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The causal association between maternal depression, anxiety, and infection in pregnancy and neurodevelopmental disorders among 410 461 children: a population study using quasi-negative control cohorts and sibling analysis

Published online by Cambridge University Press:  11 January 2024

Holly Hope
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK
Matthias Pierce
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK
Hend Gabr*
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK Department of Mathematics, Insurance, and Statistics, Faculty of Commerce, Menoufia University, Shebeen El-Kom, Menoufia, Egypt
Maja R. Radojčić
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK
Eleanor Swift
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK Greater Manchester Mental Health NHS Foundation Trust, Manchester, UK
Vicky P. Taxiarchi
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK
Kathryn M. Abel
Affiliation:
Centre for Women's Mental Health, Division of Psychology and Mental Health, Faculty of Biology, Medicine and Health, University of Manchester, Manchester, UK Greater Manchester Mental Health NHS Foundation Trust, Manchester, UK
*
Corresponding author: Hend Gabr; Email: [email protected]
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Abstract

Background

To address if the long-standing association between maternal infection, depression/anxiety in pregnancy, and offspring neurodevelopmental disorder (NDD) is causal, we conducted two negative-control studies.

Methods

Four primary care cohorts of UK children (pregnancy, 1 and 2 years prior to pregnancy, and siblings) born between 1 January 1990 and 31 December 2017 were constructed. NDD included autism/autism spectrum disorder, attention-deficit/hyperactivity disorder, intellectual disability, cerebral palsy, and epilepsy. Maternal exposures included depression/anxiety and/or infection. Maternal (age, smoking status, comorbidities, body mass index, NDD); child (gender, ethnicity, birth year); and area-level (region and level of deprivation) confounders were captured. The NDD incidence rate among (1) children exposed during or outside of pregnancy and (2) siblings discordant for exposure in pregnancy was compared using Cox-regression models, unadjusted and adjusted for confounders.

Results

The analysis included 410 461 children of 297 426 mothers and 2 793 018 person-years of follow-up with 8900 NDD cases (incidence rate = 3.2/1000 person years). After adjustments, depression and anxiety consistently associated with NDD (pregnancy-adjusted HR = 1.58, 95% CI 1.46–1.72; 1-year adj. HR = 1.49, 95% CI 1.39–1.60; 2-year adj. HR = 1.62, 95% CI 1.50–1.74); and to a lesser extent, of infection (pregnancy adj. HR = 1.16, 95% CI 1.10–1.22; 1-year adj. HR = 1.20, 95% CI 1.14–1.27; 2-year adj. HR = 1.19, 95% CI 1.12–1.25). NDD risk did not differ among siblings discordant for pregnancy exposure to mental illness HR = 0.97, 95% CI 0.77–1.21 or infection HR = 0.99, 95% CI 0.90–1.08.

Conclusions

Maternal risk appears to be unspecific to pregnancy: our study provided no evidence of a specific, and therefore causal, link between in-utero exposure to infection, common mental illness, and later development of NDD.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press

Introduction

Maternal mental illness is an increasingly common phenomenon: up to one in six children is exposed during pregnancy (Abel et al., Reference Abel, Heuvelman, Rai, Timpson, Sarginson, Shallcross and Emsley2019a). Other pregnancy-related exposures, including small-for-gestational-age and prematurity are well-recognized antecedents of neurodevelopmental risk (Allotey et al., Reference Allotey, Zamora, Cheong-See, Kalidindi, Arroyo-Manzano, Asztalos and Birtles2018; Arcangeli, Thilaganathan, Hooper, Khan, & Bhide, Reference Arcangeli, Thilaganathan, Hooper, Khan and Bhide2012) triggering postnatal infant monitoring and additional supports to families. This is not the case for infants exposed to maternal mental illness during pregnancy (Spittle & Treyvaud, Reference Spittle and Treyvaud2016), despite the well-documented association between parental mental illness and offspring neurodevelopmental disorder (NDD; Ayano, Maravilla, & Alati, Reference Ayano, Maravilla and Alati2019; Chen et al., Reference Chen, Chen, Hsu, Huang, Bai, Chen and Su2020). This may be because there remain important gaps in our knowledge about the mechanisms through which parental mental illness transmits neurodevelopmental risk (Ji-Xu & Vincent, Reference Ji-Xu and Vincent2020). Compared to paternal exposure, antenatal maternal mental illness has consistently stronger effects (Ayano et al., Reference Ayano, Maravilla and Alati2019), suggesting exposure during pregnancy might be important.

