Associations of acute conflict with equity in maternal healthcare: an uncontrolled before-and-after analysis of Egypt demographic and health survey data

Egypt is a lower-middle-income country in northern Africa with a Gross National Income per capita of US$ 5654 in 2012 [10]. The pluralistic health system is more poorly resourced (i.e. staff, funding, supplies, infrastructure) in rural areas compared to urban areas, an indication of geographic inequity [11]. Under-five mortality during 2008–2013 averaged 27 deaths per 1000 births [11]. The maternal mortality ratio was 33 per 100,000 live births in 2014 [26]. Poor quality-of-care and delays in seeking care were identified as major causes of maternal death in Egypt [27, 28].

The Egyptian revolution started in January 2011, when thousands of civilians protested against the government, eventually leading to the resignation of long-time president Mr. Hosni Mubarak [29, 30]. While the acute phase ended early in 2013 [29], Egypt is not considered fully free from the threat of civil unrest. Despite an elected government taking office in 2012, political protests continued [30]. Several socio-political and economic reasons behind the revolution have not been addressed, including rising poverty, perceived government autocracy, and neglect of social welfare [29]. Although evidence is still emerging, conflict is considered to have adversely affected Egypt’s economic and human development indicators [30]. Figure 1 provides a chronology of events related to the conflict.

A quasi-experimental ‘uncontrolled before-and-after’ design was selected, using multi-level modelling (MLM) regression of 2014 Egypt Demographic and Household Survey (EDHS) data, to compare levels of maternal care usage before and during the acute 2011–2013 Egyptian conflict across socioeconomic groups. The study adopted a working definition of ‘conflict-affected’ from relevant literature as a setting in which routine socio-political, economic and/or civil life are disrupted due to armed political conflict [16, 31‐34]. The ‘pre-conflict’ sample included births from January 2009 to January 2011 while the ‘peri-conflict’ sample included births from February 2011 to December 2012. Based on media reports describing the end of the acute phase of the conflict in early 2013, births from January 2013 onwards were excluded [29]. Analysis thus included 7210 births from 7118 eligible women in 1679 clusters (i.e. 2569 pre-conflict births and 4641 peri-conflict births).

Data were drawn from the 2014 EDHS, which provided a nationally-representative sample (excluding North and South Sinai governorates) [21]. The 2014 EDHS used multi-stage sampling [21]. First,884 primary sampling units (PSUs) were selected. Second, depending on PSU size, systematic sampling yielded 1–3 parts per PSU (1000 households each). Third, each part was divided into equally-sized segments (200 households each), two to three of which were selected randomly from each PSU. A total of 1838 segments (clusters) were selected from 884 PSUs. A household listing was undertaken in each segment. An average of 15 households was selected from each segment using systematic random sampling. Thus, a total of 29,471 households were included. Eligible participants were ever-married women aged 15–49 and present in selected households the night prior to interview. A total of 21,903 women were eligible for the survey. From each eligible woman, details were gathered on childbirths in the five years preceding the date of survey. The 2014 EDHS response rate was 98.4%.

Data were collected in April–June 2014 [21]. Maternal data, collected by local recently-graduated enumerators in Arabic, included place of care-seeking, type of facility, provider and frequency of attendance, timeliness, and contents of services received. All questions were pre-tested and revised based on comments from interviewers, pre-testing, and tabulations of pre-test results. As part of quality control, enumeration teams were closely supervised throughout fieldwork and field editors conducted routine re-interviews using a shortened questionnaire.

Outcome variables were usage of seven binary maternal care components, selected based on data reliability and relevance to improve maternal and neonatal health in a LMIC setting based on empirical evidence [35, 36]:

Selection of outcome measures was based on WHO’s list of essential maternal care services for LMICs and Egypt’s maternal care clinical guidelines [36, 37]. These maternal care indicators consider social and health determinants of maternal care including service delivery in LMICs [35, 36].

Explanatory variables were five maternal characteristics: (i) age, (ii) urban/rural residence, (iii) education, (iv) employment, and (v) household wealth status. Household wealth was calculated in the 2014 EDHS dataset in quintiles from poorest to wealthiest. EDHS calculations used a step-wise approach with key household economic characteristics and assets weighted using principal component analysis [21] .

