Timing and amount of gestational weight gain in association with adverse birth outcomes

Abstract

Background:

Most existing research on gestational weight gain and pregnancy outcomes has not accounted for timing of weight gain. The area under the weight gain curve (AUC) provides a single measure that incorporates both timing of weight gain and total amount gained. This study evaluated predictors and outcomes associated with second- and third-trimester weight gain AUC from the second and third trimester using time-to-event analysis to account for the correlation between gestional weight gain and gestational duration.

Methods:

Our prospective cohort study used data from the LifeCodes study at Brigham and Women’s Hospital. Maternal weights were available from all prenatal and study visits. We used log–poisson models with empirical variance estimation to identify predictors of total AUC from 14 weeks to delivery and Cox proportional hazards models to estimate hazard ratios and 95% confidence intervals for the association between AUC quintile and adverse pregnancy outcomes.

Results:

Compared to the middle quintile, the highest quintile of accumulated pound–days was associated with a decreased hazard of spontaneous preterm birth among multigravid women [Hazard Ratio (HR): 0.44, 95% Confidence Interval (CI) 0.23, 0.84], a decreased hazard of small-for-gestational age (SGA) births (HR 0.65, 95% CI 0.45, 0.92) overall and an increased hazard of large for gestational age (LGA) births among normal and underweight women (HR 3.21, 95% CI 1.50, 6.89)

Conclusion:

In our study, a pattern of gestational weight gain characterized by more rapid gains earlier in pregnancy was associated with improved pregnancy outcomes in some subgroups of pregnant women.

INTRODUCTION

Evidence suggests that the amount of weight gained by most women during pregnancy is considered either excessive or inadequate relative to current Institute of Medicine recommendations.¹ Data from the National Vital Statistics System show that in 2015, only 32% of women giving birth to full-term, singleton infants gained weight within the recommended range by the end of pregnancy, while 48% gained more weight and 21% gained less weight than recommended.¹ Consequently, a large proportion of the pregnant population may be at increased risk for adverse pregnancy outcomes associated with inadequate and excessive weight gain. Numerous studies have linked inadequate gestational weight gain to preterm birth and small-for-gestational age births (SGA) and excessive gestational weight gain to large-for-gestational age births (LGA).^2–14 Promoting adequate gestational weight gain therefore constitutes an important public health issue.

At the same time, the use of total weight gain as a single measure to summarize pregnancy weight gain does not account for an individual’s weight gain pattern.¹⁵ For example, low weight gain in early pregnancy followed by rapid weight gain later may influence the risk of adverse outcomes differently than constant weight gain.¹⁶ The comparatively small number of studies to examine the timing of weight gain point toward potentially critical periods in pregnancy during which weight gain may have a larger impact on outcomes. One study found that low weight gain by 24 weeks of gestation was associated with an increased risk of low birth weight, even if total weight gain was normal.¹⁷ Other studies have shown positive associations between gestational weight and infant birth weight restricted to the first¹⁸ and second trimesters,^18–20 and an inverse association between weight gain in the second and third trimesters and intrauterine growth restriction.²¹ High weight gain solely in the third trimester has been associated with an increased risk for LGA²² whereas low weight gain during this trimester alone has been associated with an increased risk for preterm birth.^{23, 24}

To simultaneously address both the timing of weight gain and the total amount gained, Kleinman et al.²⁵ proposed an area under the curve (AUC) approach. Calculating the area under the gestational weight gain curve provides a single measure which is interpretable as the additional pound–days carried due to pregnancy. Higher accumulated pound–days reflect more weight gained earlier in gestation. Despite the utility of this method, few studies thus far have employed it to assess the relation between gestational weight gain and birth outcomes.^25,26 In addition, while several predictors of overall gestational weight gain have been identified including pre-pregnancy BMI,^{27, 28} parity,²⁸ and socio-demographic factors,^29–32 to our knowledge no information is known regarding predictors of accumulation of pound–days during pregnancy.

An identified shortcoming of the AUC approach is its inherent correlation with gestational duration.¹⁵ Longer pregnancies provide more opportunity to accumulate pound–days. Without accounting for this correlation, studies of the association between the AUC and gestational age-dependent pregnancy outcomes such as preterm birth may be biased. Treating the AUC as a time-varying exposure in a time-to-event analysis will mitigate this source of bias because it ensures that an individual’s AUC at the time of her pregnancy outcome is compared to the AUC among only those individuals with ongoing pregnancies at that gestational age.^15,33 Since maternal weight is rarely measured during each week of gestation, however, this method does necessitate the interpolation of weight values for the weeks in between weight measurements, but simulations have shown that the use of interpolated weights during the intervals between actual measurements can nonetheless yield unbiased estimates^.33

Using data from the ongoing LifeCodes prospective birth cohort at Brigham and Women’s Hospital, we aim in this study determine predictors of the weight gain AUC and to evaluate the association between accumulated pound–days during pregnancy as a time-varying exposure in a time-to-event analysis. We then compare these results to those obtained using gestational-age-standardized total weight gain z-scores as a measure of gestational weight gain, which is similarly uncorrelated with gestational duration¹⁵ but does not account for weight gain pattern.