The ‘maternal immune activation’ or ‘MiA’ hypothesis is a popular mechanistic explanation for pregnancy-related risk transmission, whereby placental function is altered by maternal inflammatory humoral and cytokine responses causing atypical fetal development and NDD (Brown & Meyer, Reference Brown and Meyer2018). Most evidence for MiA derives from animal studies: inducing inflammatory responses in pregnant mice results in behavioral changes among offspring analogous to human autism spectrum disorder (ASD) (Weber-Stadlbauer et al., Reference Weber-Stadlbauer, Richetto, Labouesse, Bohacek, Mansuy and Meyer2017). Candidate risks for MiA in humans include exposure to maternal stress/depression, maternal infection, or teratogenic drugs during pregnancy (Han et al., Reference Han, Patel, Jones, Nielsen, Mohammad, Hofer and Nassar2021). One case–control study undertook mid-gestational serum profiling of mothers of children with NDDs and suggested that chemokine and cytokine regulation were indeed altered in pregnancy in women of children with ASD compared to controls; although case–control studies are susceptible to selection and recall bias, and unmeasured confounding (Jones et al., Reference Jones, Croen, Yoshida, Heuer, Hansen, Zerbo and Ashwood2017). Such studies do not consider whether maternal inflammatory regulation might be altered prior to pregnancy. To supplement animal and genetic studies, we can use large datasets, where it is unfeasible or unethical to randomize women to exposures, which can provide vital information about the transmission of neuropsychiatric risk (Hagberg, Robijn, & Jick, Reference Hagberg, Robijn and Jick2018), in particular the specific role of the maternal in-utero environment in the etiology of NDD (Ji-Xu & Vincent, Reference Ji-Xu and Vincent2020; O'Connor & Ciesla, Reference O'Connor and Ciesla2022; Rai et al., Reference Rai, Lee, Dalman, Newschaffer, Lewis and Magnusson2017). In a recent Swedish register study, maternal hospitalization for infection in pregnancy was independently associated with the risk of ASD, particularly ASD with intellectual disability (Lee et al., Reference Lee, Magnusson, Gardner, Blomström, Newschaffer, Burstyn and Dalman2015); however, sibling analysis suggested significant unmeasured confounding (Brynge et al., Reference Brynge, Sjöqvist, Gardner, Lee, Dalman and Karlsson2022). Separately, in a Danish study, a similar small increased risk of NDD was associated with maternal and paternal infection in pregnancy, which undermines MiA assumptions (Lydholm et al., Reference Lydholm, Köhler-Forsberg, Nordentoft, Yolken, Mortensen, Petersen and Benros2019). In this analysis, we triangulate two different negative control studies to assess causal inference of the MiA hypothesis in a large, whole UK population cohort and ask whether:

  1. 1. excess offspring neurodevelopment is followed by exposure to maternal mental illness or maternal infection during pregnancy compared to offspring exposed 1–2 years prior to pregnancy.

  2. 2. infants exposed to maternal mental illness or infection during pregnancy were at increased risk of NDDs compared to unexposed siblings.

