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. 2019 Jun 14;19:760. doi: 10.1186/s12889-019-7111-8

Socioeconomic factors contributing to under-five mortality in sub-Saharan Africa: a decomposition analysis

Carine Van Malderen 1,, Agbessi Amouzou 2, Aluisio J D Barros 3, Bruno Masquelier 4,5, Herman Van Oyen 6,7, Niko Speybroeck 1
PMCID: PMC6570834  PMID: 31200681

Abstract

Background

In sub-Saharan Africa, socioeconomic factors such as place of residence, mother’s educational level, or household wealth, are strongly associated with risk factors of under-five mortality (U5M) such as health behavior or exposure to diseases and injuries. The aim of the study was to assess the relative contribution of four known socioeconomic factors to the variability in U5M in sub-Saharan countries.

Methods

The study was based on birth histories from the Demographic and Health Surveys conducted in 32 sub-Saharan countries in 2010–2016. The relative contribution of sex of the child, place of residence, mother’s educational level, and household wealth to the variability in U5M was assessed using a regression-based decomposition of a Gini-type index.

Results

The Gini index – measuring the variability in U5M related to the four socioeconomic factors – varied from 0.006 (95%CI: 0.001–0.010) in Liberia 2013 to 0.034 (95%CI: 0.029–0.039) in Côte d’Ivoire 2011/12. The main contributors to the Gini index (with a relative contribution higher than 25%) were different across countries: mother’s educational level in 13 countries, sex of the child in 12 countries, household wealth in 11 countries, and place of residence in 8 countries (in some countries, more than one main contributor was identified).

Conclusions

Factors related to socioeconomic status exert varied effects on the variability in U5M in sub-Saharan African countries. The findings provide evidence in support of prioritizing intersectoral interventions aiming at improving child survival in all subgroups of a population.

Keywords: Under-five mortality, Sub-Saharan Africa, Poisson regression, Gini decomposition, Socioeconomic inequalities

Background

The under-5 mortality rate (U5MR), the probability of dying before 5 years of age (per 1000 live births), is a key global indicator of child health [1], and one of the most important measures of global health [2]. Previously targeted in the fourth Millennium Development Goal (MDG), U5MR now appears in the third Sustainable Development Goal (SDG3) [3], aiming to reduce under-5 mortality to at least as low as 25 deaths per 1000 live births in all countries by 2030. Though the global U5MR dropped from 93 deaths per 1000 live births in 1990 to 39 in 2017, the highest rates are still seen in sub-Saharan Africa, with an U5MR of 76 deaths per 1000 live births in 2017, leading to 2.7 million deaths in the region. A vast majority of these deaths are amenable to health care and prevention, as the leading causes of death among children under age five include preterm birth complications, pneumonia, intrapartum-related complications, diarrhea and malaria [4, 5].

Even if U5MR has declined in most sub-Saharan African countries, substantial inequalities between sub-groups of the population still exist within countries [6]. Population sub-groups may be defined by different dimensions such as place of residence, sex of children, ethnicity, and maternal factors such as educational level, occupation or income [7]. These socioeconomic factors are included in the Mosley and Chen conceptual framework as the distal determinants of child mortality [7]. In this framework, socioeconomic determinants operate at three levels (the community, the household, and the individual) and affect mortality through proximate determinants such as maternal factors, environmental contamination, nutrient deficiency, injury, and personal illness control.

The magnitude of socioeconomic inequalities in U5MR may be assessed by studying each socioeconomic factor separately, using the concentration index, and income or wealth are among the most widely studied [810]. However, the concentration index measuring wealth-related inequalities in U5MR was not significant in several sub-Saharan countries [8, 11], an observation calling for further research on other dimensions of socioeconomic inequalities in U5MR.

Identifying the larger socioeconomic gaps in U5MR across a population may be done by assessing the relative contribution of several socioeconomic factors to the variability in U5MR, using a multivariate regression model and additional decomposition techniques [12].

Taking a set of four socioeconomic factors representative of the multiple dimensions of a society’s stratification in U5MR, the aim of the study was to identify which one(s) contributed the most to the variability in U5MR in sub-Saharan African countries.