METHODS

Study Cohort

Participants in this study were pregnant women from the Boston area who attended Brigham and Women’s Hospital for prenatal care and enrolled in the LifeCodes cohort during the period between its initiation in 2006 and September 2015.³⁴ Participation in this cohort involved the completion of study visits that coincide with clinical care at approximately 10 weeks, 24 weeks, and 35 weeks of gestation in addition to attending regular prenatal visits. At the first visit, participants completed a questionnaire that ascertained sociodemographic and health information. First trimester ultrasound was used to validate and/or establish gestational age as needed. Participants were followed until delivery, at which time complications and neonatal anthropometric measurements were recorded. All participants provided written informed consent. The Institutional Review Board at Brigham and Women’s Hospital approved the study. This secondary analysis was limited to singleton pregnancies lasting more than 22 weeks with known dates of delivery, at least 2 recorded weight measurements, an initial weight measurement taken at or before 12 weeks of gestation, and plausible values (± 5 standard deviations (SD) from the cohort mean) for total gestational weight gain at the end of pregnancy.

Assessment of gestational weight gain

Weight measurements were taken at both regular prenatal visits and study visits. Participants’ first available weight measurements are referred to as their initial weights, and BMI calculated from this is referred to as initial BMI. We characterized the AUC as a time-varying exposure, which requires weight measurements for each week of gestation in order for all participants with ongoing pregnancies at the time of a pregnancy outcome to contribute to the risk set. We interpolated weight values for weeks in which weight measurements were unavailable using a linear repeated-measures mixed-effects model with gestational age as the independent variable, weight as the dependent variable, fixed and random effects for the intercept and gestational age terms, and an unstructured variance–covariance matrix. This model produced subject specific slopes and intercepts which were used to interpolate weight values. Each participant therefore had a real or interpolated weight value for each week of gestation starting from the week of their first weight measurement. In a validation study, this interpolation method showed an average difference in real and interpolated weight values of 0.13 lbs at 28 weeks and −0.30 lbs at 40 weeks.³⁵

Starting with measured or interpolated weight at 12 weeks of gestation, we calculated the total accumulated pound–days for each week by summing the areas of trapezoids formed by connecting successive measures of weight gain in pounds perpendicularly with the time axis of the weight curve (gestational age in weeks). If participants had weight values that were smaller than their initial weight measurement, we replaced these values with the pre-pregnancy weight to avoid negative pound–days in accordance with the methodology used by Kleinman et al.²⁵ We then classified accumulated pound–days for each week of gestation into quintiles based on the distribution of the study population for that specific week. In stratified analyses (BMI < 25 vs ≥25, primigravid vs. multigravid), we calculated quintile distributions for each stratum separately.

We also classified total gestational weight gain according to gestational-age standardized z-scores using reference charts specifically developed for normal, overweight, and obese pregnant women.^36,37 We calculated total weight gain as the difference between participants’ measured or interpolated weight at the time of delivery and their initial weight. We categorized total weight gain z-scores as <−1 SD, −1 SD to +1 SD, and >+1 SD to facilitate interpretability.

Pregnancy Outcomes

We defined spontaneous preterm births as delivery before 37 weeks with presentation of spontaneous labor or preterm premature rupture of the membranes.³⁸ All cases of preterm birth were independently validated by a panel of board-certified maternal–fetal medicine physicians. Infant weights were recorded in their medical records immediately after birth. We considered infants weighing below the 10^th percentile for gestational age at delivery according to population reference standards³⁷ to be SGA and those weighing above the 90^th percentile to be LGA. Weight for gestational-age z-scores were calculated according to U.S. national reference data.³⁹

Covariates

We chose the following as potential predictors of pound–days accumulated by the end of pregnancy and potential confounders in the analyses of pound–days and pregnancy outcomes: age (< 25, 25 – <30, 30 – <35, ≥ 35 years), initial BMI (continuous), maternal height (continuous), gravidity (0, 1, 2, ≥ 3), current smoking reported at baseline (yes/no), race/ethnicity (Caucasian, African American, Asian, Hispanic, Other), insurance status (private/self-pay, public/none), education (high school or less, some college, college graduate, graduate school), history of diabetes (yes/no), history of chronic hypertension (yes/no), history of thyroid disease (yes/no), gestational diabetes (yes/no), gestational hypertension (yes/no), and pre-eclampsia (yes/no).