Methods

Data source

We used CPRD GOLD which contains diagnosis, symptom, and prescription information from ~500 UK general practices, representing ~11 million patients (Herrett et al., Reference Herrett, Gallagher, Bhaskaran, Forbes, Mathur, Van Staa and Smeeth2015). In the UK, >98% of the population is registered with a primary care practice, which is free at the point of care and is a gateway to specialist medical services. Most common illnesses including depression and anxiety are diagnosed and managed entirely within primary care. The quality outcomes framework includes new diagnosis of depression as an incentivized performance indicator for primary care physicians, making the CPRD a comprehensive dataset of the mental health status of registered patients (Department of Health and Social Care, 2011; Khan, Harrison, & Rose, Reference Khan, Harrison and Rose2010) suitable for capturing incidence and prevalence trends (Khan et al., Reference Khan, Harrison and Rose2010; Rait et al., Reference Rait, Walters, Griffin, Buszewicz, Petersen and Nazareth2009; Slee, Nazareth, Freemantle, & Horsfall, Reference Slee, Nazareth, Freemantle and Horsfall2021). Validated linkages connect women to their pregnancies (Pregnancy Register [Minassian et al., Reference Minassian, Williams, Meeraus, Smeeth, Campbell and Thomas2019]) and their children (mother–baby link [Gallagher, Kousoulis, Williams, Valentine, & Myles, Reference Gallagher, Kousoulis, Williams, Valentine, Myles, Sturkenboom and Schink2021]). Three-quarters of English practices in CPRD also have linkage with hospital episodes data (Hospital Episodes Statistics [HES]) which have ICD10 diagnoses from clinical specialist visits and hospital admissions.

Cohorts

The cohort consisted of children born between 01.01.90 and 31.12.17 registered at general practices that are linked to secondary care datasets (HES) in England (N = 715 287) and provided data of sufficient quality (N = 546 305). To create exposure and control cohorts, mothers could not transfer out of practice before the child's date of registration at the practice (544 519). Children had to be linked to a single birth episode in the mother's maternity record.

Three cohorts were constructed, designed to capture discrete periods of exposure to maternal mental illness or infection: during pregnancy, 1 year before pregnancy, and between 1 and 2 years before pregnancy. Mothers in each cohort were included if they were registered at a practice for given lengths of time: (1) pregnancy cohort: registered for a minimum of 280 days before the child's date of birth; (2) 1 year before cohort: registered for a minimum of 1 year and 280 days before the child's date of birth; and (3) 2 years before cohort: registered for a minimum of 2 years and 280 days before the child's date of birth. After exclusions (eFig. 1), 410 461 children linked to 297 803 mothers were included in the pregnancy cohort: 352 993 children linked to 256 617 mothers in the 1 year before pregnancy cohort; and 303 016 children linked to 220 895 mothers in the 2 years before pregnancy cohort (eTable 1). Median age of offspring at the end of follow-up was 5 (IQR [interquartile range] 2–10).

Outcomes

NDD included disorders which would be recorded in primary care in sufficient number from birth onwards with well-understood neurodevelopmental consequences; attention-deficit/hyperactivity disorder (ADHD)/attention-deficit disorder (ADD), autism/ASD, intellectual disability, cerebral palsy, and epilepsy. Cases were drawn from the following sources: primary care, outpatients, and hospital admissions. In addition, ADHD and ADD cases were identified from prescriptions data; dates from each source were captured and the earliest date was used as the outcome event date (see eTable 2 for how NDD was coded, see github for codes).

Exposures

Incident maternal depression and anxiety (using our algorithm which captures all depression and anxiety events in the mother's primary care record (1) see (see eTable 2 for algorithm and githhub for codes).

Infections – all records of viral or non-viral infections recorded in primary care see (see github for categories and codes).

Pregnancy duration was determined for each child in three ways: child's date of birth minus (1) pregnancy start date in pregnancy register (n = 344 500); (2) gestational age of child (n = 25 726); where there was no recorded start date or gestational age; (3) 280 days before delivery date recorded in primary care record (n = 41 055).

During each exposure period, exposure (yes/no) to each exposure variable was recorded. The trimester in which it occurred was also recorded. Prior to pregnancy, exposure (yes/no) to each variable was recorded where a mental illness/infection event occurred and 1 and 2 years prior to pregnancy start date.

Measured confounders

During each exposure period, the following covariates were identified from primary care data: smoking status (current/ex-smoker/non-smoker); body mass index (BMI), from height and weight recorded in and converted into categories (<18.5, <25, <30, <35, <40, and 40⩾); alcohol or substance misuse (yes/no); and Charlson comorbidity index (CCI) (Charlson, Szatrowski, Peterson, & Gold, Reference Charlson, Szatrowski, Peterson and Gold1994) – a validated measure of health burden based on number and type of long-term health conditions, where higher scores indicate greater burden. If there were multiple different BMI or CCI scores recorded on the same date, the mean score was used. Where there were multiple events within the exposure period, the most severe score or category of confounder was selected. Other confounders that did not vary over time included region of England, index of multiple deprivation, maternal history of NDD (yes/no), and birth order. Gender and ethnicity (Asian British/Black British/Mixed/Other/White British/Unknown) of child were extracted from the maternal record in HES and the child record in CPRD. Missing was treated as a separate category for categorical covariates.

