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Bronchopulmonary dysplasia is chronic lung disease of the neonate that typically is caused by prolonged ventilation and is further defined by age of prematurity and extent of O₂ requirement.

Bronchopulmonary dysplasia (BPD) is considered present when there is need for supplemental O₂ in premature infants who do not have other conditions requiring O₂ (eg, pneumonia, congenital heart disease).

Etiology

BPD has a multifactorial etiology.

Significant risk factors include

• Prolonged mechanical ventilation
• High concentrations of inspired O₂
• Infection
• Degree of prematurity

Additional risk factors include

• Pulmonary interstitial emphysema
• High peak inspiratory pressures
• Large end-tidal volumes
• Increased airway resistance
• Increased pulmonary artery pressures
• Male sex

The lungs of premature infants are more vulnerable to the inflammatory changes that result from mechanical ventilation. The development of normal lung architecture is interrupted; fewer and larger alveoli develop, and the interstitium is thickened.

Diagnosis

• National Institute of Child Health and Human Development (NICHD) criteria
• Characteristic x-ray findings

BPD typically is suspected when a ventilated infant is unable to wean from O₂ therapy, mechanical ventilation, or both. Infants typically develop worsening hypoxemia, hypercapnia, and increasing O₂ requirements. Additionally, when an infant cannot be weaned within the expected time, possible underlying disorders, including patent ductus arteriosus and nursery-acquired pneumonia, should be sought.

For diagnosis the patient has to have required at least 28 days of > 21% O₂. Specific additional diagnostic criteria (see Table 2: Respiratory Disorders in Neonates, Infants, and Young Children: National Institute of Child Health and Human Development Criteria for Diagnosis of Bronchopulmonary Dysplasia (BPD)*) have been developed by the NICHD.

Chest x-ray initially shows diffuse haziness due to accumulation of exudative fluid; appearance then becomes multicystic or spongelike, with alternating areas of emphysema, pulmonary scarring, and atelectasis. Alveolar epithelium may slough, and macrophages, neutrophils, and inflammatory mediators may be found in the tracheal aspirate.

Table 2
National Institute of Child Health and Human Development Criteria for Diagnosis of Bronchopulmonary Dysplasia (BPD)* < 32 Wk Gestational Age† ≥ 32 Wk Gestational Age‡ Diagnosis Breathing room air at 36 wk PMA or discharge, whichever comes first Breathing room air by 56 days postnatal age or discharge, whichever comes first Mild BPD Need for < 30% O2 at 36 wk PMA or discharge, whichever comes first Need for < 30% O2 at 56 days postnatal age or discharge, whichever comes first Moderate BPD Need for ≥ 30% O2, positive pressure, or both at 35 wk PMA or discharge, whichever comes first Need for ≥ 30% O2, positive pressure, or both at 56 days postnatal age or discharge, whichever comes first Severe BPD *NOTE: These criteria are in addition to the baseline requirement of > 21% O2 for at least 28 days. †Assessed at 36 wk PMA. ‡Assessed at age 29 to 55 days. PMA = postmenstrual age.

Prognosis

Prognosis varies with severity. Infants who still depend on mechanical ventilation at 36 wk gestation have a 20 to 30% mortality rate in infancy. Infants with BPD have a 3- to 4-fold increased rate of growth failure and neurodevelopmental problems. For several years, infants are at increased risk of lower respiratory tract infections (particularly viral pneumonia or bronchiolitis) and may quickly develop respiratory decompensation if pulmonary infection occurs. The threshold for hospitalization should be low if signs of a respiratory infection or respiratory distress develop.

Treatment

• Nutrition supplementation
• Fluid restriction
• Diuretics
• Inhaled bronchodilators
• O₂ supplementation as needed
• Respiratory syncytial virus (RSV) monoclonal antibody

Treatment is supportive and includes nutritional supplementation, fluid restriction, diuretics, and perhaps inhaled bronchodilators. Respiratory infections must be diagnosed early and treated aggressively. Weaning from mechanical ventilation and supplemental O₂ should be accomplished as early as possible.

Feedings should achieve an intake of 150 calories/kg/day; caloric requirements are increased because of the increased work of breathing and to aid lung healing and growth.

Because pulmonary congestion and edema may develop, daily fluid intake is often restricted to about 120 to 140 mL/kg/day. Diuretic therapy is sometimes used: chlorothiazide Some Trade Names
DIURIL
SODIUM DIURIL
Click for Drug Monograph
10 to 20 mg/kg po bid plus spironolactone Some Trade Names
ALDACTONE
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1 to 3 mg/kg once/day or split into twice-daily doses. Furosemide Some Trade Names
LASIX
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(1 to 2 mg/kg IV or IM or 1 to 4 mg/kg po q 12 to 24 h for neonates and q 8 h for older infants) may be used for short periods, but prolonged use causes hypercalciuria with resultant osteoporosis, fractures, and renal calculi. If long-term diuretic use is required, chlorothiazide Some Trade Names
DIURIL
SODIUM DIURIL
Click for Drug Monograph
is preferred because it has fewer adverse effects. Hydration and serum electrolytes should be monitored closely during diuretic therapy.

Weeks or months of additional ventilator support, supplemental O₂, or both may be required for advanced BPD. Ventilator pressures and fraction of inspired O₂ (Fio₂) should be reduced as rapidly as tolerated, but the infant should not be allowed to become hypoxemic. Arterial oxygenation should be continuously monitored with a pulse oximeter and maintained at ≥ 88% saturation. Respiratory acidosis may occur during ventilator weaning and treatment and is acceptable as long as the pH remains > 7.25 and the infant does not develop severe respiratory distress.

Passive immunoprophylaxis with palivizumab Some Trade Names
SYNAGIS
Click for Drug Monograph
, a monoclonal antibody to RSV, decreases RSV-related hospitalizations and ICU stays but is costly and is indicated primarily in high-risk infants (see Respiratory Viruses: Prevention for indications). During RSV season (November through April), children are given 15 mg/kg IM q 30 days until 6 mo after treatment of the acute illness. Infants > 6 mo also should be vaccinated against influenza.

Systemic or inhaled corticosteroids are discouraged except as a last-resort therapy for established BPD with rapidly worsening pulmonary status and impending death. Informed parental consent is required.

Prevention

Practices for prevention of BPD include

• Use of antenatal corticosteroids
• Prophylactic use of exogenous surfactant in selected high-risk group of infants (eg, < 30 wk gestation)
• Early therapeutic continuous positive airway pressure
• Early use of surfactant for treatment of respiratory distress syndrome
• Prophylactic use of methylxanthines to assist successful early ventilator therapy withdrawal
• Permissive hypercarbia and hypoxemia to achieve low ventilator pressures, volumes, or both
• Prophylactic use of vitamin A (5000 units IM 3 times/wk for a total of 12 doses) for infants with birth weight < 1000 g
• Avoidance of large volumes of fluid
• Early aggressive management of patent ductus arterious

Inhaled nitric oxide seems to be promising and is under investigation.

Last full review/revision March 2009 by Anand D. Kantak, MD; John T. McBride, MD

Content last modified March 2009