Statistical Analysis

We used generalized linear models with a normal distribution and identity link function to estimate crude and multivariable adjusted beta coefficients and 95% confidence intervals for the associations between each potential predictor and both total accumulated pound–days by the end of pregnancy and gestational weight gain z-score. Gestational age at delivery was also included as a covariate in multivariable models to account for correlated gestational age.

We used Cox proportional hazards regression models with the Andersen-Gill counting method and week of gestation as the time scale to estimate crude and adjusted hazard ratios and 95% confidence intervals for the association between time-varying quintile of accumulated pound–days and time to each pregnancy outcome. In this modeling approach, risk sets are formed that include all participants with equal or longer pregnancy durations, thereby eliminating the dependency of gestational weight gain on gestational length. We used log–poisson regression with empirical variance estimation to estimate crude and adjusted risk ratios and 95% confidence intervals for the associations between total weight gain z-score category and each birth outcome among participants with pregnancies lasting at least 28 weeks (n=1,898).

These models were further stratified by initial BMI category (< 25 kg/m², ≥ 25 kg/m²) and gravidity (primigravid, multigravid), since both have shown to modify associations between gestational weight gain and birth outcomes.^40–42 Medically indicated preterm births are censored at the time of birth in the analysis of AUC quintiles and grouped with full term births in the analysis of gestational weight gain z-scores.

We conducted several post-hoc sensitivity analyses. First, we assessed the impact of excluding women who lost weight during pregnancy, since potential pathologies underlying this weight loss, such as hyperemesis gravidarum, may limit their comparability to the full cohort. Second, we investigated the impact of the interpolated values on the results. In this analysis, we examined the association between each outcome and the weight gain AUC calculated from weight measurements taken at two time-points, 18 and 26 weeks of gestation, which were chosen due to the large number of measured weights available for these weeks. We modeled these associations both among participants with measured weight values at these time points (n=395) and among all participants, and compared the results. Third, we repeated the analyses excluding participants with who were diagnosed with gestational diabetes, pre-eclampsia, and gestational hypertension (n=117). Last, we repeated the analysis among participants who had higher than the median number of weight measurements (n=1299).

RESULTS

Pregnancy weight information was available for N=2,624 (69%) of the N=3,813 participants enrolled in LifeCodes up to September 2015. We excluded 236 twin pregnancies, five pregnancies for implausible weight gain (± 5 SD), and 12 pregnancies that ended earlier than 22 weeks gestation. All 2,370 final participants had at least two weight measurements. A flow diagram for inclusion into the study is shown in Figure 1. Participants in the final analytic cohort were similar to the full cohort with respect to baseline characteristics (eAppendix 1).

Figure 1.

Flow diagram of study inclusion

The final analytic cohort had a total of 24,378 weight measurements available. The average number of weight measurements recorded per participant was 12 (minimum two, maximum 30). Another 34,495 weight measurements were interpolated. An average of 15 weight measurements were interpolated per participant. Based on the combination of real and interpolated weight measurements, participants in the cohort gained 24.7 on average pounds during pregnancy and accumulated 1143.9 pound–days. Mean weight gain for each week of gestation according to quintile of pound–days is shown in Figure 2, and eAppendix 2 provides ranges of pound days for each week of gestation by quintile.

Figure 2.

Mean pound-days accumulated in each quintile by week of gestation

Four-hundred sixty-seven women had at least one negative value for pound–days during follow-up. Approximately 25% of these women were overweight or obese and the other 75% were normal or underweight. Approximately 80% of participants contributed person–time to more than one quintile of pound–days, but over half (56% of these) changed quintiles only once or twice. As shown in eAppendix 3, most of this movement took place between adjacent quintiles.

Table 1 shows the percentages of participants with each baseline characteristic falling into quintiles of accumulated pound–days at the end of pregnancy. Participants differed most notably with respect to initial BMI. Mean initial BMI was 32.1 (SD 7.6) in the lowest quintile and 26.2 (5.9) in the highest quintile. In addition, more than twice the percentage of participants with three or more previous pregnancies were in the lowest quintile (29.8%) compared to primigravid women (13.7%). A notably smaller percentage of women with gestational diabetes (20.1%) were in the highest quintile compared to women without it (6.9%).

Table 1.

