Introduction
Subjective well-being (SWB) is a multidimensional measure that involves cognitive (life satisfaction and positive functioning) and emotional components subjective to an individual and relevant to society’s norms and values [1]. The European Commission and the Organization for Economic Cooperation and Development (OECD) guidelines are commonly adopted to define SWB, which encompasses three fundamental components: life evaluation, eudaimonic well-being (i.e., a sense of purpose and meaning in life), and affect (positive and negative) [2]. SWB has long been considered critical to positively affect several health outcomes including decreased mortality, decreased cardiovascular disease risks, fewer chronic illnesses and functional impairments, and improved health behavior [Reference Bolier, Haverman, Westerhof, Riper, Smit and Bohlmeijer3, Reference Howell, Kern and Lyubomirsky4]. Extending the examination of well-being from pregnancy to postpartum years is crucial to maximizing wellness of maternal and child health [5].
Previous studies on parental happiness trajectories found that parental happiness increased in the year before delivery and then fell to pre-child levels [Reference Myrskylä and Margolis6]. Parental happiness has also been observed to be influenced by factors such as parity, with parents who had a second child having a greater baseline level of life satisfaction than those who only had one child [Reference Myrskylä and Margolis6]. Although accumulated evidence indicated that poor perinatal maternal mental health might have a negative impact on the child physically [Reference Grote, Bridge, Gavin, Melville, Iyengar and Katon7], psychologically [Reference Laurent, Leve, Neiderhiser, Natsuaki, Shaw and Harold8, Reference Murray9], emotionally, and behaviorally [Reference O’Connor, Heron, Golding, Beveridge and Glover10], few studies have investigated the effects of maternal positive well-being on child outcomes.
Regarding birth outcomes, a longitudinal study reported that positive affect in the first and second trimesters was associated with longer gestational length, and higher positive emotion in late pregnancy was associated with a lower risk of preterm delivery [Reference Pesonen, Lahti, Kuusinen, Tuovinen, Villa and Hämäläinen11]. For child development, on the other hand, parental psychological well-being is associated with health behavior [Reference Sabatini12] and parenting behavior [Reference Jouriles, Murphy and O’Leary13], which may impact child development [Reference Barling, MacEwen and Nolte14]. For example, prenatal maternal positive mental health was associated with a lower risk of mental illness in children [Reference Lähdepuro, Lahti-Pulkkinen, Pyhälä, Tuovinen, Lahti and Heinonen15] and reduced the effect of maternal stress on children internalizing and externalizing symptoms [Reference Clayborne, Nilsen, Torvik, Gustavson, Bekkhus and Gilman16]. In addition, a longitudinal study reported that positive maternal perinatal mental health is associated with more favorable developmental outcomes in toddlers, particularly regarding cognition, communication, and social development [Reference Phua, Kee, Koh, Rifkin-Graboi, Daniels and Chen17]. To the best of our knowledge, no study has broadly evaluated the fundamental components of maternal SWB simultaneously. Moreover, the association between maternal positive well-being and child development has been rarely investigated, and the moderating effect of parity has not been addressed.
Our study addresses previous research limitations by using a longitudinal design to assess SWB from early pregnancy to 2 years postpartum; as well as the negative effects of depression and anxiety, separately, on birth outcomes and child development, with the potential moderating effects of parity examined. We hypothesize that the children of mothers with higher levels of SWB would be less likely to have a suspected developmental delay than the children of mothers with lower levels of SWB and that the effect could differ between first-time and experienced mothers.
Methods
Study design and sample
We analyzed data from the Longitudinal Examination across Prenatal and Postpartum Health in Taiwan (LEAPP-HIT) project, which is an ongoing prospective study that began in 2011 in Taipei, Taiwan. Pregnant women were invited to participate in the study during prenatal visits at outpatient clinics of five selected hospitals; they were then followed by postal delivery of surveys coupled with phone reminders to increase the response rate. We recruited women aged 20 years and over, whose pregnancies had not exceeded 16 gestational weeks, who intended to bring the baby to term, who were proficient in Chinese, and whose partners were willing to participate in the study. Those with physical or mental difficulties and with multigestational pregnancies (n = 10) were excluded. Detailed information on the cohort has been published elsewhere [Reference Chen, Huang, Au and Chen18].