Antidepressants and antibiotics were identified from the prescription's dataset using the British National Formulary code; antidepressants include all prescriptions from chapter 4 section 3, and antibiotics from chapter 5 section 1. In pregnancy, exposure (yes/no) to each drug was recorded where it was prescribed in the 280 days prior to the child's date of birth.

Analysis

Simple descriptives were used to describe exposed and unexposed children in the pregnancy cohort and control cohorts, proportions were compared using χ2 and median values of continuous measures using the Mann–Whitney U test. Each child was followed from the latest of these dates: their date of birth and the date they were registered at their clinical practice. Follow-up ended at the earliest date of; the event of interest, the child's date of death, 18th birthday, the date they left their clinical practice, or the date their clinical practice stopped sharing data. Cox regression models were applied to the time-to-event data and hazard ratios (HRs) measured the association between common mental illness or infection and each NDD outcome (any NDD, ASD, ADHD, intellectual disability, epilepsy, and cerebral palsy). Models were fitted on each cohort – pregnancy, 1 year before pregnancy and 2 years before pregnancy – adjusted for the same set of potential confounding variables. We adjusted the maternal infection analysis for maternal depression and the maternal depression analysis for maternal infection. Analyses were repeated for female and male offspring; and for trimester of exposure to interrogate gender and/or trimester effects. In the pregnancy cohort, we adjusted the maternal infection analysis for maternal antibiotic use and the maternal depression analysis for maternal antidepressant use in pregnancy. All models used a clustered standard error to adjust for some mothers appearing multiple times in the analysis.

Finally, to account for unmeasured environmental and genetic confounding, we compared incidence rate of NDD, ADHD, and ASD among siblings discordant for exposure to maternal common mental illness or infection. Discordant pairs were identified using the mother–baby link; where there was more than one possible discordant pair within a family, a pair was sampled at random. Adjusted estimates only included time-dependent variables (maternal age, smoking status, BMI, alcohol, or substance misuse, CCI, gender, ethnicity, birth year and birth order of the child).

Sensitivity analyses

We performed three sensitivity analyses. Potentially, NDD is misdiagnosed in primary care; therefore, we repeated analyses only using cases of NDD diagnosed in secondary care. Children born pre-term, who experience pregnancy and/or obstetric complications, are likely to be at increased risk of NDD; and may spend several weeks or months in hospital postnatally, delaying registration in primary care. However, late registration may also indicate family dysfunction or looked-after status of the child and inflate any effect of maternal mental illness or infection on the risk of NDD. Therefore, we conducted a sensitivity analysis restricted to children registered at their general practice within 30 days of their date of birth (n = 254 338).

It can be difficult to identify the end of mental illness episodes. Therefore, we repeated the main and sibling analyses by considering a woman's incident mental illness to be episodic and women as exposed for 2 years after the incident event.

The association between maternal mental illness or infection and NDD also might be confounded by medication exposure. Therefore, we adjusted associations between mental illness, pregnancy, and NDD for antidepressant use in pregnancy; risk estimates associated with infection were adjusted for antibiotic use in pregnancy.

Attrition in the 1- and 2-year cohorts might mean differences between the negative control cohorts and the pregnancy cohort biased our results. Therefore, we repeated the main negative control analysis restricted to the 303 016 women present in all cohorts.

We estimated the pregnancy start date in pregnancies; based on sample characteristics, 14% of these children might be pre-term, and this group might be in the pregnancy cohort as exposed and unexposed in the 1-year control cohort. Therefore, we excluded children with an unknown pregnancy start date and re-ran the main analysis for the pregnancy and 1-year cohort.