Sample Characteristics according to quintile of accumulated pound–days by the end of pregnancy (n=2,370)

	Quintile
Characteristic	Lowest	Second-lowest	Middle	Second-highest	Highest
Pound–days, mean (SD)	529.3 (270.6)	941.1 (200.5)	1131.1 (238.4)	1354.9 (251.6)	1866.4 (538.1)
Initial BMI (lbs/in.2), mean (SD)	32.1 (7.6)	27.6 (6.9)	26.0 (5.8)	25.4 (5.1)	26.2 (5.9)
Maternal height (in.), mean (SD)	64.2 (2.9)	64.2 (2.8)	64.2 (2.8)	64.4 (2.6)	64.7 (2.7)
Age in years, N (%)
<25	73 (22)	46 (14)	62 (19)	60 (18)	87 (27)
25 – < 30	116 (22)	90 (17)	108 (20)	103 (19)	121 (23)
30 – < 35	156 (20)	175 (23)	150 (19)	155 (20)	140 (18)
≥ 35	176 (34)	158 (22)	145 (20)	132 (19)	101 (14)
Gravidity, N (%)
0	77 (14)	110 (20)	125 (22)	128 (28)	124 (22)
1	126 (20)	131 (20)	137 (21)	121 (19)	127 (20)
2	103 (23)	101 (23)	87 (20)	77 (17)	78 (18)
≥3	213 (30)	131 (18)	119 (17)	126 (18)	125 (18)
Smoking, N (%)
Yes	78 (21)	63 (18)	62 (18)	70 (20)	82 (23)
No	443 (22)	409 (20)	402 (20)	382 (19)	371 (19)
Ethnicity, N (%)
Caucasian	205 (17)	252 (20)	268 (22)	279 (23)	233 (19)
African American	144 (35)	73 (18)	60 (15)	57 (14)	80 (19)
Asian	22 (16)	38 (28)	32 (24)	22 (16)	22 (16)
Hispanic	122 (26)	92 (20)	86 (19)	74 (16)	89 (19)
Other	30 (25)	18 (15)	21 (18)	20 (17)	30 (25)
Insurance status, N (%)
Private/Self-pay	236 (31)	121 (16)	121 (16)	121 (16)	156 (21)
Public/None	282 (18)	350 (22)	340 (21)	328 (21)	290 (18)
Education, N (%)
High school or less	120 (3)	51 (13)	72 (19)	52 (13)	95 (24)
Some college	147 (29)	95 (19)	85 (17)	90 (18)	97 (19)
College graduate	137 (20)	142 (20)	139 (19)	145 (21)	136 (19)
Graduate School	116 (16)	182 (24)	168 (22)	163 (22)	121 (16)
History of diabetes, N (%)
Yes	18 (30)	12 (20)	3 (5)	12 (20)	15 (25)
No	491 (21)	455 (20)	461 (20)	436 (19)	435 (19)
History of chronic hypertension, N (%)
Yes	42 (34)	22 (18)	21 (17)	15 (12)	22 (18)
No	481 (21)	451 (20)	447 (20)	437 (19)	432 (19)
History of thyroid disease, N (%)
Yes	45 (21)	36 (17)	51 (24)	48 (22)	36 (17)
No	478 (22)	437 (20)	417 (19)	404 (19)	418 (19)
Gestational diabetes, N (%)
Yes	68 (39)	49 (28)	28 (16)	18 (10)	12 (7)
No	451 (21)	422 (19)	368 (21)	430 (20)	374 (20)

SD=standard deviation, lb.=pounds, in.=inches, BMI=body mass index

Initial BMI was negatively associated with of accumulated pound–days at the end of pregnancy (multivariable β=−18 (95% CI −21, −15)) but positively associated with total weight gain z-score (multivariable β=0.02 (95% CI 0.01, 0.03)) (Table 2). Older maternal age was associated with both lower accumulated pound–days (multivariable β=−190 (95% CI −270, −100)) and lower total weight gain z-score (multivariable β=−0.25 (−0.42, −0.08)). While gestational diabetes was negatively associated with both pound–days and total weight gain z-score, pre-eclampsia and gestational hypertension were positively associated with these measures.

Table 2.

Factors associated with pound–days accumulated over gestation in generalized linear models (n=2,370) and weight gain z-score (n=1,898)