Data were analysed, using Stata software version 13, both descriptively and by estimating effects through multilevel modelling. Descriptive analyses summarised key explanatory variables by period (pre-conflict, peri-conflict) with frequencies for categorical variables. Multilevel regression models were developed to account for data clustering and allow for the dependency of observations within clusters [38‐40]. EDHS data are hierarchical, i.e. births are nested within households, households within clusters, clusters within PSUs, and PSUs within Governorates [21], and conventional linear regression models that do not account for multiple levels would underestimate the standard errors of effect sizes with a higher chance of Type I error [38‐40]. In hierarchical data, multi-level modelling accounts for dependency of observations and covariates at multiple levels, without assigning them to one or limited levels only [38].

The multilevel model accounted for sample hierarchy at four levels, with a random intercept at each, excluding level 1: births (level 1), household nested within clusters (level 2), cluster nested within PSUs (level 3), and PSU nested within governorates (level 4). MLM included fixed effects of individual factors [38]. Logistic regressions were performed, adjusting for maternal age, residence, education, employment, and household wealth. The sampling weights, applied by EDHS statisticians for national representativeness, were accounted for in multilevel regressions. Sampling weights were rescaled, since including raw weights without scaling in MLM could lead to biased parameters and standard errors [38], so that the new weights would sum to the effective cluster size [38].

Multilevel models were applied by socioeconomic strata as per the following model specifications:where Y_ijkl is the outcome for birth i (level 1), within cluster j (level 2), within PSU k (level 3), within governorate l (level 4). α is a constant and X_{1ijkl …….} X_nijkl are the explanatory variables, with β_{1 ……} βn as their coefficients. T_ijkl is a binary variable that is 1 for the ‘peri-conflict’ sample and 0 otherwise, with γ as its coefficient. θ_l, μ_kl and η_jkl are the error terms at governorate, PSU and cluster levels respectively.

Next, interactions between conflict and each explanatory variable were estimated in turn as per the following model specification:

where Y_ijkl is the outcome for birth i (level 1), within cluster j (level 2), within PSU k (level 3), within governorate l (level 4). α is a constant and X_{1ijkl …….} X_nijkl are the explanatory variables, with β_{1 ……} βn as their coefficients. T_ijkl is a binary variable that is 1 for the ‘peri-conflict’ sample and 0 otherwise, with γ as its coefficient. T.X is the interaction term between conflict and the given explanatory variable, with ρ as its coefficient. θ_l, μ_kl and η_jkl are the error terms at governorate, PSU, and cluster levels respectively.

Finally, a joint test of the interaction terms was performed using a Wald test to assess whether the effect of conflict on each outcome variable varied significantly between strata for a given explanatory variable.

Table 1 shows descriptive analysis of key socio-demographic variables. The pre-conflict sample included 2569 births and the peri-conflict sample included 4641 births. The DHS report indicated that this near doubling of births in the peri-conflict period compared to the pre-conflict period was due to an unusual national doubling of births from 2011 to early 2013 [21]. For example, the total number of stillbirths to women aged 15–49 was 29,349 during 2012–2014 and only 8109 during 2009–2010 [21]. In the pre-conflict period, 66% of births were to women aged 30+ years, peri-conflict this was 41%. There was a marked shift to younger maternal age between pre-conflict and peri-conflict periods and this trend of early childbirth among women in Egypt and the region has been widely discussed [21, 41]. The majority of births were to women with secondary or higher education (58% pre-conflict, 62% peri-conflict) and from rural settings (65% pre-conflict, 69% peri-conflict). Above half of women gave birth to a male baby (55% pre-conflict, 53% peri-conflict) in their last birth preceding the survey. The largest wealth quintile was the middle (24% pre-conflict, 25% peri-conflict). A majority of births were to non-working women (85% pre-conflict, 87% peri-conflict). Slightly above half of women already had 2–3 children (60% pre-conflict, 54% peri-conflict). Nearly all women (97%) were Muslim, while the rest were Christian.

