Birth weight and risk of cardiovascular disease in a cohort of women followed up since 1976
BMJ 1997; 315 doi: https://doi.org/10.1136/bmj.315.7105.396 (Published 16 August 1997) Cite this as: BMJ 1997;315:396- Janet W Rich-Edwards, instructor (nhjre{at}gauss.bwh.harvard.edu)b,
- Meir J Stampfer, professord,
- JoAnn E Manson, associate professorb,
- Bernard Rosner, professorc,
- Susan E Hankinson, assistant professorc,
- Graham A Colditz, professorc,
- Charles H Hennekens, professorb,
- Walter C Willet, professord
- a Department of Medicine, Brigham and Women's Hospital and Harvard Medical School, Boston, MA 02215, USA
- b Division of Preventive Medicine
- c Channing Laboratory
- d Department of Nutrition, Harvard School of Public Health, Boston, MA 02115, USA
- Correspondence to: Dr J W Rich-Edwards Department of Ambulatory Care and Prevention, Harvard Pilgrim Health Care and Harvard Medical School, 126 Brookline Avenue, Suite 200, Boston, MA 02215, USA
- Accepted 2 July 1997
Abstract
Objective: To examine the association between birth weight and non-fatal adult cardiovascular disease while controlling for potential confounders such as socioeconomic group and adult lifestyle.
Design: Retrospective self report of birth weight in an ongoing longitudinal cohort of nurses followed up by postal questionnaire every two years.
Setting: Nurses' health study, a cohort of 121 700 women followed up since 1976.
Main outcome measures: Non-fatal cardiovascular disease, including myocardial infarction, coronary revascularisation, and stroke.
Results: Among the 70 297 women free of cardiovascular disease at baseline who reported birth weight in the 1992 questionnaire there were 1309 first cases of non-fatal cardiovascular disease. Increasing birth weight was associated with decreasing risk of non-fatal cardiovascular disease. There were 1216 first cases of non-fatal cardiovascular disease among women who were singletons and had been born full term; their relative risks adjusted for several cardiovascular risk factors were 1.49 (95% confidence interval 1.05 to 2.10) for birth weight <2268 g (<5 lb 0 oz); 1.25 (0.98 to 1.61) for birth weight 2268-2495 g (5 lb 0 oz to 5 lb 8 oz); 1.12 (0.98 to 1.27) for birth weight >2495-3175 g (>5 lb 8 oz to 7 lb 0 oz); 1.00 (referent) for birth weight >3175-3856 g (>7 lb 0 oz to 8 lb 8 oz); 0.96 (0.80 to 1.15) for birth weight >3856-4536 g (>8 lb 8 oz to 10 lb 0 oz); and 0.68 (0.46 to 1.00) for birth weight >4536 g (>10 lb 0 oz) (P value for trend=0.0004). The inverse trend was apparent for both coronary heart disease and stroke.
Conclusions: These data provide strong evidence of an association between birth weight and adult coronary heart disease and stroke.
Key messages
Birth weight and mortality from cardiovascular disease are inversely associated in adult women
This study found that birth weight and the risk of non-fatal cardiovascular disease is also inversely associated in adult women for both coronary heart disease and stroke
This association is driven by the 13% of women born at the extremes of birth weight
It seems to be largely independent of established cardiovascular risk factors also associated with birth weight: adult body weight, hypertension, and diabetes
It is not weakened by controlling for childhood socioeconomic group or adjusting for adult lifestyle
Introduction
As interest has grown in early determinants of cardiovascular disease, it has been hypothesised that indicators of adult cardiovascular risk are manifest even at birth. Birth weight and other measures of prenatal growth have been associated with adult blood pressure,1 2 3 4 5 6 7 diabetes,4 5 8 9 10 11 body fat distribution,4 5 12 and, less consistently, lipid concentrations.4 13 An inverse association between birth weight and death and illness from coronary heart disease has been reported among men14 15 and women16 in England. We examined the association between birth weight and non-fatal cardiovascular disease among women in the United States who had been born between 1921 and 1946.
Subjects and methods
The nurses' health study was established in 1976, when 121 701 American female registered nurses aged 30 to 55 years responded to postal questionnaires on their medical histories and lifestyles.17 We excluded the 1709 women who had prevalent cardiovascular disease at baseline. There were 5341 deaths between 1976 and 1992 (including 723 deaths from cardiovascular disease). Of the women who were alive in 1992, 11 863 did not respond to the 1992 questionnaire and a further 32 491 women did not report their birth weight. This analysis includes the 70 297 participants who were free from coronary heart disease and stroke in 1976 and who reported their birth weight.
The 1976 questionnaire requested information about past and current risk factors for cardiovascular disease. Follow up questionnaires were posted every two years to elicit updated information on exposure variables and the incidence of myocardial infarction, angina, coronary revascularisation, and stroke. In 1992 the women indicated their birth weight in categories of pounds. These were not sure, <5 lb, 5 lb to 5½ lb, >5½ lb to 7 lb, >7 lb to 8½ lb, >8½ lb to 10 lb, and >10 lb, which in this paper are <2268 g, 2268-2495 g, >2495-3175 g, >3175-3856 g, >3856-4536 g, and >4536 g respectively. The women also said whether they had been born full term or two or more weeks prematurely and whether they were one of a multiple birth (hereafter referred to as twins).