	Accumulated pound–days		Weight gain z-score
Characteristic	Unajusted Beta-coefficient (β) (95% CI)	Adjusteda Beta-coefficient (β) (95% CI)	Unajusted Beta-coefficient (β) (95% CI)	Adjusteda Beta-coefficient (β) (95% CI)
Age (years)
<25	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)
25 – < 30	−120 (−190, −41)	−91 (−165, −16)	−0.01 (−0.15, 0.13)	−0.09 (−0.24, 0.06)
30 – < 35	−93. (−160, −22)	−130(−210, −47)	−0.12 (−0.25, 0.01)	−0.23 (−0.39, −0.08)
≥ 35	−200. (−270, −120)	−190 (−270, −100)	−0.15 (−0.28, −0.01)	−0.25 (−0.42, −0.08)
Initial BMI (lbs/in.2)	−23 (−26, −20)	−17 (−21, −15)	0.02 (0.01, 0.02)	0.02 (0.01, 0.03)
Maternal height (in.)	16 (8, 24)	5.5 (−2.1, 13)	0.01 (0, 0.03)	0.01 (0, 0.02)
Gravidity
0	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)
1	−97 (−160, −35)	−53 (−110, 4.6)	−0.13 (−0.24, −0.02)	−0.09 (−0.2, 0.02)
2	−170 (−230, −98)	−80 (−140, −16)	−0.21 (−0.34, −0.09)	−0.19 (−0.31, −0.06)
≥3	−200 (−260, −140)	−62 (−120, −1.6)	−0.15 (−0.26, −0.04)	−0.06 (−0.17, 0.06)
Smoking	37 (−25, 99)	41 (−16, 99)	0.1 (−0.01, 0.21)	0.05 (−0.06, 0.17)
Ethnicity
Caucasian	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)	0.0 (Ref.)
African American	−130 (−190, −64)	−15 (−84, 53)	0.04 (−0.08, 0.15)	−0.07 (−0.2, 0.07)
Asian	−70 (−170, 27)	−53 (−140, 38)	−0.26 (−0.43, −0.08)	−0.15 (−0.32, 0.03)
Hispanic	−110 (−160, −47)	−42 (−110, 24)	−0.06 (−0.17, 0.04)	−0.08 (−0.2, 0.05)
Other	−75 (−180, 28)	−0.06 (−100, 100)	−0.19 (−0.38, 0.01)	−0.23 (−0.44, −0.03)
Insurance status
Private/Self-pay	0.0 (Ref.)	0.0 (Ref.)	0.00 (Ref.)	0.00 (Ref.)
Public/None	89 (42, 140)	97 (35, 160)	0.06 (−0.03, 0.15)	0.17 (0.05, 0.3)
Education
High school or less	0.00 (Ref.)	0.00 (Ref.)	0.00 (Ref.)	0.00 (Ref.)
Some college	−35 (−110, 37)	−36 (−100, 33)	0.06 (−0.08, 0.19)	0.08 (−0.05, 0.22)
College graduate	32 (−36, 100)	−29 (−110, 49)	0.07 (−0.05, 0.2)	0.06 (−0.1, 0.21)
Graduate School	57 (−10, 120)	−55 (−140, 29)	−0.03 (−0.15, 0.1)	0.02 (−0.14, 0.19)
History of diabetes	−99 (−240, 42)	33 (−100, 160)	0.3 (0.06, 0.53)	0.18 (−0.06, 0.42)
History of chronic hypertension	−190 (−290, −87)	−42 (−140, 56)	0.16 (−0.02, 0.33)	0.03 (−0.15, 0.21)
History of thyroid disease	5.3 (−72, 82)	18 (−53, 88)	0.06 (−0.07, 0.2)	0.06 (−0.08, 0.19)
Gestational diabetes	−310 (−390, −230)	−200 (−280, −120)	−0.26 (−0.42, −0.11)	−0.3 (−0.46, −0.14)
Gestational hypertension	124 (11, 240)	130 (27, 230)	0.23 (0.04, 0.43)	0.19 (0, 0.38)
Pre-eclampsia	−110 (−200, −24)	140 (51, 230)	0.42 (0.26, 0.58)	0.39 (0.21, 0.56)

CI=confidence interval, BMI=body mass index, lb.=pounds, in.=inches

^aAdjusted model controls for variables included in the table and gestational age at delivery

The highest quintile of accumulated pound–days was associated with a reduced hazard of preterm birth (HR 0.55, 95% CI 0.31, 0.99) and SGA (HR 0.65, 95% CI 0.45, 0.92) and an increased hazard of LGA (HR 1.6, 95% CI 1.0, 2.4) compared to the middle quintile (Table 3). Total weight gain z-scores below −1 were associated with an increased risk of SGA (RR 1.4, 95% CI 1.1, 1.9). We observed no association between total weight gain z-score and size for gestational age z-score.

Table 3.

Associations between gestational weight gain AUC^a (n=2,370), total weight gain z-score (n=1,898) and birth outcomes^b