Self-reported instruments were used to assess the most important early developmental years. Overall, assessments were conducted at seven time points: early pregnancy (prior to 16 weeks, T1), mid-pregnancy (17 to 28 weeks, T2), late pregnancy (after 29 weeks, T3), and 1 month (T4), 6 months (T5), 1 year (T6), and 2 years (T7) postpartum. A total of 1,224 participants completed the questionnaires from T1 to T4 (up to childbirth), and 600 completed from T1 to T7 (up to 2 years postpartum). Some participants for whom we had data up to birth outcomes had not yet reached the 2-year mark to compare the differences because our cohort is part of an ongoing project. In addition, we only added the SWB instrument in 2016; therefore, we analyzed the positive mental health of 454 women. No significant differences were observed regarding sociodemographic factors and maternal emotional disturbance for women with and without SWB assessments. Written informed consent was obtained from each participant. The study protocol was approved by the institutional review boards of the participating hospitals.
Instruments and Measures
In general, maternal SWB, depression, and anxiety were assessed from T1 to T7, while the child’s development from T5 to T7 was examined. In addition, we further derived sociodemographic data at T1 and child characteristics (e.g., birth outcomes, sex, and birth order) at T4 from the questionnaires. Detailed descriptions are presented later in the article.
Outcome variables
Birth outcomes and child development
Children’s gestational weeks and birth weight were reported by mothers at T4 based on the records in the “Children’s Health Booklet,” which were assessed by hospital healthcare professionals. Gestational weeks and birth weight were used as continuous variables.
We used the Taipei City Developmental Checklist for Preschoolers, 2nd Edition (Taipei II) [Reference Liao, Cheng, Hsieh and Yang19] to assess suspected developmental delay in children aged from 6–24 months (T5 to T7). This concise screening instrument is designed to identify children that should be referred for further evaluation due to a potential risk of developmental delay. It contains 13 checklists for 13 age groups, with each consisting of 11–13 behavior- or skill-related items relating to gross and fine motor control, cognition, language/communication, and emotional/social areas. The items were easily observable or elicited by the child’s caregiver. The internal consistency coefficients (α) of the 13 checklists were 0.72–0.87. A child was classified to have “suspected developmental delay” if they failed more than two items or had more than one marked item throughout the evaluation. This cutoff point had a sensitivity of 0.8 and a specificity of 0.99 and helped to evaluate possible delays in children aged less than 3 years [Reference Liao, Cheng, Hsieh and Yang19].
Independent variables
Subjective well-being
The guidelines of the Joint Research Centre of the European Commission and the OECD were used to assess elements of SWB from T1 to T7 [2]. Four items were used for life evaluation, with questions including “I am satisfied with my life,” and six items were used to measure eudaimonic well-being, with questions including “Most days I get a sense of accomplishment from what I do.” Six items were used for evaluating affect, three for positive (e.g., happy) and three for negative affect (e.g., sad) [2, Reference Yi-Wen20]. Responses were rated on a five-point Likert scale (from 5-strongly agree to 1-strongly disagree). Appropriate validity and reliability have been reported for the scales of life evaluation [Reference Diener, Emmons, Larsen and Griffin21, Reference Eid and Diener22], eudaimonic well-being, and positive and negative affect [Reference Diener, Wirtz, Biswas-Diener, Tov, Kim-Prieto, D-w and Diener23]. Although continuous scores were often preferred in statistical modeling because they provided greater variability, we also sought to identify women with psychological issues below the regular line. To assess prenatal effects on birth outcomes using linear regression models, the median was used to dichotomize the average of T2 and T3 assessments to indicate higher or lower levels of each SWB throughout pregnancy. Whereas for developmental outcomes using the generalized estimating equations models (GEE) to emphasize the trajectories, the median score at each time point from T4 to T7 was used as the cutoff to dichotomize elements of SWB during the postpartum period.