Table 2 provides the stratified analysis of adjusted associations of age-group with maternal outcomes in the peri-conflict period compared to the pre-conflict period. The joint interaction test suggested that the effect of conflict on maternal care use differed by age group for several outcomes: receiving ANC from a government provider (p = 0.003), receiving ANC from a doctor (p < 0.001), delivering in public institutions (p = 0.01) and receiving any PNC (p = 0.02). In the stratified analysis, the reduction in the odds of receiving ANC from a government provider during conflict was relatively greater for younger women (e.g. age < 25: OR 0.91; 95% CI 0.83–0.99) than for older women (e.g. age > 35: OR 0.98; 95% CI 0.95–1.02); the increase in the odds of receiving ANC from a doctor during conflict was relatively greater for younger women (e.g. age < 25: OR 1.09; 95% CI 0.95–1.25) than for older women (e.g. age > 35: OR 0.99; 95% CI 0.98–1.01); the reduction in the odds of delivering in a public institution during conflict was relatively greater for younger women (e.g. age < 25: OR 0.93; 95% CI 0.87–0.99) than for older women (e.g. age > 35: OR 0.99; 95% CI 0.96–1.02). The association with receiving any PNC was more complicated, with women aged 25–29 having the greatest reduction in odds during conflict (OR 0.92; 95% CI 0.88–0.96) and women aged above 35 having the greatest increase (OR 1.05; 95% CI 0.99–1.11).

In Table 3, the interaction test showed that the effect of conflict differed by maternal residence for receiving ANC from a government provider (p = 0.01), SBA (p < 0.001), physician-assisted delivery (p < 0.001), and delivery in public institutions (p = 0.03). In the stratified analysis, the reduction in the odds of receiving ANC from a government provider during conflict was relatively greater for rural women (OR 0.99; 95% CI 0.98–0.99) than for urban women (OR 0.99; 95% CI 0.96–1.01); the increase in odds of receiving SBA during conflict was relatively greater for rural women (OR 1.02; 95% CI 1.02–1.03) than for urban women (OR 1.00; 95% CI 0.99–1.01); the increase in odds of receiving physician-assisted delivery during conflict was relatively greater for rural women (OR 1.03; 95% CI 1.02–1.04) than for urban women (OR 1.01; 95% CI 0.98–1.04); and the reduction in odds of public institutional delivery during conflict was relatively greater for urban women (OR 0.97; 95% CI 0.95–0.99) than for rural women (OR 1.00; 95% CI 0.98–1.01).

In Table 4, the joint interaction test showed that the effect of conflict differed by maternal education level for SBA (p < 0.001), physician-assisted delivery (p < 0.001), and delivery in public institutions (p = 0.01). In the stratified analysis, the increase in the odds of receiving SBA during conflict was relatively greater for women educated to primary level (OR 1.04; 95% CI 1.01–1.07) than for women with no education (OR 1.00; 95% CI 0.96–1.05) or women educated to secondary level (OR 1.00; 95% CI 0.99–1.01); the increase in the odds of doctor-assisted deliveries during conflict was relatively higher for women educated to primary level (OR 1.05; 95% CI 1.01–1.10) than for women with no education (OR 1.00; 95% CI 0.97–1.05) or women educated to secondary level (OR 1.01; 95% CI 1.00–1.03); and the reduction in the odds of delivery in a public institution was relatively greater for women educated to secondary level (OR 0.97; 95% CI 0.96–0.99) than for women with no education (OR 1.01; 95% CI 0.95–1.07) or women educated to primary level (OR 1.02; 95% CI 0.99–1.05).

In Table 5, the interaction test showed that the effect of conflict differed by maternal employment status for SBA (p = 0.01) and physician-assisted deliveries (p < 0.001). Stratified analysis showed that the increase in the odds of SBA during conflict was relatively greater for employed mothers (OR 1.04; 95% CI 1.01–1.07) than for unemployed mothers (OR 1.01; 95% CI 1.00–1.02) and the increase in the odds of physician-assisted delivery was also greater for employed mothers (OR 1.07; 95% CI 1.02–1.11) than for unemployed mothers (OR 1.01; 95% CI 1.00–1.02).

In Table 6, the joint interaction test showed that the effect of conflict differed by household wealth status for receiving 4+ ANC visits (p < 0.001), ANC from a government provider (p = 0.004), SBA (p < 0.001), and physician-assisted delivery (p < 0.001). Stratified analysis showed that the increase in the odds of having any ANC (i.e. either 4+ ANC visits, ANC from government provider, or ANC from a doctor) during conflict was relatively lowest for women from poorest households (OR 1.00; 95% CI 0.98–1.02) than women in all the other wealth quintiles (all with OR 1.01); the reduction in odds of receiving ANC from a government provider during conflict was relatively greater for women from richest households (OR 0.97; 95% CI 0.95–0.98) than women in all other wealth quintiles (all OR 0.99 or greater); the increase in the odds of SBA during conflict was relatively greater for women from less poor households (OR 1.03; 95% CI 1.02–1.05) than women in all other wealth quintiles (all OR 1.02 or less); and the increase in the odds of physician-assisted delivery during conflict was relatively greater for women from less poor (OR 1.03; 95% CI 1.01–1.05) and middle households (OR 1.03; 95% CI 1.01–1.05) than women in other wealth quintiles (all OR 1.02 or less).