Methods

Conceptual framework

Four factors were selected as proxies for the main socioeconomic determinants introduced by Mosley & Chen [13]: place of residence for the community level (ecological setting, political economy and health system), household wealth for the household level (goods and services such as food, housing, transportation, financial access to care), mother’s educational attainment for the individual level (mother’s choices and skills in health care practices), and sex of the child also for the individual level (differential feeding and medical care practices). However, the gender of the child may represent both gender discrimination and a biological disadvantage [14]. These four factors are the main socioeconomic factors used to describe U5MR by population subgroups at the international level [6, 10, 14, 15].

Data

Data from 32 Sub-Saharan African countries with a standard Demographic and Health Survey (DHS) completed in 2010–2016 (the most recent available at the time of the analysis, in July 2018) were used. Details on survey sampling, data collection and data processing are available on the DHS Program website [16]. In total, the study gathered data from 366,960 children obtained from the interview of 248,732 mothers.

The outcome variable was under-five death. This information was obtained from the birth history of interviewed females aged 15 to 49 [16]. The analysis was restricted to the last 5 years preceding the survey to limit the time gap between the event and the collection of socioeconomic information. The socioeconomic factors investigated were: sex of the child, place of residence (urban or rural), mother’s educational level (lower than primary, primary and above), and household wealth (poorest/middle tertiles versus the highest tertile). Household wealth tertiles were derived from the wealth index provided with the DHS data, constructed from several household assets (type of flooring, water supply, sanitation facilities, electricity, persons per sleeping room, ownership of agricultural land, domestic servant, and other assets). U5MR was calculated in each wealth tertile, then the tertiles “poorest” and “middle”, showing similar levels of U5MR in a majority of countries, were pooled to have the same number of categories for the four variables, hence avoiding any bias overestimating the contribution of variables with more categories. The proportion of missing values for the included variables was lower than 0.03% in all countries.

Data analysis

Distinct individual level analyses were carried out for the 32 included countries. U5MR was estimated in each population sub-group with the synthetic cohort probability method employed in DHS [17]. Differences in U5MR between subgroups were tested with a bootstrap technique.

The relative contribution of each factor to the variability in U5MR was made using a regression-based decomposition of a Gini index, described below.

A multivariate Poisson regression model (with exposure time as offset) was used. Multi-collinearity was checked and no variance inflation factor was greater than 10. Analyses were weighted (using weights available in the DHS datasets), accounting for clustering (with cluster as the primary sampling unit and household as the secondary sampling unit) and for stratification (with region as strata). The significance threshold was set up at 5%.

Variability in the obtained individuals’ predicted death rates was assessed with a Gini index (G), and decomposed using Wagstaff’s method [1821]. G is defined as twice the covariance of the health variable (here predicted death rates) and the person’s fractional rank in the distribution of health, divided by the mean level of health. As the mean of the predicted death rates was negative, G ranged between − 1 (maximum variability) and 0 (no variability), but for the description of the variability in all countries, the sign was reversed so higher values mean more variability. A factor’s relative contribution to the Gini index is the product of its elasticity (bx¯y¯, where b is the factor’s regression coefficient, x¯ its mean and y¯ the mean of the predicted death rates) and its concentration index (a Gini-type measure of its unequal distribution in the population ranked by predicted death rate), divided by the overall G. Factors’ concentration indexes ranged from - 1 (the factor is more concentrated among the lower values of the health variable) to 1 (the factor is more concentrated among the higher values of the health variable), 0 meaning equal distribution in the population. The four factors’ relative contributions were presented in percent, adding up to 100%. A factor was defined as a main contributor if it contributed to at least 25% to the variability in U5M.

RGui (R version 3.4.0., The R foundation for Statistical Computing) and Stata 14.0 (calculation of U5M) were used for the data analysis (an overview of the R code is provided in Appendix 1).

Results

Under-five mortality rate (U5MR) versus variability in U5MR in the 32 countries

U5MR ranged from 49 [95%CI:42;57] deaths per 1000 live births in Rwanda 2014/15 to 152 [95%CI:138;166] in Sierra Leone 2013 (Fig. 1). The Gini index, assessing the variability in U5MR related to the four factors – sex of the child, place of residence, mother’s education and household wealth, varied from 0.006 (95%CI: 0.001–0.010) in Liberia 2013 to 0.034 (95%CI: 0.029–0.039) in Côte d’Ivoire 2011/12. No correlation could be identified between U5MR and the Gini indexes (Pearson’s correlation coefficient r = 0.10, p = 0.59). Table 1 shows U5MR in all countries, at national level and by population subgroup. U5MR was significantly lower in females compared to males in 9 countries, in urban compared to rural areas in 12 countries (the contrary was observed in Tanzania 2015/16 where U5MR was higher in urban areas), in children born to mothers with at least a primary education compared to children born to mothers without any formal education in 19 countries, and in the richest households compared to the poorest of middle wealth households in 17 countries.

