did not differ. Amonginfants who received extracorporeal membrane oxygenation, overallmortality was 16 percent (14 percent in the control group and18 percent in the nitric oxide group).
Several open-label studies preceding this trial reported improvedoxygenation in infants with severe persistent pulmonary hypertensionwho were treated with initial doses of nitric oxide rangingfrom 5 to 80 ppm.17,18,19 In the current trial, 47 percent ofthe infants treated with nitric oxide (53 of 112) received the80-ppm concentration after having less than a complete responseat 20 ppm. Only 15 percent of those infants (8 of 53) had improvedresponses (3 complete and 5 partial) at 80 ppm, suggesting thatlimited numbers of infants will benefit from higher doses ofnitric oxide.
Nitric oxide treatment appears safe at the concentrations anddurations used in this trial. However, the protocol was designedto reduce the likelihood of dose-related toxic effects by encouragingthe use of the lowest effective dose. There was no evidenceof toxic effects as determined on the basis of elevated levelsof nitrogen dioxide, persistently elevated methemoglobin levels,systemic hypotension, or evidence of increased bleeding. Theeffect of inhaled nitric oxide on coagulation, platelet aggregation,and adhesion is unclear.25,26,27 The study was not designedto evaluate the formation of peroxynitrites or evidence of othertissue damage that could potentially accompany the administrationof nitric oxide.28,29 Nor was it designed to determine the lowesteffective dose of nitric oxide. Further research will be requiredto address these issues. All the infants in the current trialwill receive a blinded neurodevelopmental evaluation at theage of 18 to 24 months.
We intended to treat infants who had an oxygenation index of25 or above (50 percent risk of requiring extracorporeal membraneoxygenation or dying), but the majority had three oxygenation-indexdeterminations exceeding 40 within a two-hour period, therebymeeting the most common criterion for extracorporeal membraneoxygenation before they were randomized.30 Before extracorporealmembrane oxygenation was widely available, oxygenation indexesin this range predicted a risk of mortality of approximately80 percent.30 Although post hoc subgroup analyses did not showa significant difference in the relative risks, infants withthe lowest oxygenation indexes appeared more likely to havecomplete responses to the initial administration of nitric oxideand to survive without extracorporeal membrane oxygenation,suggesting that the earlier use of nitric oxide may be beneficial.This question should be tested in a prospective trial. In theinterim, nitric oxide therapy should not be delayed until theinfant's condition is so unstable that transfer for extracorporealmembrane oxygenation would be difficult or impossible. We believethat appropriate support by conventional means, including theuse of surfactant and high-frequency ventilation by experiencedpractitioners, should precede the administration of inhalednitric oxide. If such management does not lead to improvement,however, treatment with nitric oxide, whether there is echocardiographicevidence of pulmonary hypertension or not, will substantiallyreduce the number of infants who receive extracorporeal membraneoxygenation.
Inhaled nitric oxide reduced the use of extracorporeal membraneoxygenation in critically ill neonates born at or near termwith hypoxic respiratory failure who had received maximal conventionaltherapy. Nitric oxide therapy was safe, well tolerated, andrelatively easy to administer.
Supported in part by the Canadian Medical Research Council andby grants (U10 HD21364, U10 HD21385, U10 HD21415, U10 HD27853,U10 HD27856, U10 HD27871, U10 HD27880, U10 HD27881, U10 HD27904,and U01 HD19897) from the National Institute of Child Healthand Human Development (NICHD).
We are indebted to Ohmeda, a member of the BOC Group, for supplyingnitric oxide to the NICHD Neonatal Research Network Centers.
* The members of the Neonatal Inhaled Nitric Oxide Study Groupare listed in the Appendix.
Source Information
Dr. Ehrenkranz, as co-principal investigator of the study, assumes responsibility for the overall content and integrity of the article.
Address reprint requests to Dr. Richard A. Ehrenkranz at the Department of Pediatrics, Yale University School of Medicine, P.O. Box 208064, 333 Cedar St., New Haven, CT 06520-8064.
