Morbidity and Mortality in Late-Preterm Infants: More than Just Transient Tachypnea!

Article Outline

• References
• Copyright

Concern about higher morbidity in late-preterm (34^0/7 to 36^6/7 weeks) infants has led to a flurry of recent publications with largely the same conclusions: late-preterm infants are more prone to problems related to delayed transition and overall immaturity, and they should therefore be treated differently than their more mature term counterparts.¹, ², ³, ⁴, ⁵ These observations have led to greater attention being paid to tracking short-term morbidity, healthcare costs, hospital stays, and issues such as re-hospitalization.⁵ However, widespread publicity has yet to make a measurable impact on the incidence of late prematurity; nearly 3 out of 4 preterm births occur at late-preterm gestations and this number is on the rise.⁶ It is estimated that nearly 250,000 late-preterm births occurred in the US in 2004; and although the problem appears to be widespread, similar estimates from other nations are not readily available.

A broad range of neonatal complications has been documented in the growing body of literature on late-preterm infants. These problems include delayed lung fluid clearance (transient tachypnea of the newborn), respiratory distress syndrome, pulmonary hypertension, apnea, temperature instability, hypoglycemia, jaundice, and poor feeding.⁶ Little, however, is known about the long-term impact of these “transitional issues” because there are no data repositories with information about outcomes, and, in spite of growing concern about the vulnerability of the late-preterm brain to white matter injury, systematic developmental assessments are seldom performed.

These publications notwithstanding, the obstetric community is yet to fully embrace the public health impact of late prematurity. Late-preterm infants are considered functionally mature (hence the widespread use of the “near term” label), and there is a relative lack of attention to neonatal considerations when delivery at these gestations is being contemplated. Although women in preterm labor at gestations 33 weeks and less are routinely considered for tocolysis and antenatal steroids, they are candidates for neither if gestation has advanced by a few days and crosses over to the magic 34-week mark. These decisions appear oblivious to the fact that inaccuracies in the estimation of gestational age abound, and up to 50% of infants at 34 weeks gestation may require intensive care.¹

What then will it take to drive a concerted effort to tackle this problem? A good starting point will be the availability of reliable data about short- and long-term outcome of late-preterm infants and documentation of serious morbidity that could dispel the myth of the “transient” nature of late-preterm woes. Recent reports about the occurrence of serious complications such as hypoxic respiratory failure and kernicterus are good first steps, and compilation of accurate mortality statistics would be another.², ⁷ In this issue of The Journal, Tomashek et al⁸ attempt to close the gap in our understanding of differences in mortality between late-preterm and term infants. Using period linked birth-infant death files from 1995 to 2002, the authors analyzed overall and cause-specific mortality rates for singleton late-preterm and term infants. The authors report that although significant declines in mortality were observed over the last decade for both groups of infants, the infant mortality rate for late-preterm infants was several-fold higher than that for term infants. Late-preterm infants were particularly more likely to die in the early neonatal period compared with term infants from causes such as respiratory compromise, maternal complications of pregnancy, and congenital anomalies.

The report by Tomashek et al is being highlighted for several reasons. First, although their data clearly demonstrate a higher mortality burden related to birth at late-preterm gestations, the magnitude of the reported difference is particularly striking. Problems associated with the use of large databases such as the one used by the authors notwithstanding, the low frequency of death in term and near-term infants precludes other methodological approaches including the use of smaller (but more detailed) local data sources for such analyses. This report underscores the need for prospective data collection to confirm the overall excess in mortality—information that is critical for affecting a change in allocation of resources and for an overall change in our approach to these neonates.

Second, this work sheds new light on the causes of death in late-preterm infants. For example, the reported high occurrence of congenital anomalies in late-preterm infants raises several questions that need to be addressed in future studies. Are fetuses with serious congenital anomalies more likely to be delivered early either spontaneously or electively, given the widespread practice of “controlled” delivery of an anomalous fetus? Does prematurity and lack of spontaneous labor add to the risk of death in infants with congenital anomalies? Are late-preterm infants at higher risk of death if infants with congenital anomalies are excluded? To address the last issue, the authors performed additional analysis of their data after excluding infants with any congenital malformation, deformation, or chromosomal abnormality (ICD-10Q00-99) as the underlying cause of death. The differences in infant mortality between late-preterm and term infants were found to persist even with these exclusions, underscoring the inherent vulnerability of the late-preterm infant to serious morbidity and death.