Results

Characteristics of cohorts

The analysis included 410 461 children of 297 426 mothers and 2 793 018 person-years of follow-up with 8900 NDD cases (incidence rate = 3.2 per 1000 person years). Table 1 shows the rates of exposure to maternal common mental illness and maternal infection in the pregnancy cohort. Maternal and child characteristics were similar for cohorts exposed at 1 and 2 years. However, mothers in the 2-year cohort had fewer comorbidities and different ethnicity, deprivation, and smoking profiles to those in pregnancy (eTable 2). Maternal common mental illness and maternal infection in pregnancy were both associated with lower maternal age, maternal smoking, low birthweight, elective, and emergency Caesarean section. Maternal mental illness was associated with infant resuscitation at birth. Women with depression or anxiety were more likely to experience infection during pregnancy or at any other exposure period.

Table 1. The characteristics of women and their children unexposed and exposed to mental illness and infection in pregnancy

Association between maternal mental illness or maternal infection exposure in pregnancy and offspring NDD was compared to exposure at other times.

Maternal mental illness during pregnancy increased offspring NDD risk (5.53 in exposed v. 3.09 events per 1000 person-years in unexposed offspring, HR = 1.83, 95% CI 1.69–1.99); the HR attenuated after adjustment for maternal age, maternal smoking, comorbidities, BMI, history of maternal NDD and offspring gender, ethnicity, birth year, region, and level of deprivation (adj. HR = 1.58, 95% CI 1.46–1.72). The unadjusted and adjusted association of exposure to maternal mental illness 1 year (5.02 v. 3.01 events, HR = 1.70, 95% CI 1.59–1.81, adj. HR = 1.49, 95% CI 1.39–1.60) and 2 years prior to pregnancy (5.34 v. 3.03 events, HR = 1.79, 95% CI 1.67–1.93, adj. HR = 1.62, 95% CI 1.50–1.74) were like risk following exposure during pregnancy. Compared to children unexposed to maternal infection in pregnancy, exposed children had an increased risk of offspring NDDs, but to a lesser extent than exposure to maternal mental illness during pregnancy (3.68 v. 3.06 events per 1000 person-years, HR = 1.21, 95% CI 1.15–1.27). After adjusting for all potential confounders, this effect was reduced (adj. HR = 1.16, 95% CI 1.10–1.22). There was also an association between maternal infection and offspring NDDs following maternal infection 1 year (3.74 v. 3.01, HR = 1.25, 95% CI 1.19–1.32, adj. HR = 1.20, 95% CI 1.14–1.27) and 2 years prior to the index pregnancy (3.75 v. 3.05, HR = 1.24, 95% CI 1.17–1.31, adj. HR = 1.19, 95% CI 1.12–1.25).

The association between maternal mental illness and offspring NDD was retained after adjustment for confounders and pregnancy exposure to antidepressant (adj. HR = 1.21, 95% CI = 1.07–1.37), as was the association between infection in pregnancy and NDD after adjustment for antibiotic use (adj. HR = 1.07, 95% CI 1.02–1.12).

Similar patterns of associations were observed for each type of NDD outcome (see Fig. 1) and did not vary by gender of child (see eFig. 2). Effects did not vary by trimester (see Fig. 2).

Figure 1. The association between maternal mental illness or infection and NDD outcome for pregnancy, 1-year prior and 2-year prior cohorts. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, and area; region, and index of multiple deprivation, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

Figure 2. The effect of mental illness and infection in pregnancy and NDD, by pregnancy trimester. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, and area; region, and index of multiple deprivation, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

Discordant sibling analysis

We examined 7738 siblings discordant for exposure to maternal mental illness and 60 534 siblings discordant for exposure to maternal infection during pregnancy. Rates of NDD were similar for exposed and unexposed siblings (5.66 v. 5.36 events per 1000 person years). After adjustment for maternal age, smoking status, BMI, alcohol, or substance misuse, CCI, and offspring gender, ethnicity, birth year, and birth order, there was no increase associated with maternal mental illness (adj. HR = 0.97, 95% CI 0.77–1.21); a similar pattern was observed for offspring ASD (adj. HR = 1.01, 95% CI 0.71–1.43) and ADHD (adj. HR = 0.92, 95% CI 0.65–1.31). There was no evidence of a difference in rates of NDD among siblings exposed and unexposed to maternal infection during pregnancy (3.44 v. 3.44, adj. HR = 0.99, 95% CI 0.90–1.08). This pattern of results was repeated for ADHD (adj. HR = 1.05, 95% CI 0.89–1.23) and ASD (adj. HR = 0.99, 95% CI 0.86–1.15).