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Appendix
The Neonatal Inhaled Nitric Oxide Study was a collaborationof the NICHD Neonatal Research Network and the Canadian InhaledNitric Oxide Study Group. The following institutions and investigatorsparticipated in the trial. (Members of the Executive Committeeare indicated by asterisks.) NICHD Neonatal Research Network:Case Western Reserve University, Cleveland — E. Stork,E. Gorjanc; George Washington University, Biostatistics Center,Rockville, Md. — J. Verter,* N. Younes, B.A. Stenzel,T. Powers; Indiana University, Indianapolis — G. Sokol,*D. Appel; NICHD, Bethesda, Md. — L.L. Wright,* S.J. Yaffe,C. Catz; Stanford University, Palo Alto, Calif. — K. VanMeurs, W. Rhine,* B. Ball; University of Cincinnati, Cincinnati— R. Brilli, L. Moles; University of New Mexico, Albuquerque— M. Crowley, C. Backstrom; University of Tennessee atMemphis — D. Crouse, T. Hudson; Wayne State University,Detroit — G. Konduri,* R. Bara; Women and Infants' Hospital,Providence, R.I. — M. Kleinman, A. Hensman, R.W. Rothstein;Yale University, New Haven, Conn. — R.A. Ehrenkranz* (co-principalinvestigator). Canadian Inhaled Nitric Oxide Study Group: BritishColumbia Children's Hospital, Vancouver — A. Solimano,*F. Germain; Children's Hospital of Eastern Ontario, Ottawa —R. Walker, A.M. Ramirez; Foothills Hospital, Calgary, Alta.— N. Singhal, L. Bourcier; Health Sciences Center, Winnipeg,Man. — C. Fajardo, V. Cook; McMaster University, Hamilton,Ont. — H. Kirpalani,* S. Monkman; Montreal Children'sHospital, Montreal — A. Johnston,* K. Mullahoo; RoyalAlexandra Hospital, Edmonton, Alta. — N.N. Finer* (co-principalinvestigator), A. Peliowski, P. Etches, B. Kamstra; Royal UniversityHospital, Saskatoon, Sask. — K. Sankarhan, A. Riehl; Universitéde Sherbrooke, Sherbrooke, Que. — P. Blanchard, R. Gouin;Texas Children's Hospital, Houston — M. Wearden, M. Gomez,Y. Moon. NICHD Neonatal Research Steering Committee: Universityof Miami, Miami — C.R. Bauer; University of Cincinnati,Cincinnati — E.F. Donovan; Yale University, New Haven,Conn. — R.A. Ehrenkranz; Case Western Reserve University,Cleveland — A.A. Fanaroff; University of Tennessee atMemphis — S.B. Korones; Indiana University, Indianapolis— J.A. Lemons; Women and Infants' Hospital, Providence,R.I. — W. Oh; University of New Mexico, Albuquerque —L.A. Papile; Wayne State University, Detroit — S. Shankaran;Stanford University, Palo Alto, Calif. — D.K. Stevenson;Emory University, Atlanta — B.J. Stoll; University ofTexas Southwestern Medical Center, Dallas — J.E. Tyson;George Washington University, Biostatistics Center, Rockville,Md. — J. Verter; NICHD, Bethesda, Md. — L.L. Wright.Data Safety and Monitoring Committee: Children's Hospital NationalMedical Center, Washington, D.C. — G. Avery (chairman);New England Medical Center, Boston — M. D'Alton; YaleUniversity, New Haven, Conn. — M.B. Bracken; NICHD, Bethesda,Md. — C. Catz (executive secretary); Johns Hopkins Hospital,Baltimore — C.A. Gleason; University of Pennsylvania,Philadelphia — M. Maguire; University of Pittsburgh, Pittsburgh— C. Redmond; Greenbrae, Calif. — W. Silverman;McMaster University, Hamilton, Ont. — J. Sinclair; GeorgeWashington University, Biostatistics Center, Rockville, Md.— J. Verter (ex officio).
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A correction has been published: N Engl J Med 1997;337(6):434.
