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Factors affecting the incidence of chronic lung disease of prematurity in 1987, 1992, and 1997

Abstract

OBJECTIVE To determine changes in the incidence of chronic lung disease of prematurity between 1987, 1992, and 1997.

METHODS Observational study based on data derived from a geographically defined population: Trent Health Region, United Kingdom. Three time periods were compared: 1 February 1987 to 31 January 1988 (referred to as 1987); 1 April 1992 to 31 March 1993 (referred to as 1992); 1997. All infants of ⩽ 32 completed weeks gestation born to Trent resident mothers within the study periods and admitted to a neonatal unit were included. Rates of chronic lung disease were determined using two definitions: (a) infants who remained dependent on active respiratory support or increased oxygen at 28 days of age; (b) infants who remained dependent on active respiratory support or increased oxygen at a corrected age of 36 weeks gestation.

RESULTS Between 1987 and 1992 there was a fall in the birth rate, but a significant increase was noted in the number of babies of ⩽ 32 weeks gestation admitted to a neonatal unit. There was no significant change in survival when the two groups of infants were directly compared. However, mean gestation and birth weight fell. Adjusting for this change showed a significant improvement in survival (28 day survival: odds ratio (OR) = 1.69; 95% confidence interval (95% CI) = 1.23 to 2.33. Survival to 36 week corrected gestation: OR = 1.45; 95% CI = 1.06 to 1.98). These changes were accompanied by a large increase in the incidence of chronic lung disease even after allowing for the change in population characteristics (28 day definition: OR = 2.20; 95% CI = 1.47 to 3.30. 36 week definition: OR = 3.04; 95% CI = 1.91 to 4.83). Between 1992 and 1997 a different pattern emerged. There was a further increase in the number of babies admitted for neonatal care at ⩽ 32 weeks gestation despite a continuing fall in overall birth rate. Survival, using both raw data and data corrected for changes in gestation and birth weight, improved significantly in 1997 (adjusted data: 28 day survival: OR = 1.72 (95% CI = 1.22 to 2.38); survival to 36 week corrected gestation: OR = 1.90 (95% CI = 1.36 to 2.64)). Rates of chronic lung disease showed no significant change between 1992 and 1997 despite improved survival (adjusted data: 28 day definition: OR = 0.72 (95% CI = 0.50 to 1.03); 36 week definition: OR = 0.88 (95% CI = 0.61 to 1.26).

CONCLUSIONS Current high rates of chronic lung disease are the result of policies to offer neonatal intensive care more widely to the most immature infants. Recent improvements in survival have been achieved without further increases in the risk of infants developing chronic lung disease.

  • prematurity
  • chronic lung disease
  • respiratory disease
  • incidence

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In the 30 years since bronchopulmonary dysplasia was first described in preterm infants,1 a huge medical literature has evolved on the topic and its implications. There is no doubt that chronic lung disease (CLD) remains a major problem in neonatal units. Reported estimates of incidence and time trends have shown great variation, but many of these studies have been based on hospital populations that are not ideal for such work because of the potential for referral bias.2-6

Even the most widely tested developments in care have been difficult to assess in terms of their impact on the incidence of CLD. Randomised trials were generally focused (and hence sized) on acute outcomes such as death. Subsequent meta analyses have provided insight into the effect of surfactant and antenatal steroids on CLD.7-11Many other treatments have been introduced into neonatal intensive care—for example, oscillatory ventilation, trigger ventilation, postnatal steroids, nitric oxide, increased use of constant positive airway pressure (CPAP)—with much less careful assessment. The overall effect of these, even on survival, is not clear.

Given the major innovations that have taken place in perinatal care in recent years, we wished to investigate the extent to which the incidence of the condition had changed using a large geographically defined population.

Methods

The Trent Neonatal Survey (TNS) is a continuing study of neonatal intensive care activity in the Trent Health Region (United Kingdom) and has been described previously.12

Trent has a population of roughly 4.6 million and there are about 60 000 births per year. The region is recognised as being representative of England and Wales as a whole.

Three time periods spanning 10 years were chosen to investigate changes in the incidence of CLD:

  • 1 February 1987 to 31 January 1988, the earliest data available from the TNS. For descriptive purposes we termed this period 1987.

  • 1 April 1992 to 31 March 1993. An expansion of the dataset on 1 April 1992 made this period more suitable than the calendar year 1992. Nonetheless for descriptive purposes we termed this period 1992.

  • 1997. The whole year of 1997 was used.

We used both of the common definitions of CLD2 ,13:

  • infants who remain dependent on active respiratory support or increased oxygen at 28 days of age;

  • infants who remain dependent on active respiratory support or increased oxygen at a corrected age of 36 weeks gestation.

STATISTICAL ANALYSIS

Distribution free analysis of variance (Kruskal-Wallis test ) was used to compare median gestation and Apgar scores over the three reported years. Changes in birth weight adjusted for study year and gestation were investigated using a weighted least squares regression model. The odds ratios (OR) for survival and CLD were estimated using logistic regression modelling. Other variables were compared using a χ2 test, or a χ2 test for trend where appropriate. SAS v6.12 was used for all analyses.