There are several limitations to the methodology used and, as such, to any conclusions drawn from data linked to death certificates.⁸ Death certificates lack information about contributing causes of death that could shed more light on diagnostic categories such as “atelectasis.” Autopsy findings were also not available to ascertain diagnoses such as sudden infant death syndrome (SIDS). Finally, data reported on gestational age may be subject to misclassification, although, as the authors argue, such errors should impact both subgroups included in the analysis. However, the hypothesis generated by these data that now needs further testing is straightforward: Are late-preterm infants at higher risk for death than their term counterparts, and, if so, why?

Overall, it should come as no surprise that the higher morbidity reported in late-preterm infants may be associated with an increase in mortality as well. What is surprising is the magnitude of the difference in death rates between late-preterm and term infants, given the perception of mild and transient nature of these problems. The findings should also foster debate around the rationale for preterm delivery, particularly when the decision to do so is based on soft indications. Although the data provide no direct link to the widespread practice of induction of labor and/or elective cesarean sections, it raises questions about the recent rise in such practices, particularly in the face of uncertainty in accurate estimation of gestational age. As such, future occurrences of serious morbidity/death in electively delivered late-preterm infants where a clear indication for early delivery is lacking should call for a thorough peer review of the circumstances around delivery and the subsequent care of the neonate. Finally, there is an urgent need to study the role of strategies to enhance maturity of the late-preterm fetus, such as the use of antenatal steroids. Given the large number of deliveries at late-preterm gestations, the public heath impact of such preventive strategies could be enormous.

Back to Article Outline

References 

1. Dudell GG, Jain L. Hypoxic respiratory failure in the late preterm infant. Clin Perinatol. 2006;33:803–830
   • View In Article
   • Full Text
   • Full-Text PDF (344 KB)
   • CrossRef
2. Jain L, Dudell GG. Respiratory transition in infants delivered by cesarean section. Semin Perinatol. 2006;30:296–304
   • View In Article
   • Abstract
   • Full Text
   • Full-Text PDF (332 KB)
   • CrossRef
3. Raju TN, Higgins RD, Stark AR, Leveno KJ. Optimizing care and outcome for late-preterm (near-term) infants: a summary of the workshop sponsored by the National Institute of Child Health and Human Development. Pediatrics. 2006;118:1207–1214
   • View In Article
   • CrossRef
4. Wang ML, Dorer DJ, Fleming MP, Catlin EA. Clinical outcomes of near-term infants. Pediatrics. 2004;114:372–376
   • View In Article
   • CrossRef
5. Escobar GJ, Greene JD, Hulac P, Kincannon E, Bischoff K, Gardner MN, et al. Rehospitalisation after birth hospitalisation: patterns among infants of all gestations. Arch Dis Child. 2005;90:125–131
   • View In Article
   • CrossRef
6. Davidoff MJ, Dias T, Damus K, Russell R, Bettegowda VR, Dolan S, et al. Changes in the gestational age distribution among U.S. singleton births: impact on rates of late preterm birth, 1992 to 2002. Semin Perinatol. 2006;30:8–15
   • View In Article
   • Abstract
   • Full Text
   • Full-Text PDF (342 KB)
   • CrossRef
7. Clark RH. The epidemiology of respiratory failure in neonates born at an estimated gestational age of 34 weeks or more. J Perinatol. 2005;25:251–257
   • View In Article
   • MEDLINE
   • CrossRef
8. Tomashek KM, Shapiro-Mendoza CK, Davidoff MJ, Petrini JR. Differences in mortality between late-preterm and term singleton infants in the United States, 1995-2002. J Pediatr. 2007;151:450–456
   • View In Article
   • Abstract
   • Full Text
   • Full-Text PDF (154 KB)
   • CrossRef