Study findings show that existing equity patterns in maternal care changed unpredictably during the conflict. If the healthcare delivery system is well developed with progressive health financing, the scope for a conflict to cause large inequities is limited. However, given the limited availability of quality maternal care, inequities in service delivery, and regressive health financing in Egypt, maternal policy could benefit from specific in-built equity strategies to address unpredictable effects of conflict on equity [2, 4]. For example, strategic involvement of community-based groups, volunteers, and local providers has helped pregnant women during emergencies [3]. Depending on the severity of conflict and women’s relative vulnerability, failure to implement remedial measures could worsen equity [2, 4].

Experiences in several countries affected by acute and sporadic conflicts (e.g. Nepal, Myanmar) showed that post-conflict reconstruction could offer opportunities to build more equitable health systems than existed previously [17, 61]. The commitment shown by Egyptian policy-makers in implementing multi-sectorial policy measures to address health inequities is worth acknowledging [10, 65]. Improved maternal care use among socioeconomically disadvantaged groups could be partially due to this increased policy attention. Increasing the involvement of non-state actors may strengthen the government’s equity-driven initiatives further. For instance, active participation of civil society in policy-making may inspire maternal health policies to be more equity-focused [30]. Given the financial and technical constraints in the public health system, development partners and the private sector could leverage funding and technical capacity to implement equitable maternal care strategies [64]. Enhancing the capacity of providers and community-based networks could reduce access barriers for previously marginalised groups [30].

Due to data constraints, this study did not assess the association between conflict, out-of-pocket expenditure, and financial catastrophes due to maternal care. Egypt’s proportion of out-of-pocket healthcare expenditure is high at more than 70%, while its financial risk-protection measures are still evolving [41]. User fees and lack of pre-payment systems are known limitations in the Egyptian health system [66, 67]. During major conflicts, financial access to care typically deteriorates due to collapsing livelihoods and healthcare delivery services [2]. Though the 2011–2012 Egyptian conflict was not particularly severe, maternal needs could have engendered financial hardship, particularly among poorer groups [27, 68‐70].

In-depth research is needed to explore the underlying drivers of maternal care equity during future conflicts [42]. It should be noted that socioeconomic adversity in Egypt is more concentrated in the Rural South Region, which was relatively less conflict-affected than the more affluent urban areas [11, 20]. This could be a reason for maternal care among vulnerable groups not being more significantly adversely affected by conflict in this study. Egypt has recently been implementing several maternal and child health initiatives in the Rural South Region [20], which could have positively influenced maternal care among socioeconomically disadvantaged groups. Additional evidence is needed on the differential association of conflict and quality of maternal care used by different groups. Assessing the equity dimension in quality of maternal care would help understanding of conflict’s potential effect on maternal health status among different groups [71]. The literature indicates that LMICs generally provide relatively low-quality maternal services to economically poorer women, as is reportedly the case in Egypt [70, 72].

Several potential limitations relate to the nature of the data. First, as DHS data were not specifically collected to assess the effects of conflict, customising data led to omitting relevant ANC and PNC variables due to incompatibility with a before-and-after analysis. Second, DHS data were self-reported and described details of maternal care-seeking in previous years, possibly leading to recall or social desirability biases [73]. However, a validation study in LMICs found moderate to high sensitivity and moderate validity for self-reported coverage of maternal care in surveys [74, 75]. DHS data were representative of childbirth experiences in the general population, and DHS employed standardised procedures to ensure data quality and tools were rigorously tested across time. Third, the EDHS wealth index is potentially biased against rural households, by including more items or utilities (e.g. electrical appliances) suited to urban populations [73]. Fourth, underlying temporal trends could have influenced the measurement of effect size, though the period under consideration was too short for a large temporal trend to have occurred [75]. Fifth, as the effect size found was relatively small, qualitative exploration would have been helpful to generate additional explanatory evidence. Sixth, given the country-wide geographical spread of the conflict and lack of data on region-specific exposures, this study considered all women to be equally exposed to conflict and could not differentiate level of exposure. Finally, the number of outcomes and potential effect modifiers considered meant that multiple statistical tests were performed, increasing the likelihood of finding evidence of effect modification by chance alone.