Trends in the association between educational assortative mating, infant and child mortality in Nigeria

This study analyzed data obtained from three waves of the Nigeria Demographic and Health Survey (DHS). It includes the surveys of 2008, 2013, and 2018, collected from June to October 2008, February to July 2013, and August to December 2018, respectively. Nigeria is located in West Africa, and the survey was conducted by the National Population Commission (NPC) in collaboration with ICF International. The study protocols followed the Helsinki guidelines, and also received approval from the National Health Research Ethics Committee of Nigeria. The sample for the survey was selected using a stratified two-stage cluster design. This consisted of the selection of primary sampling units (PSUs) across both rural and urban strata. A nationally representative sample of 36,269; 40,680; and 41,668 households were selected across the PSUs in 2008, 2013 and 2018, respectively. All women aged 15 to 49 years old in households were eligible for interviews. Out of the 34,596; 39,902; and 42,121 eligible women in 2008, 2013 and 2018, respectively, between 97 to 99% were successfully interviewed in each of the years. Questions related to household socio-demography, reproductive health, and fertility, among others. No financial compensation was attached to the respondent’s participation. More information about the survey setting and data collection is available in the final reports [31‐33].

Sample selection focused on children who had complete information about their survival status and the educational attainment of both parents. Children of mothers who are either separated, widowed, not cohabitating, or not in a marital union were excluded from the analysis. This was done because the direct or indirect input of the father into childcare could be limited or non-existent (as would be in the case of widowed mothers or single mothers not in a marital union). In addition, mothers who have been married more than once were also excluded because elements from the previous union(s) may have unexplained residuals in the current union. This reduced the sample to a total of 72,527 out of 94,053 births across the three surveys. Analysis of infant mortality included all 72,527 children (2008 = 21,716; 2013 = 23,981; 2018 = 26,930), and child mortality included 53,595 children (2008 = 15,809; 2013 = 17,758; 2018 = 20,028). However, analysis varied slightly across models, depending on the number of missing values among covariates, varying up to 5.3%.

For multivariate analysis, we used the Cox proportional hazard regression with the frailty model. This was done for two reasons. First, Cox regression analysis allows for the inclusion of censored data and it models censored time-until-event data as a dependent variable. Secondly, the frailty model considers the hierarchical structure of the data. Children are nested within households, and, as such, have shared frailty, which may make subjects within households correlate [36].

Conditioned on frailty α_i, the hazard function h_ij(t) for the failure time of the j^th child in the i^th household (j = 1, 2, 3, … ..j; i = 1, 2, 3 … ..n) is expressed as

Where h₀(t) is an unspecified baseline hazard function, α_i is the group-level (household) frailty and β_x denotes the vector of the regression coefficient for a set of covariates [37, 38].

The analyses include two models. Model 1 included the dependent variable and covariates, and Model 2 included an interaction between EAM and household wealth. This is based on the Andersen behavioral model of health service utilization [21], as family wealth may affect factors such as access to quality health and nutrition, which are among the determinants of childhood mortality [26‐29].

We conducted three sensitivity analyses to check the robustness of our result. In the first, we restructured the EAM variable by re-segmenting it into at most secondary vs. tertiary. In the second, we excluded couples who have the same level of educational attainment and then defined homogamy as a mother having any level of education higher than her husband’s, and hypergamy as a father having any level of education higher than the mother. In the third, we excluded those with no years of formal education and then created an indicator for whether the number of years of education completed by the mother is lower, equal, or higher than the number of years completed by the father.

The synthetic cohort technique, as modified by Rutstein (1983) [39], was employed to estimate infant and child mortality rates across the spectrum of EAM. The probability of dying is built up from probabilities calculated for subintervals: 0, 1–2, 3–5, 6–11 months (1q₀), and 12–23, 24–35, 36–47, 48–59 months (4q₁). Death probabilities are defined by a time-period and an age interval, and within these two parameters, three birth cohorts of children are included, as illustrated in Fig. 1.

Only cohort B is completely included, while cohorts A and C are only partially exposed to mortality in the time-period [t₁ t₂]. The subinterval probabilities of death are calculated by dividing the number of deaths occurring in the relevant age interval for children who were exposed to death in a specific calendar period by the number of children exposed in the calendar period. See the DHS statistics guide for a more detailed explanation of this methodology [40, 41]. The conventional mortality rate is then given as: where nq_x is the probability of dying between ages x and x + n , and q[i] is quotient from the subinterval probabilities of dying.

The strength of the approach is rooted in the fact that it allows the full use of the most recent data.

The socio-demographic characteristics of the pooled sample are presented in Table 1. The gender of the children born within the 5 years preceding each wave of the survey was a nearly equal distribution (51.0% male, and 49.0% female). The majority of the births (64.1%) were delivered at a medical facility, and 96.6% were singletons. The average age of mothers was 29.3 years, standard deviation (SD = 6.8). Furthermore, about 68.2% of households were from rural areas, and a negative average family wealth index of − 0.2 (SD = 1.0) suggests that the majority of the sample were from poor households.

The main assumption of the Cox regression is proportional hazard, and we used the scaled Schoenfeld residuals test to verify that this was not violated [36]. The test of proportionality of the whole, as well as each predictor and covariates, were not significant (p-values > 0.05). Also, the graphed plot of the log(−log (survival)) of the main predictor variable against survival time showed roughly parallel lines for all categories of EAM (particularly after the neonate period), an indication of proportional hazard (see supplemental Figure 1).

The trend of infant mortality rate per 1000 live births, and child mortality rate per 1000 who survive up to the first year of birth across the spectrum of EAM are presented in Fig. 2. The data shows that, except for infant mortality in 2008, mortality rates, including child mortality, were highest in low-education homogamy. The trend however declined between 2008 and 2013 only to rise again in 2018. Expectedly, both infant and child mortality was lowest in high-education homogamy but the trend over time was also similar to low-education homogamy, declining between 2008 to 2013 and rising again in 2018. We also observed that both infant and child mortality rates were relatively lower where mothers were in hypogamy compared to hypergamous unions, except for infant mortality in 2008. This further echoed the pattern observed in the multivariate analysis.

The limitations associated with this study include the use of cross-sectional data, which does not allow for the inference of a causal relationship. Second, there may be instances of under-reporting of mortality due to cultural reasons that forbid speaking of the dead or the emotional pain associated with recalling a lost child. Third, due to the few samples of neonatal mortality, we analyzed neonatal mortality together with infant mortality. Lastly, the educational attainment of the father was as reported by the mother. There is the possibility of error, particularly in the sensitivity analysis in supplemental Table 5, where we focused on years of education completed. Despite the limitations, the strength of the study lies in the use of large and nationally representative data, and the use of a frailty model to account for the correlation between samples at the household level.