Results

During the 10 years spanned by the study, the total number of births in the region fell from 61 050 to 55 780 per year. However, this change was accompanied by a significant increase (p<0.001) in the number of infants of ⩽ 32 completed weeks gestation admitted to a neonatal unit (802 to 934). Similarly median gestation fell by one week (χ2(df = 2) = 12.9; p = 0.0016). Closer examination (Mann-Whitney test) suggested that there was a significant difference between 1987 and 1992 (p = 0.0018), but not 1992 and 1997 (p = 0.96). After differences in gestation were taken into account, there was evidence of a reduction in mean birth weight across the three time periods (p = 0.027). Comparison of 1987 with 1992 showed a fall of 13 g, with a fall of 17 g between 1992 and 1997.

No change in median Apgar score was noted between the years, and male to female ratio was similarly constant, with about 57% of infants being male in each year. Not surprisingly, both antenatal steroid and surfactant use increased significantly during the period (p<0.001 for both; surfactant was not commercially available in 1987 and antenatal steroid use was not established practice). There was also an increase in the proportion of babies born by caesarean section (p<0.001) but not in the proportion requiring ventilation (p = 0.85).

When survival at 28 days in 1987 was compared directly with that in 1992, no significant difference was seen (OR = 1.15; 95% CI = 0.88 to 1.49). However, comparing 1992 with 1997 showed a significant improvement (OR = 1.49; 95% CI = 1.13 to 1.97). The same pattern was seen with survival to 36 weeks (1987 v1992: OR = 1.02 (95% CI = 0.79 to 1.32); 1992v 1997: OR = 1.57 (95% CI = 1.20 to 2.06). Table 1 shows data on survival at 28 days of age and 36 weeks corrected gestation, adjusted for the changes in birth weight and gestation described above. Correcting for the change in birth weight and gestation of the population showed a significant improvement in the odds ratio for survival for both time comparisons and age cut offs.

Table 1

Survival of infants of ⩽ 32 weeks gestation, admitted for neonatal care, at 28 days of age and 36 weeks corrected gestation

Table 2 shows the rates of CLD in the three time periods with the relevant comparisons. The data by both definitions show the same pattern. Improved survival between 1987 and 1992 resulted in a large increase in CLD. Improved survival between 1992 and 1997 did not produce a similar change. The data from the latter comparison show a trend suggesting that the risk of developing CLD was decreased, but this did not reach statistical significance. However, in 1997 an increasing proportion of infants received constant positive airway pressure (CPAP) alone as their active respiratory support. If these infants are included with the ventilated group who survived 28 days, the odds ratio for CLD (28 day definition) shows a statistically significant fall between 1992 and 1997 (1992, n = 366; 1997, n = 459; OR for CLD adjusted for birth weight and gestation 0.63 (95% CI 0.44 to 0.89)).

Table 2

Rates of chronic lung disease (CLD), using the 28 day and 36 week definitions

Discussion

During the last decade there has been a good deal of speculation about whether, and to what extent, the incidence of CLD has changed. This study provides an insight into the nature of the changes that have occurred in Trent in recent years, and these are likely to have been paralleled in many developed countries.

Of fundamental importance appears to be the increased number of babies of ⩽ 32 weeks gestation being admitted to neonatal units during the study period. Although similar changes are likely to have occurred elsewhere, the time scale for such changes may well have varied, certainly between countries and perhaps even different regions of the same country. Variation of this type may well explain some of the apparent differences between what appear to be similar neonatal services. Without data to assess such variation in practice, it will remain difficult, if not impossible, to assess reliably performance over time or between individual units.4 ,6 ,14

In terms of CLD, the two time periods considered show quite different patterns. Between 1987 and 1992, as more infants of ⩽ 32 weeks gestation were admitted for intensive care, survival improved, but this was associated with a large rise in the number of babies who developed CLD (double by the 28 day definition, treble by the 36 week definition). In contrast, a somewhat greater improvement in survival between 1992 and 1997 was accompanied by no statistically significant change in the risk of CLD. The trend in the data for this second time period suggests that the risk of developing CLD may have fallen, but the change did not reach statistical significance. The improved outcome noted when infants treated with CPAP only were included in the comparison groups should be considered with caution because opinions on CPAP as an alternative, albeit unproven, to ventilation changed considerably between 1992 and 1997.15 ,16 Given the nature of the population, with care being given by 16 different hospitals, it is impossible to equate the better performance in relation to CLD during the second five year period to a particular strategy of care, such as permissive hypercapnia,2 or new intervention, such as oscillation, because only one or two institutions have joint protocols.

Currently there are a number of theories about the causes of CLD. These can be broadly divided into those that point to a major influence of in utero factors, particularly infection or inflammation,6 ,17-19 and those relating to exposures after birth,6 ,20 especially the nature and extent of respiratory support. The data from this study were obtained at a time when various strategies were being used to improve the package of supportive care available to the preterm infant. No comparable measures were in place to try to alter the inflammatory exposure of the infant while in utero. It seems therefore that the changes observed reflect the interaction of ex utero care and the infants maturity, confirming the importance of interventions such as ventilation in the production of CLD. The influence of in utero events is likely to have been a constant factor during the study and, given the continuing health economic importance of CLD, probably offers the best opportunity for new research to make a genuine impact on the condition.

Acknowledgments

We wish to acknowledge the continuing help and collaboration of the hospitals delivering perinatal care in both Trent and adjacent regions. This study is one of the Trent Infant and Mortality and Morbidity Studies (TIMMS), which are funded by the Trent Regional Health Service. E S D is supported by a grant from Leicestershire Health Authority.

References