Depression and anxiety
The Edinburgh Postnatal Depression Scale (EPDS) [Reference Cox, Holden and Sagovsky24] was used to measure depression. Adequate reliability and validity have been demonstrated for the EPDS for Chinese mothers [Reference Su, Chiu, Huang, Ho, Lee and Wu25]. We used 20 items from the State subscale of the State–Trait Anxiety Inventory (STAI) [Reference Spielberger26] to assess anxiety. The Chinese version of the STAI has been validated with high reliability [Reference Shek27].
We used a cutoff value to address higher or lower levels of depression and anxiety (i.e., 14/13 for depression [Reference Walfisch, Sermer, Matok, Koren and Einarson28] and 45/44 for anxiety [Reference Teixeira, Figueiredo, Conde, Pacheco and Costa29]) to dichotomize the average score of T2 and T3 and assess the effects on birth outcomes. In addition, the same cutoff value was used at each postnatal time point from T4 to T7 in the GEE model to emphasize the trajectories’ effects on child developmental outcomes.
Covariates
At T1, participants completed the baseline questionnaire that collected information on age, education level, employment status, household income, unplanned pregnancy, smoking status, drinking status, perceived health status, and parity. We also collected information on the child’s birth sex (T4) and health status from birth to 2 years old (T4 to T7).
Statistical analysis
Participant characteristics were summarized using descriptive statistics. Changes in maternal SWB scores over time (from T1 to T7) were examined using repeated-measures analysis of variance (ANOVA). We conducted group-based trajectory modeling (GBTM) to collect individuals who had statistically similar trajectories into meaningful subgroups of prenatal mental health (T1 to T3). We used GBTM to ensure that we thoroughly used the longitudinal data during the prenatal period and identified higher-risk women requiring special attention. Grouping from GBTM was used in the GEE to examine the effects of prenatal mental health throughout the child’s development. To accurately define the trajectories, the relationship between time (i.e., pregnancy trimester) and outcome (e.g., life evaluation and depression) was modeled using polynomial equations. The optimal model, in terms of the number and shape of trajectories, was then chosen using the Bayesian Information Criterion, which favored parsimony [Reference Nagin and Tremblay30]. Stata plugins traj were used for the analyses [Reference Nagin and Tremblay30].
Associations between prenatal positive and negative mental health and birth outcomes were examined using linear regression models. GEEs with an exchangeable correlation structure were used to investigate the effects of maternal positive and negative mental health trajectories on child developmental outcomes from T5 to T7. Each mental health domain was examined in separate models, with time-invariant variables (e.g., prenatal mental health from GBTM) and time-varying variables (e.g., postnatal mental health from T4 to T7) simultaneously. Previously proposed potential confounders or variables with (p < 0.2) in univariate analyses were included in the multivariable regression model. Interaction terms between parity and the main independent variables reached statistical significance (p < 0.1) for child development outcomes but not for birth outcomes (p-values 0.3–0.7); therefore, subgroup analyses stratified by parity were further performed to model child development. Data were analyzed using the Stata software program (Release 15; Stata Corp LLC, College Station, TX). Statistical significance was set at p < 0.05 (two-tailed).
Results
GBTM selection and evaluation
The GBTM results indicated that a two-group solution met the criteria for adequate model fit. Among the two-trajectories groups, over 60% of the participants were classified to have high life evaluation, eudaimonic well-being, and positive affect trajectories, whereas 29.0, 34.1, and 31.2% of the participants were classified to have a high negative affect, depression, and anxiety, respectively.
Table 1 presents the distribution of prenatal life evaluation and eudaimonic well-being according to participant characteristics (see the Supplementary Materials for affect, depression, and anxiety).
Note: The total count for each variable may vary because of missing values.
*p < 0.05, **p < 0.01, ***p < 0.001.
Repeated measure ANOVA results
Repeated-measures ANOVA scores for maternal eudaimonic well-being (p = 0.003) and positive affect (p < 0.001) exhibited significant changes from T1 to T7 (Figures 1 and 2). Significant changes in eudaimonia scores were noted for multiparous mothers (p = 0.001; Figure 1), and significant changes in maternal positive affect scores were observed for primiparous mothers (p < 0.001) from T1 to T7.