Results were similar whether siblings were sisters or brothers (see Fig. 3).

Figure 3. Sibling association for autism/ASD and ADHD comparing all siblings, sister–sister pairs, and brother–brother pairs. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

Sensitivity analyses

The association between maternal mental illness (HR = 1.83, 95% CI 1.69–1.99) and maternal infection (HR = 1.21, 95% CI 1.15–1.27) in pregnancy and NDD remained highly elevated for secondary care diagnoses only. When we excluded children with delayed registration at their GP practice (which may select families with more dysfunction), and restricted the analysis to children with known pregnancy duration and to women present in pregnancy and control cohorts, the association between maternal mental illness and maternal infection in pregnancy and offspring NDD did not change (see online Supplementary material), nor did these exclusions alter the pattern of attenuation of effects after each adjustment (confounders, exposure in other periods).

Modeling maternal mental illness exposure as episodic increased the number of women with mental illness during pregnancy to 36 439 (8.8%). This did not materially change the results.

When we restricted the analysis to children with known pregnancy duration and to women present in pregnancy and control cohorts, the association between maternal mental illness and maternal infection in pregnancy and offspring NDD was similar (see eTable 3).

Discussion

We constructed a ‘natural experiment’ using high-quality, population-based data from primary and secondary care sources to create different exposure windows for examining the relationship between exposure to maternal mental illness or maternal infection and offspring neurodevelopment. Overall, a child whose mother experienced mental illness or infection during pregnancy had higher incidence of NDD in childhood. However, this increase was similar whether exposure occurred during, or 1–2 years before onset, of pregnancy; nor did risk vary by trimester, counter to MiA hypothesized mechanism of action. We report similar risks for siblings whose mothers had neither recorded mental illness nor infection during pregnancy. Taken together, these findings strongly imply that there is no specific link between maternal mental illness or maternal infection during pregnancy and subsequent risk of offspring NDD.

Research in context

The observational literature examining associations between antenatal (severe) maternal stress, and offspring brain development and/or cognitive delay is inconsistent (Abel et al., Reference Abel, Heuvelman, Jörgensen, Magnusson, Wicks, Susser and Dalman2014; Khashan et al., Reference Khashan, Abel, McNamee, Pedersen, Webb, Baker and Mortensen2008). Timing of offspring exposure does not alter the association between exposure and NDD risk in children, which places doubt on the proposed mechanism of risk transmission triggered in pregnancy (Arcangeli et al., Reference Arcangeli, Thilaganathan, Hooper, Khan and Bhide2012; Brynge et al., Reference Brynge, Sjöqvist, Gardner, Lee, Dalman and Karlsson2022; O'Connor & Ciesla, Reference O'Connor and Ciesla2022). Moreover, sibling analyses and our findings that maternal infection outside of pregnancy also increased offspring NDD risk point to shared familial susceptibility to common mental illness, infection, and NDD within families consistent with previous reports (Han et al., Reference Han, Patel, Jones, Nielsen, Mohammad, Hofer and Nassar2021; Lee et al., Reference Lee, Magnusson, Gardner, Blomström, Newschaffer, Burstyn and Dalman2015; Lydholm et al., Reference Lydholm, Köhler-Forsberg, Nordentoft, Yolken, Mortensen, Petersen and Benros2019; Qiao et al., Reference Qiao, Guo, Shang, Zhao, Wang, Liu and Chen2020). The sibling analyses account for half of the unmeasured genetic effects (Pingault et al., Reference Pingault, O'reilly, Schoeler, Ploubidis, Rijsdijk and Dudbridge2018), and potentially a greater proportion of shared environment if the children are born close together. The marked regression to the mean suggests factors with known links to lower IQ such as family deprivation/poverty and intimate partner violence must be considered as candidates for environmental confounding (Abel et al., Reference Abel, Hope, Swift, Parisi, Ashcroft, Kosidou and Pierce2019b). Larger genome-wide association studies also fail to support the MiA hypothesis: genes associated with susceptibility to infection are elevated in adults and children with neuropsychiatric and neurodevelopmental disorder (Karlsson, Sjöqvist, Brynge, Gardner, & Dalman, Reference Karlsson, Sjöqvist, Brynge, Gardner and Dalman2022; Nudel et al., Reference Nudel, Wang, Appadurai, Schork, Buil, Agerbo and Mors2019).