Validation of self reported birth weight
The validity of self reported birth weights was tested among a younger cohort of female nurses aged 27-44 years.18 Birth weight was obtained from 220 state birth certificates, and 70% of participants reported the same birth weight category as their birth certificate.18 The Spearman correlation between categories of self reported and recorded birth weight was 0.74. Participants who were aged 27-34 and 35-44 years recalled their birth weights with similar accuracy.
Documentation of end points
Because we obtained information in 1992 on birth weight we were able to consider only non-fatal cardiovascular end points that occurred between the 1976 and 1992 questionnaires. Permission to review medical records was sought from participants who reported a non-fatal myocardial infarction or stroke. The records were reviewed by doctors who were blind to the risk factors of the participants. Non-fatal myocardial infarctions and strokes for which we could not obtain hospital records but which required admission and were corroborated by additional information in a letter or from a telephone interview were classed as probable events.
Non-fatal myocardial infarctions were classed as confirmed if they met the criteria of the World Health Organisation: symptoms and either diagnostic electrocardiographic changes or raised cardiac enzyme activities.19 Thus, silent infarctions and those occurring at an indeterminate time that had been discovered on routine examination were excluded. We combined 507 confirmed and 85 probable cases of non-fatal myocardial infarction because the results did not differ when we considered only confirmed cases. Coronary artery bypass grafting and angioplasty were self reported on the questionnaires.
Stroke was classified according to the criteria established by the national survey of stroke.20 We required evidence of a typical neurological deficit of sudden or rapid onset that persisted for more than 24 hours. Stroke classifications included ischaemic stroke due to thrombotic or embolic occlusion of a cerebral artery or haemorrhagic stroke due to subarachnoid or intraparenchymal haemorrhage. The results were similar when the 67 probable strokes were analysed with the 322 confirmed strokes, so both were combined in this analysis.
We examined the incidence of total non-fatal coronary heart disease (including non-fatal myocardial infarction and coronary artery bypass grafting or percutaneous transluminal coronary angioplasty) and total non-fatal stroke (including ischaemic, haemorrhagic, and unclassified strokes) before separately examining myocardial infarction, coronary revascularisation, and the stroke subtypes. Because the results were similar for coronary heart disease and stroke, these end points were combined as a non-fatal cardiovascular end point.
Statistical analysis
Age adjusted means and prevalence of baseline characteristics were obtained by direct standardisation to the overall age distribution in years.21 Incident cases of cardiovascular disease were assigned to the birth weight categories, with follow up dating from the return of the baseline questionnaire in 1976 to the date of occurrence of disease or 1 June 1992, whichever came first. The odds ratio was used to compare the odds of disease for women in a given birth weight category compared with that of women who weighed >3175-3856 g at birth. To assess trend across categories, each birth weight category was assigned a representative value in an ordinal variable (2155 g, 2381 g, 2835 g, 3515 g, 4196 g, and 4649 g). Two sided P values and 95% confidence intervals are presented.
All analyses were adjusted for age in years as a continuous variable; multivariate relative risks were derived from proportional hazards models22 including terms as specified in the tables and text. As information on alcohol consumption, saturated fat intake, and physical activity was first collected in 1980, analyses considering these variables include follow up from 1980 to 1992. Similarly, analyses using the ratios of waist to hip circumference include follow up from 1986 to 1992.
Results
As reported previously,7 birth weight was associated with age, adult body mass index (weight (kg)/height (m)2), adult hypertension, raised cholesterol concentration, and diabetes (table 1). The heavier the nurse was at birth the less likely it was that her father had been a manager or professional when the nurse was a child and the less likely it was that the nurse's mother smoked during the nurse's childhood. No associations were evident between birth weight and variables reflecting the nurse's adult lifestyle.
From 1976 to 1992, 889 cases of first non-fatal coronary heart disease occurred among women who were singletons and had been born full term, including 461 cases of non-fatal myocardial infarction and 428 cases of coronary revascularisation. An inverse association between birth weight and non-fatal coronary heart disease was evident after adjustment for age (table 2).
Adjustment for baseline hypertension (yes/no) and history of diabetes mellitus (yes/no) somewhat attenuated the association between lower birth weight and non-fatal coronary heart disease, while adjustment for baseline body mass index (in tenths) strengthened the association between higher birth weight and reduced incidence of non-fatal coronary heart disease (table 2). In a multivariate model including these factors, as well as cigarette smoking, parental history of myocardial infarction before the age of 60, raised cholesterol concentration, menopausal state, and the use of postmenopausal hormones, there was a 5% decrease (95% confidence interval 0% to 9%) in the risk of non-fatal coronary heart disease for every 454 g increase in birth weight. Inclusion of 3347 women who had been born prematurely, 52 of whom had coronary heart disease, made little difference to the relative risks associated with birth weight.