Outcome	Spontaneous preterm birth Hazard Ratio (95% CI)	Small for gestational age Hazard Ratio (95% CI)	Large for gestational age Hazard Ratio (95% CI)	Weight for gestational age z-score β (95% CI)
Cases/person -weeks	167/54,275	387/58,873	218/58,873
Unadjusted model
Quintile of pound–days
Lowest	0.98 (0.61, 1.6)	1.2 (0.91, 1.6)	1.2 (0.76, 1.9)
Second lowest	1.2 (0.8, 1.9)	1.2 (0.9, 1.6)	0.78 (0.47, 1.7)
Middle	1.0 (Ref.)	1.00 (Ref.)	1.00 (Ref.)
Second highest	1.1 (0.71, 1.8)	0.84 (0.61, 1.2)	1.5 (1.0, 2.4)
Highest	0.55 (0.31, 0.96)	0.66 (0.47, 0.93)	1.7 (1.1, 2.6)
Adjusted model
Quintile of pound–days
Lowest	0.94 (0.56, 1.6)	1.3 (0.94, 1.8)	0.55 (0.32, 0.93)
Second lowest	1.1 (0.72, 1.8)	1.2 (0.85, 1.6)	0.64 (0.38, 1.1)
Middle	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)
Second highest	1.2 (0.72, 1.8)	0.83 (0.6, 1.2)	1.4 (0.86, 2.1)
Highest	0.55 (0.31, 0.99)	0.65 (0.45, 0.92)	1.6 (1.0, 2.4)
Unadjusted GWG z-score
< −1	1.2 (0.74, 2.0)	1.6 (1.2, 2.2)	0.45 (0.25, 0.81)	−0.22 (−0.48, 0.05)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	0.00 (Ref.)
> 1	0.57 (0.14, 2.3)	0.51 (0.19, 1.4)	1.8 (0.95, 3.5)	0.09 (−0.23, 0.43)
Adjusted GWG z-score
< −1	1.4 (0.81, 2.3)	1.4 (1.0, 1.9)	0.57 (0.31, 1.0)	−0.21 (−0.48, 0.05)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	0.0 (Ref.)
> 1	1.1 (0.26, 5.0)	0.44 (0.16, 1.2)	1.8 (0.88, 3.5)	0.06 (−0.30 0.42)

CI=confidence interval, GWG=gestational weight gain, BMI=body mass index.

^aPound–days treated as a time varying exposure in stratified Cox-proportional hazards models, with completed gestational weeks as the time scale

^bAdjusted for age, baseline BMI, maternal height, gravidity, race/ethnicity, education, insurance status, smoking status, history of thyroid disease, history of lupus, history of diabetes, gestational diabetes, gestational hypertension, and pre-eclampsia.

The direction of the associations between AUC quintile and spontaneous preterm birth, AUC quintile and SGA and total weight gain z-score did not change after stratification by initial BMI (Table 4) though the confidence intervals widened. Person–time in the highest AUC quintile was associated with 3.2-fold (95% CI 1.5, 6.9) increased risk of LGA births among normal weight and underweight women compared to the middle quintile; however, no association was observed for overweight or obese women.

Table 4.

Multivariable associations between time-varying quintile of AUC, total weight gain z-score, and birth outcomes, stratified by initial BMI (<25 (n=1,034) vs. ≥ 25 (n=1,327))^a

Outcome	Spontaneous preterm birth HR (95% CI)	Small for gestational age HR (95% CI)	Large for gestational age HR (95% CI)	Weight for gestational age z-score β (95% CI)
BMI < 25
Cases/person–weeks	72/23,788	200/25,114	70/25,114
Quintile of pound–days
Lowest	1.2 (0.48, 3.0)	1.8 (1.1, 2.8)	1.3 (0.39, 4.4)
Second lowest	1.5 (0.74, 2.9)	1.4 (0.95, 2.1)	0.36 (0.1, 1.3)
Middle	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)
Second highest	1.4 (0.7, 2.7)	0.72 (0.46,1.1)	2.0 (0.92, 4.4)
Highest	0.69 (0.31, 1.6)	0.81 (0.51, 1.3)	3.2 (1.5, 6.9)
BMI ≥ 25
Cases/person–weeks	88/15,444	180/31,231	132/31,231
Quintile of pound–days
Lowest	0.77 (0.41, 1.5)	0.95 (0.61, 1.5)	0.46 (0.26, 0.83)
Second lowest	0.93 (0.50, 1.8)	0.87 (0.54, 1.4)	0.67 (0.37, 1.2)
Middle	1.0 (Ref.)	1.0 (Ref.)	1.0 (Ref.)
Second highest	1.0 (0.52, 2.0)	1.0 (0.63, 1.7)	1.1 (0.62, 1.9)
Highest	0.44 (0.19, 1.0)	0.48 (0.27, 0.87)	1.00 (0.57, 1.8)
BMI < 25
GWG z-score
< −1	1.6 (0.82, 3.0)	1.4 (0.95, 2.1)	0.4 (0.14, 1.1)	−0.25 (−0.65, 0.15)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	0.00 (Ref.)
> 1	0.74 (0.1, 5.5)	0.57 (0.18, 1.8)	2.6 (0.91, 7.6)	0.15 (−0.44, 0.74)
BMI ≥ 25
GWG z-score
< −1	0.79 (0.35, 1.8)	1.4 (0.84, 2.4)	0.69 (0.33, 1.5)	−0.23 (−0.59, 0.13)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	0.00 (Ref.)
> 1	0.62 (0.08, 4.7)	0.27 (0.04, 2.0)	1.4 (0.54, 3.4)	0.09 (−0.38, 0.57)

AUC=area under the curve, BMI=body mass index, HR=hazard ratio, GWG=gestational weight gain

^aAdjusted for age, gravidity, race/ethnicity, education, insurance status, smoking status, initial BMI, maternal height, history of thyroid disease, history of lupus, history of diabetes, gestational diabetes, gestational hypertension, and pre-eclampsia.