Strengths and limitations

Several strengths of this study help extend the current literature. First, this large population sample captures exposure to maternal mental illness and infection in the community and not at hospital admission, meaning it represents a more accurate exposure estimate than prior analyses (Brynge et al., Reference Brynge, Sjöqvist, Gardner, Lee, Dalman and Karlsson2022). Furthermore, women might be admitted to hospital because of medical concerns about the pregnancy (which could independently influence NDD risk) and may develop an infection in hospital (Lee et al., Reference Lee, Magnusson, Gardner, Blomström, Newschaffer, Burstyn and Dalman2015). Second, the large sample size and statistical power means we were able to capture the incidence of a variety of NDDs and examine effects by trimester. In the UK, considerable efforts have been made to reduce the stigma of reporting mental health problems such as the ‘No health without Mental Health’ government strategy (Department of Health and Social Care, 2011), where reducing stigma was a key pledge. Identifying and managing depression is incentivized within primary care (UK Department of Health, 2003), and in the perinatal period women are asked about their mental health when they attend antenatal appointments (NIfHaCE, 2007). The majority of the cohort enter the analysis after 2007 meaning incidence in pregnancy should be well recorded. In a prior analysis using a similar cohort of mothers, we report higher rates of mental illness in the UK (Abel et al., Reference Abel, Hope, Swift, Parisi, Ashcroft, Kosidou and Pierce2019b) than Sweden (Pierce et al., Reference Pierce, Abel, Muwonge, Wicks, Nevriana, Hope and Kosidou2020), where rates were extracted from primary and secondary care datasets, suggesting primary care captures more of the mental health risk in communities. Thirdly, triangulation, where the findings of two studies whose methods are independent are combined, is endorsed specifically in its application to causal inference (Ohlsson & Kendler, Reference Ohlsson and Kendler2020).

Despite this, reliable identification of illness in healthcare records can be challenging (Abel et al., Reference Abel, Hope, Swift, Parisi, Ashcroft, Kosidou and Pierce2019b), particularly identifying the exact date of diagnosis/illness onset. This means that some women and offspring might be misclassified as unexposed particularly those with milder disorder. We think our slight underestimate of exposure incidence will not have contributed to an exaggerated association. We adjusted the measurement of depression, anxiety, and NDD to take account of delayed presentation to services and this did not change our results. Autism is increasingly diagnosed in primary care (O'Nions et al., Reference O'Nions, Petersen, Buckman, Charlton, Cooper, Corbett and Stott2023), whether this represents true increasing need, better identification of actual need, changes to the threshold of diagnosis, or overdiagnosis is open to discussion. In our analysis, misclassifying children with autism might affect associations within cohorts but does not alter our overall interpretation that maternal risk appears to be unspecific to pregnancy. Sensitivity analyses indicate that attrition and imputing gestational age for some children did not substantially bias our results. Finally, maternal infection in pregnancy is common. In our sample, 90 482 (22%) of pregnant women presented to primary care with an infection, higher than other studies of infection. That said, many infections in pregnant women are mild, self-limiting, and do not require treatment, meaning our primary care contacts are likely to underestimate the true incidence of maternal infection because many women will not seek help, or remain unaware they have an infection.

Future research

Whilst our finding that developing a common mental illness or infection in pregnancy severe enough to require treatment does not cause NDD in your offspring is informative to people planning or who are pregnant and those who work with them, future innovative study designs that employ negative controls, including using serology, might further inform causality for specific infections. For example, in a prior analysis, we reported that people who tested negative for COVID-19 infection were at a similar risk of mental illness during the pandemic as those who tested positive (Abel et al., Reference Abel, Carr, Ashcroft, Chalder, Chew-Graham, Hope and Pierce2021).