Table 2 presents the associations between prenatal positive and negative mental health and birth outcomes, after adjustment for relevant covariates. The results indicated that higher prenatal eudaimonic well-being was associated with longer gestational length (adjusted beta coefficient [aβ] = 0.36, 95% confidence interval [CI] = 0.03, 0.68) and higher birth weight (aβ = 124.71, 95% CI = 35.75, 213.66). A higher prenatal positive affect was associated with longer gestational length (aβ = 0.38, 95% CI = 0.06, 0.70), whereas higher levels of negative affect and depression symptoms were associated with smaller birth weight and shorter gestational length, respectively. We found no association between life evaluation, anxiety, and birth outcomes.
Note: Results were adjusted for maternal age, employment status, family income, unplanned pregnancy, smoking status, maternal perceived health status, baby sex, and parity.
*p < 0.05, **p < 0.01.
Abbreviations: aβ, adjusted beta coefficient; cβ, crude beta coefficient; CI, confidence interval.
Table 3 presents the longitudinal effects of maternal mental health on child development during the first 2 years of life. Using GEE models, after adjustment for potential confounders, higher prenatal eudaimonic well-being was significantly associated with lower risks of suspected developmental delay, particularly among children of multiparous mothers (adjusted odds ratio [aOR] = 0.18, 95% CI = 0.05, 0.70). Higher levels of prenatal depression and anxiety were associated with increased risks of suspected developmental delay in children of primiparous mothers. We observed no associations between life evaluation, positive and negative affect, and suspected child developmental delay.
Note: Results were adjusted for maternal age, education, family income, unplanned pregnancy, baby sex, and baby health status.
*p < 0.05, **p < 0.01, ***p < 0.001, ┼p = 0.05.
Discussion
To the best of our knowledge, this is the first prospective study to broadly examine the impact of maternal SWB on birth outcomes and child early development from early pregnancy to 2 years postpartum while considering the effects of parity. We observed that prenatal eudaimonic well-being was associated with longer gestational length and larger birth weight, and positive affect was associated with longer gestational length. We further observed that prenatal eudaimonic well-being was independently associated with an 82% decreased risk of suspected developmental delay up to 2 years of age among children of multiparous mothers. In addition, higher levels of prenatal depression and anxiety were associated with increased risks of suspected developmental delay among children of primiparous mothers. However, life evaluation and positive and negative affect had no significant association.
In this study, positive prenatal mental health (i.e., eudaimonic well-being and positive affect) was associated with better birth outcomes, and higher negative affect and depression were associated with worse birth outcomes. Previous studies have focused mainly on the effects of maternal mental illnesses and have reported consistent results. Antepartum depression and anxiety have been reported to be significantly associated with preterm birth and low birth weight [Reference Nasreen, Pasi, Rifin, Aris, Rahman and Rus31, Reference Steer, Scholl, Hediger and Fischer32]. Furthermore, limited evidence suggests that higher prenatal eudaimonic well-being and positive affect are associated with lower risks of small gestational weeks and birth weight. A study reported a positive association between increasing positive maternal affect throughout pregnancy and birth outcomes [Reference Voellmin, Entringer, Moog, Wadhwa and Buss33]. Another study identified that positive appraisal was associated with less distress and high coping stability throughout pregnancy [Reference Yali and Lobel34]. However, this study observed a null finding for life evaluation, perhaps due to researchers typically equating life evaluation with overall life satisfaction. Moreover, this study did not observe any association between anxiety and birth outcomes. Anxiety has been linked to premature birth and low birth weight [Reference Grigoriadis, Graves, Peer, Mamisashvili, Tomlinson and Vigod35]. The inconsistency and null findings may be explained by variability in assessment tools and differences in sample characteristics (e.g., higher socioeconomic status with better resources and social support) [Reference Richter, Bondü, Spiess, Wagner and Trommsdorff36, Reference Strine, Chapman, Balluz, Moriarty and Mokdad37].