Stratification by gravidity (Table 5) showed that the reduced hazard ratio observed between the highest AUC quintile and spontaneous preterm birth is limited to multigravid women (HR 0.44, 95% CI 0.23, 0.84). Among primigravid women, person–time in the lowest quintile had 2.08 times the hazard of SGA (95% CI 1.0, 4.0) compared to those in the middle quintile. This association was not observed among multigravid women.

Table 5.

Multivariable associations between time-varying quintile of AUC, total weight gain z-score, and birth outcomes, stratified by gravidity (primigravid (n=564) vs. multigravid (n=1,802)

Outcome	Spontaneous preterm birth HR (95% CI)	Small for gestational age HR (95% CI)	Large for gestational age HR (95% CI)	Weight for gestational age z-score β (95% CI)
Primigravid
Cases/person–weeks	40/12,880	91/14,071	41/14,121
Quintile of pound–days
Lowest	3.7 (0.79, 17.0)	2.1 (1.1, 4.0)	1.3 (0.34, 4.7)
Second lowest	3.8 (1.0, 14.1)	1.8 (1.0, 3.3)	0.56 (0.17, 1.8)
Middle	1.0 (Ref.)	1.0 (Ref.)	1.0 (Ref.)
Second highest	6.5 (1.9, 22.5)	0.84 (0.42, 1.7)	1.3 (0.5, 3.7)
Highest	1.8 (0.42, 8.0)	0.58 (0.27, 1.3)	1.4 (0.5, 3.8)
Multigravid
Cases/person–weeks	127/41,175	296/44,607	177/44,607
Quintile of pound–days
Lowest	0.72 (0.41, 1.3)	1.16 (0.81, 1.66)	0.53 (0.3, 0.94)
Second lowest	0.89 (0.54, 1.5)	1.0 (0.72, 1.5)	0.64 (0.35, 1.2)
Middle	1.0 (Ref.)	1.0 (Ref.)	1.00 (Ref.)
Second highest	0.69 (0.39, 1.2)	0.84 (0.57, 1.2)	1.3 (0.81, 2.2)
Highest	0.44 (0.23, 0.84)	0.66 (0.44, 0.99)	1.6 (0.98, 2.6)
Primigravid
GWG z-score
< −1	1.7 (0., 5.0)	1.6 (0.80, 3.0)	0.96 (0.26, 3.5)	−0.11 (−0.86, 0.64)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	0.00 (Ref.)
> 1	3.3 (0.64, 17.3)	0.7 (0.15, 2.9)	0.99 (0.20, 4.9)	−0.02 (−0.81, 0.78)
Multigravid
GWG z-score
Adjusted GWG z-score
< −1	1.1 (0.6, 1.9)	1.3 (0.92, 1.9)	0.47 (0.23, 0.94)	−0.21 (−0.50, 0.08)
−1 to 1	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)	1.00 (Ref.)
> 12	-	0.30 (0.07, 1.3)	1.8 (0.82, 3.8)	0.06 (−0.35, 0.47)

AUC=area under the curve, CI=confidence interval, HR=hazard ratio, GWG=gestational weight gain

A post-hoc sensitivity analysis that excluded participants who lost weight showed similar results to those reported above (data not shown). EAppendix 4 displays the results of a sensitivity analysis that compared hazard ratio estimates for the association between the AUC between 18 and 26 weeks and each outcome between those with measured weights available at these time points and all participants. The point estimates for the association between quintiles of the AUC between 18 and 26 weeks and spontaneous preterm birth were similar between groups, though the confidence interval was substantially wider for the hazard ratio pertaining to participants with measured weights at these time points. The associations seen with SGA and LGA among all participants were not present, however, among participants for whom the AUC between 18 and 26 weeks was derived from measured values only. Sensitivity analyses excluding participants with gestational diabetes, pre-eclampsia, and gestational hypertension (eAppendix 5) and excluding participants with the median number of weight measurements or below (eAppendix 6) did not substantially alter the point estimates seen in Table 3, though the precision of these estimates was reduced.