Fig. 1.

Fig. 1

Under-five mortality rates (U5MR, left) versus variability in U5MR measured by a Gini index (right) in the 32 countries, Demographic and Health Surveys 2010–2016 (0–5 years prior to each survey)

Table 1.

Under-five mortality (‰) by determinant in the 32 countries, Demographic and Health Surveys 2010–2015

Sex of the child Place of residence Mother’s education Household wealth
n Total Male Female p Rural Urban p None Primary+ p Poorest/Middle Richest p
Western Africa
 Burkina Faso 2010 15,044 128 139 117 0,016 137 80 < 0.001 133 61 < 0.001 144 96 < 0.001
 Senegal 2010–11 12,326 66 73 60 0,12 82 41 < 0.001 71 33 < 0.001 76 47 < 0.001
 Benin 2011–12 13,407 72 77 66 0,11 82 56 0,001 76 47 < 0.001 81 52 < 0.001
 Cote d’Ivoire 2011–12 7776 112 145 79 < 0.001 113 111 0,84 119 80 0,004 111 115 0,80
 Guinea 2012 7039 123 135 109 0,032 140 74 < 0.001 130 68 < 0.001 148 71 < 0.001
 Niger 2012 12,558 133 148 118 0,032 143 65 < 0.001 135 84 0,001 143 112 0,026
 Gambia 2013 8088 52 54 50 0,70 50 54 0,67 60 33 0,003 52 50 0,82
 Mali 2012–13 10,326 102 122 80 < 0.001 110 64 < 0.001 107 45 < 0.001 119 67 < 0.001
 Liberia 2013 7606 96 104 88 0,32 91 101 0,51 101 83 0,34 102 83 0,34
 Nigeria 2013 31,482 121 129 113 0,001 143 80 < 0.001 151 82 < 0.001 146 71 < 0.001
 Sierra Leone 2013 11,938 152 163 141 0,063 153 150 0,89 157 131 0,032 153 151 0,86
 Togo 2013–14 6979 93 90 97 0,49 101 79 0,10 106 61 0,001 104 71 0,004
 Ghana 2014 5884 63 76 50 0,12 73 51 0,18 87 44 0,030 72 46 0,045
Central Africa
 Cameroon 2011 11,732 128 128 128 0,99 149 98 < 0.001 167 82 < 0.001 147 89 < 0.001
 Congo 2011–12 9329 70 78 63 0,22 64 74 0,28 75 68 0,50 71 69 0,93
 Gabon 2012 6067 89 112 63 0,098 96 87 0,57 92 88 0,89 89 88 0,95
 DRCongo 2013–14 18,716 107 113 102 0,25 113 95 0,096 118 93 0,007 114 93 0,058
 Chad 2014–15 18,623 138 149 126 0,001 137 140 0,84 139 129 0,53 145 125 0,043
Eastern Africa
 Mozambique 2011 11,102 94 101 87 0,092 97 88 0,36 98 76 0,060 97 88 0,38
 Comoros 2012 3149 51 52 50 0,89 58 33 0,024 60 35 0,060 51 51 >0,99
 Kenya 2014 20,964 54 58 49 0,13 50 60 0,095 58 51 0,18 56 49 0,25
 Rwanda 2014–15 7856 49 57 42 0,030 49 49 0,99 57 34 < 0.001 55 38 0,015
 Malawi 2015–16 17,286 63 71 55 0,083 65 51 0,20 66 55 0,15 69 52 0,038
 Tanzania 2015–16 10,233 68 72 64 0,20 62 85 0,009 71 66 0,63 67 69 0,75
 Ethiopia 2016 10,641 71 81 61 0,087 74 46 0,024 73 48 0,13 73 69 0,65
 Uganda 2016 15,522 65 72 58 0,015 69 49 < 0.001 75 50 < 0.001 71 53 0,002
 Burundi 2016–17 13,192 77 82 72 0,13 79 57 0,070 81 64 0,028 84 62 0,018
Southern Africa
 Namibia 2013 5046 59 60 58 0,87 63 55 0,47 63 58 0,65 62 54 0,44
 Zambia 2013–14 13,457 70 77 63 0,075 71 68 0,60 77 63 0,040 73 65 0,19
 Lesotho 2014 3138 86 78 97 0,32 91 77 0,38 108 80 0,11 88 84 0,84
 Zimbabwe 2015 6132 66 75 58 0,059 74 49 0,006 87 63 0,095 77 46 < 0.001
 Angola 2015–16 14,322 68 73 63 0,18 85 57 < 0.001 79 49 < 0.001 80 44 < 0.001