Researchers have identified a negative association between maternal depression and anxiety and child cognitive development at 2 and 3 years [Reference Ibanez, Bernard, Rondet, Peyre, Forhan and Kaminski38]. Other studies have also revealed a negative association between antenatal depression and child self-regulation [Reference Braungart-Rieker, Lefever, Planalp and Moore39] and development [Reference Camkurt, Fındıklı, Bakacak, Karaaslan, Tolun and Tuman40, Reference Tough, Siever, Leew, Johnston, Benzies and Clark41]. Consistent with the findings of these studies, we found that higher levels of prenatal depression and anxiety were associated with elevated risks of child suspected developmental delay in children of primiparous mothers. Moreover, in our study, we observed beneficial effects of antenatal eudaimonic well-being on child developmental outcomes, especially among children of multiparous mothers. Consistent with our findings, Clayborne et al. (2022) identified that positive maternal mental health during pregnancy was associated with positive developmental outcomes in children aged 5 [Reference Clayborne, Nilsen, Torvik, Gustavson, Bekkhus and Gilman16].
Maternal mental health during pregnancy has been suggested to exert effects on child psychopathology and subsequent development, irrespective of maternal postnatal mental health. Specifically, through the biological pathway of the effect of maternal emotions on birth outcomes, increased levels of maternal cortisol and placental corticotropin-releasing hormone CRH during pregnancy were further observed to be associated with reduced fetal growth, possibly affecting subsequent development in children [Reference Wadhwa, Garite, Porto, Glynn, Chicz-DeMet and Dunkel-Schetter42, Reference Wadhwa, Sandman, Porto, Dunkel-Schetter and Garite43]. In addition, optimistic women with a higher SWB were more proactive and motivated to engage in healthy behaviors (e.g., physical activity, a well-balanced, and nutritious diet) [Reference Blanchflower, Oswald and Stewart-Brown44, Reference Boehm, Vie and Kubzansky45], consequently promoting healthy fetal growth and leading to positive developmental outcomes for the offspring [Reference Clapp46]. A mediating analysis further revealed that higher maternal SWB positively influenced child cognitive and linguistic development through more adaptive parent–child interaction patterns [Reference Phua, Kee, Koh, Rifkin-Graboi, Daniels and Chen17]. The effects of parity with the various demands and challenges faced by first- and second-time mothers are noteworthy. Although the reasons underlying the beneficial effects of the SWB of pregnant women, particularly multiparous women, on child development remain unclear, a higher socioeconomic status with better family support and resources for those who wish to have two or more children may be key factors, as Taiwan’s total fertility rate was estimated to be the lowest in the world in 2021. Further studies are needed to elucidate these findings.
In the postpartum period, maternal mental health has been linked to child developmental outcomes through parental behavior [Reference Barling, MacEwen and Nolte14, Reference Ali, Mahmud, Khan and Ali47, Reference Bernard_Bonin48]. However, we did not observe a significant association between postpartum positive and negative mental health and child development. Because maternal postnatal emotions are often carried over from the prenatal period [Reference Van Batenburg-Eddes, Brion, Henrichs, Jaddoe, Hofman and Verhulst49], independent effects in the postpartum period may be reduced. Null and inconsistent findings may further be explained by the moderating effect of parity, assessment methods, and cultural context applied.
Regarding mood changes during the perinatal period, a previous study found that mood levels are increased around the time of birth and subsequently return to baseline in less than 2 years [Reference Frijters, Johnston and Shields50]. In our study, scores of maternal eudaimonic well-being significantly decreased from early pregnancy to 2 years postpartum, whereas positive affect scores significantly decreased from T3 to T4 and then returned to the initial level at 6 months postpartum. This may possibly reflect the circumstances that depression levels may increase in the early postpartum period as a result of substantial changes accompanied by increased stress [Reference Ngai and Chan51, Reference Gavin, Gaynes, Lohr, Meltzer-Brody, Gartlehner and Swinson52]. The reasons for and effects of the lack of increase in maternal happiness around childbirth observed in this study must be further investigated.