Non-fatal myocardial infarction and coronary revascularisation were examined separately (table 2). The inverse association in the multivariate model described above seemed to be stronger for coronary revascularisation than for myocardial infarction.
From 1976 to 1992, 364 cases of non-fatal stroke occurred among women who were singletons and had been born full term. A strong inverse association was seen between birth weight and the incidence of non-fatal stroke (table 3). As for coronary heart disease, adjustment for hypertension and diabetes somewhat dampened the association between the lowest category of birth weight and stroke, while control for body mass index had a slight influence on the heaviest category of birth weight. In the multivariate model there was an 11% (5% to 8%) decrease in the risk of non-fatal stroke for every 454 g increase in birth weight. When 3347 women who had been born prematurely were included, 17 of whom had stroke, the trend was somewhat dampened (z for trend=-2.99, P=0.002). The inverse trend between birth weight and non-fatal stroke was similar for ischaemic and haemorrhagic stroke (table 3).
Further analyses adjusting for height, aspirin use, alcohol consumption, saturated fat consumption, physical activity, ratio of waist to hip circumference, ethnic group, and whether the nurse's mother smoked cigarettes when the nurse was a child or had diabetes did not materially change the relative risk estimates for myocardial infarction or stroke. Neither did adjustment for socioeconomic group when the nurse was 16 (10 categories each for maternal and paternal occupation when she was 16), her husband's education, whether she was born prematurely, whether she was one of twins or a multiple birth, and whether she had been breast fed.
Figure 1 shows the multivariate association between birth weight and total non-fatal cardiovascular disease among women who were singletons and had been born full term (z for trend=-3.61, P<0.001. The trend was somewhat strengthened by eliminating hypertension, diabetes, and raised cholesterol concentration, which are likely intermediates in the causal pathway between in utero growth and cardiovascular disease (z for trend=-4.12, P<0.00001; data not shown). The inverse trend was not eliminated by removing body mass index from the full multivariate model (z for trend=-2.91, P=0.002).
Discussion
In this cohort of women aged 46 to 71 in 1992 birth weight was inversely related to the incidence of non-fatal coronary heart disease and stroke. The association was driven by the small proportion of women at the extremes of birth weight; if there is a difference in cardiovascular risk among the 87% of women of normal birth weight (>2495-4536 g) it seems to be minimal.
The age adjusted associations we observed for non-fatal cardiovascular disease are strikingly similar to those observed for fatal cardiovascular disease among British women.16 The association was little affected by such potential confounding variables as cigarette smoking, ethnic group, and socioeconomic group. Birth weight is presumably a marker for risk factors directly linked to cardiovascular disease. That the association persisted despite adjustment for hypertension, diabetes, raised cholesterol concentration, height, and body mass index suggests that birth weight is associated with adult cardiovascular risk primarily through other pathways. Childhood socioeconomic group cannot explain our results because the heavier infants tended to be from the poorer socioeconomic groups. In this study we did not have information on several factors known to influence birth weight, including maternal diet, blood pressure, and hormone concentrations during pregnancy.
The results of the validation study indicate that there is some misclassification of self reported birth weight. However, such misclassification is likely to have been random with respect to disease and would have led to underestimation of relative risks.
We were unable to include women who died before 1992. However, the small numbers of deaths cannot explain these findings unless there was a strong tendency for women of normal and high birth weight to develop fatal (as opposed to non-fatal) cardiovascular disease. To invoke missing data to explain the observed association requires a scenario in which we were disproportionately missing women who both had a low birth weight and did not have cardiovascular disease as well as women who had a high birth weight and did have cardiovascular disease. Such a pattern of selectively missing data seems unlikely.
In summary, a moderate but consistent inverse association was observed between birth weight and cardiovascular risk that persisted despite control for a number of risk factors. Women who had a low birth weight (2495 g or less) had a significantly increased risk (by 23%) of non-fatal cardiovascular disease compared with all other women. Only 11% of this cohort born between 1921 and 1946 had a low birth weight. Thus, a low birth weight was associated with no more than 2% of the non-fatal cardiovascular disease in this cohort. This figure would be lower for the generation of children born today because the prevalence of low birth weight in the United States was 7% in 1990.23
Although these data suggest that cardiovascular benefits might be reaped from interventions to reduce low birth weight, it is not clear which of the many environmental or genetic factors that determine birth weight might also affect cardiovascular risk. Birth weight is only a crude marker of intrauterine development; further research is needed to identify whether there is a specific mechanism that affects both birth weight and risk of cardiovascular disease in adulthood.
Acknowledgments
We are grateful for the leading role of Dr Frank Speizer as principal investigator of the nurses' health study and for the dedication of the registered nurses participating in this study.
Funding: The nurses' health study is supported by research grants HL 34594 and CA 40356 from the National Institutes of Health. JWR-E was supported by institutional training grant HL-07575 from the National Heart, Lung and Blood Institute.
Conflict of interest: None.