Whilst electronic health records are useful for assembling large cohorts, they may miss milder cases, where the family context might affect the timing of diagnosis. For clinical and public health reasons, it is vital to understand whether maternal infection materially contributes to the risk of atypical offspring neurodevelopment (Ji-Xu & Vincent, Reference Ji-Xu and Vincent2020). Comparing the mean difference in validated scales of developmental delay might be more robust, but currently these types of data are not readily available in datasets of the size required to advance our understanding in this area. In a much smaller sample, Shuffrey et al. (Reference Shuffrey, Firestein, Kyle, Fields, Alcántara, Amso and Bence2022) demonstrated that pregnancy exposure to the COVID-19 pandemic, but not to COVID infection per se was associated with offspring developmental delay assessed through mean scores from the All-Stages' Questionnaire.

Conclusions

Our findings should reassure mothers with mental illness – especially given their excess likelihood of infection during pregnancy – as well as mothers of children with NDD who may have considered themselves to ‘blame’ because of pregnancy exposures. Our findings clearly indicate that timing of maternal mental illness or infection is not associated with offspring neurodevelopmental risk.

Where it is unethical or unfeasible to manipulate exposures, using population datasets may help refine the implications of more traditional observational findings or, indeed, of fMRI studies of prenatal stress which often cannot account for confounding, or are significantly biased by small sample sizes (Wu et al., Reference Wu, Espinosa, Barnett, Kapse, Quistorff, Lopez and Kapse2022).

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0033291723003604

Data sharing

Read codes used are published on Clinicalcodes.org. Electronic health records are, by definition, considered ‘sensitive’ data in the UK by the Data Protection Act and cannot be shared via public deposition because of information governance restriction in place to protect patient confidentiality. Access to data is available only once approval has been obtained through the individual constituent entities controlling access to the data. The primary care data can be requested via application to the Clinical Practice Research Datalink (www.cprd.com/researcher), secondary care data can be requested via application to the hospital episode statistics from the UK Health and Social Care Information Centre (www.hscic.gov.uk/hesdata).

Acknowledgements

This study is based in part on data from the Clinical Practice Research Datalink (CPRD) obtained under license from the UK Medicines and Healthcare products Regulatory Agency. The study was approved by the Independent Scientific Advisory Committee (ISAC) for MHRA (Medicines and Healthcare products Regulatory Agency) Database Research (protocol number: 17_187). Generic ethical approval for observational research using CPRD with approval from ISAC has been granted by a Health Research Authority (HRA) Research Ethics Committee (East Midlands – Derby, REC reference number 05/MRE04/87). The data are provided by patients and collected by the NHS as part of their care and support. Hospital Episode Data Copyright © (2017) are re-used with the permission of The Health & Social Care Information Centre. All rights reserved.

Funding statement

This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation program (grant agreement No GA682741), and Kathryn Abel was funded by the National Institute for Health Research (ref: 111905). The interpretation and conclusions are the authors own and do not represent the views of the funders.

Competing interests

None.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

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Figure 0

Table 1. The characteristics of women and their children unexposed and exposed to mental illness and infection in pregnancy

Figure 1

Figure 1. The association between maternal mental illness or infection and NDD outcome for pregnancy, 1-year prior and 2-year prior cohorts. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, and area; region, and index of multiple deprivation, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

Figure 2

Figure 2. The effect of mental illness and infection in pregnancy and NDD, by pregnancy trimester. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, and area; region, and index of multiple deprivation, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

Figure 3

Figure 3. Sibling association for autism/ASD and ADHD comparing all siblings, sister–sister pairs, and brother–brother pairs. Model adjusted for; maternal; age, smoking status, alcohol or substance misuse, BMI; comorbidities, maternal history of NDD (yes/no), child; gender, ethnicity, birth year and order, maternal mental illness adjusted for maternal infection, and maternal infection adjusted for maternal mental illness.

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