This study has valuable implications. It described the trends in eudaimonic well-being and positive affect scores from early pregnancy to 2 years postpartum according to parity and identified the specific period in which intervention was required to improve well-being. First, maternal eudaimonic well-being and positive affect declined after birth, emphasizing the importance of family support during that time. Second, because well-being is modifiable [Reference Sakuraya, Imamura, Watanabe, Asai, Ando and Eguchi53, Reference Özbiler and Beidoğlu54], interventions for ensuring positive well-being in prenatal care settings are necessary [Reference Wang, Huang, Lin, Au and Chen55], with particular emphasis on experienced mothers. Finally, because depression and anxiety during pregnancy were associated with suspected developmental delay among children of inexperienced mothers, interventions aimed at reducing prenatal mental illness, such as stress coping and emotion management, are crucial for inexperienced mothers.
Our study has several strengths. First, we used a prospective follow-up research design, which allowed us to examine longitudinal changes in women’s SWB scores in multiple domains from early pregnancy to 2 years postpartum, with reduced recall bias. Second, we assessed the effects of maternal SWB in the first 2 years of child’s life, which is the period of remarkable early brain growth and child development. Third, evaluations conducted at seven time points enabled a trimester-specific approach and the identification of relevant time-varying factors for modeling to appropriately consider the timing of important factors and to adjust for major confounders. Fourth, the assessment of the potential modifier effect of parity facilitates the identification of higher risk groups. Finally, our overall follow-up rate was approximately 60% [Reference Wang, Huang, Lin, Au and Chen55], which is considered appropriate for a cohort study [Reference Babbie56]. No significant differences in demographics (e.g., age and education level) were observed between women who were lost to follow-up and those who remained in the study.
Our study also has some limitations. First, we recruited participants from medical centers in metropolitan Taipei, including older women with a relatively high socioeconomic status. Our findings are likely to be understated because couples with poorer marital relationships or lower levels of SWB may be more reluctant to participate or more likely to be lost to follow-up. Second, because our surveys were based on self-reporting questionnaires, potential bias due to social desirability and perception bias cannot be ruled out. Furthermore, the Taipei II was used to screen for suspected developmental delays among children instead of clinical diagnostics. Finally, the possibility of reverse causality cannot be ruled out, as prenatal emotions may be generated as maternal responses and perception of potential medical risks on child developmental outcomes.
Conclusion
This study examined how fundamental components of positive maternal mental health and maternal mental illness affect birth outcomes and child development from early pregnancy to 2 years postpartum. Our results demonstrated that prenatal eudaimonic well-being positively affects birth outcomes and child development, especially in children of multiparous mothers. Longitudinal study with a follow-up period of more than 2 years is required to determine the consistency of the association between eudaimonic well-being and child development by parity, including physiological factors.
Abbreviations
- AOR
-
adjusted odds ratio
- CI
-
confidence interval
- COR
-
crude odds ratio
Supplementary Materials
To view supplementary material for this article, please visit http://doi.org/10.1192/j.eurpsy.2022.2338.
Data Availability Statement
A request to gain access to the data can be made by contacting the corresponding author. Access can be granted subject to the Institutional Review Board (IRB) and the research collaborative agreement guidelines. This is a requirement mandated for this research study by our ethics committee and funders.
Acknowledgments
We are thankful to all participating hospitals, obstetricians, medical personnel, and couple participants for their enthusiastic participation with data collection. We also thank the LEAPP-HIT team for their great work in data collecting.
Author Contributions
W.E. assisted in data collection, analyzed and interpreted the data, and drafted the manuscript. J.-P.H. and H.-K.A. assisted in data collection and clinical consultation. C.-L.L., Y.-Y.C., H.-J.C., L.-C. C. and Y.-C.L. assisted in the literature review and interpretations of the results. Y.-H.C. conceived the study design, analyzed the data, drafted the manuscript, and was the principal investigator for this project.
Funding Statement
This study was supported by grants from the Taiwan Ministry of Science and Technology (MOST 108–2314-B-038-083-MY3, MOST 105–2314-B-038-031-MY3, NSC 102–2314-B-038-038-MY3, and NSC 99–2628-B-038-015-MY3).
Conflicts of Interest
The authors declare none.
Ethical Standards
This study was performed in accordance with the Helsinki Declaration of 1975, as revised in 2000.
Comments
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