DISCUSSION

In this study, we estimated that BMI, maternal age, and pregnancy morbidities including gestational diabetes, preeclampsia, and gestational hypertension influenced both the gestational weight gain AUC and total weight gain z-score. A larger weight gain AUC, suggesting more rapid weight gain earlier in pregnancy, was associated with a reduced hazard of preterm birth among multigravid women and a reduced hazard of SGA among all women. On the other hand, higher AUC values were associated with an increased hazard of LGA among normal weight and underweight women. Lower weight gain z-scores were associated with an increased risk of SGA.

We are aware of only two previous studies that have used the AUC to characterize gestational weight gain,^25,26 so comparability of these findings with those of other studies is limited. Nonetheless, our finding that higher maternal BMI may be associated with slower weight gain earlier in pregnancy seems largely consistent with prior reports of lower weight gain among overweight and obese women during the first¹⁹ and second trimester^{19, 37} followed by greater weight gain among these women during third trimester.^{19, 43} The lower AUC values and total weight gain z-scores observed among older women compared to younger women are likewise supported by reports of lower total gestational weight gain.^{21, 44, 45} and second and third trimester weight gain¹⁹ in this group.

Only one previous study to our knowledge has evaluated the relation between the gestational weight gain AUC and pre-term birth.²⁶ Contrary to our results, this study found no association between the first and second trimester AUC and either spontaneous or indicated preterm birth among 12,526 singleton pregnancies in Oregon and Washington State but did not examine the association within strata of gravidity. Our observation that a higher AUC was associated with a reduced hazard of spontaneous preterm birth only among multigravid women is novel. We can speculate that earlier, more rapid weight gain among multigravid women may counteract the depletion of maternal nutritional reserves through previous pregnancies and breastfeeding,⁴⁶ but additional evidence is needed to confirm this finding.

We did not observe an association between gestational age-adjusted total weight gain z-score and spontaneous preterm birth in either primigravid or multigravid women, which may reflect the importance of incorporating the timing of weight gain into measures of gestational weight gain. It may also reflect the need for caution in interpreting the results discussed above, especially since the sample size was greatly reduced in the primigravid stratum. Studies evaluating the impact of total weight gain or average weight gain on the risk of spontaneous preterm birth^47–52 have found both high and low weight gain to be associated with this outcome. Not all of these studies have accounted for the correlation between gestational weight gain and gestational duration, however.

Associations between inadequate gestational weight gain and decreased birthweight and fetal growth are well established,⁵³ but no consensus exists regarding the impact of weight gain timing on this association. Some studies suggest that low weight gain in the second trimester is particularly detrimental to infant birth weight.^54–58 These findings are somewhat aligned with our results, which imply that those who gain weight more weight earlier in pregnancy have a reduced risk for SGA infants. This association is logical since body fat and protein accretion of the fetus begin at approximately 20 weeks of gestation and accelerate thereafter until term.⁵⁹ The ways in which the different components of weight gain (fat mass vs. fat free mass) during timepoints through gestation may influence fetal growth nevertheless remains poorly understood⁶⁰ and should be prioritized in future investigations.

Although we found that greater weight gain during the first part of pregnancy was associated with reduced risk of SGA, normal and underweight women who accumulated the most pound–days had an increased risk of LGA in our study. The lack of an association between high weight gain and LGA among overweight and obese women was unexpected, since an overall link between high weight gain and LGA has been reported among obese women previously⁶¹ and could potentially be explained by insufficient power to after stratification of the data. Still, our results lend support to a study that showed an increased risk of LGA associated with excess weight gain in the second but not third trimester.²⁴

Strengths of this study include its prospective design, repeated measures of maternal weight starting in early pregnancy, ultrasound confirmation of gestational age, and use of a survival framework to account for the correlation between birth outcomes and gestational duration. A limitation of this study was the reliance on interpolated data. The survival modeling approach we used required weight values for each week of gestation. Since weekly weight measurements during pregnancy are rarely available, interpolation is necessary.¹⁷ The results of our sensitivity analyses suggested that the use of interpolated weight values may have resulted in overestimates of the associations between accumulated pound–days and SGA. In addition, we cannot rule out residual and unmeasured confounding as a source of bias in this observational study. Last, this study is limited by the omission of first trimester weight gain. Weight measurements were less consistently available during this period; we are unsure that a linear interpolation model for missing weights would be applicable to the first trimester, since previous studies have suggested that maternal weight gain in the first trimester is low, on average 0.5–2.0 kg.⁴⁰

In conclusion, our study lends additional support to the importance of maternal weight gain to ensuring adequate fetal growth. It further suggests that a high gestational weight gain AUC, indicating weight gain earlier in pregnancy, may be associated with SGA and that a high AUC may also be associated with spontaneous preterm birth among multigravid women. On the other hand, it may increase the risk of LGA among normal and underweight women. Further research into optimizing the gestational weight AUC through the development of recommended AUC ranges that are specific to trimester, BMI, and gravidity may be warranted.