U5M and p-values were calculated using the synthetic cohort probability method (“syncmrates” function in Stata)

Factors associated with U5MR in the multivariate analyses, and their relative contribution to the variability in U5MR

Table 2 shows all components of the Gini index decomposition: the overall Gini index, the mean of the predicted death rates (obtained with the multivariate Poisson regression model), variables’ means, regression coefficients, and concentration indexes. The relative contribution of a factor is calculated as the product of its mean, its regression coefficient, and its concentration index, divided by the mean of the predicted death rates, then by the overall Gini index. For instance, the relative contribution of sex of the child in the 2011–2012 DHS in Benin equals 0.48*(− 0.20)*(− 0.29) / − 6.34 / -0.017 = 26%. In Fig. 2, countries were classified according to the factor(s) which contributed to more than 25% of the variability in U5M. As the relative contributions add up to 100% and we consider 4 different factors, a contribution exceeding 25% for one factor suggests the existence of a socioeconomic gap in U5MR more marked than for the other factors.

Table 2.

Means, regression coefficient and relative contribution (%) of the selected determinants in the 32 sub-Saharan countries, Demographic and Health Surveys 2010–2015

Sex of the child Place of residence Mother’s education Household wealth
Female Urban Primary+ Richest
n G mean(y) mean b c %Gini mean b c %Gini mean b c %Gini mean b c %Gini
Western Africa
 Senegal 2010–11 12,326 -,026 −6,37 ,49 -,23 -,24 16 ,38 -,44 -,61 60 ,12 -,30 -,73 15 ,33 -,09 -,50 9
 Burkina Faso 2010 15,039 -,024 −5,77 ,49 -,13 -,23 10 ,17 -,22 -,78 20 ,07 -,30 -,84 13 ,33 -,36 -,66 56
 Benin 2011–12 13,407 -,017 -6,34 ,48 -,20 -,29 26 ,40 ,00 -,24 0 ,15 -,06 -,59 5 ,33 -,34 -,67 69
 Cote d’Ivoire 2011–12 7776 -,034 −5,83 ,50 -,63 -,50 75 ,37 -,29 -,27 14 ,18 -,30 -,44 11 ,33 ,24 -,16 0
 Guinea 2012 7039 -,029 −5,78 ,49 -,16 -,24 11 ,26 -,04 -,67 4 ,12 -,34 -,75 18 ,33 -,52 -,67 68
 Niger 2012 12,537 -,017 -5,85 ,49 -,10 -,39 18 ,13 -,73 -,87 82 ,06 ,00 -,23 0 ,33 ,05 -,05 0
 Mali 2012–13 10,326 -,028 −6,04 ,48 -,31 -,29 25 ,19 -,13 -,71 10 ,10 -,28 -,70 11 ,33 -,41 -,66 53
 Gambia 2013 8088 -,018 −6,55 ,49 -,03 -,12 1 ,48 ,25 ,13 13 ,32 -,46 -,68 85 ,33 ,04 ,11 1
 Liberia 2013 7606 -,006 −6,00 ,49 -,02 -,22 8 ,50 ,10 ,12 19 ,32 -,09 -,53 48 ,33 -,09 -,29 25
 Nigeria 2013 31,482 -,032 −5,77 ,50 -,15 -,15 6 ,35 -,23 -,57 25 ,45 -,27 -,51 33 ,33 -,30 -,65 36
 Sierra Leone 2013 11,938 -,007 −5,46 ,50 -,13 -,50 92 ,26 ,02 ,38 7 ,21 ,01 ,26 2 ,33 -,01 ,08 0
 Togo 2013–14 6979 -,025 −6,16 ,50 -,22 -,21 15 ,36 -,17 -,51 21 ,30 -,39 -,66 52 ,33 -,10 -,55 13
 Ghana 2014 5884 -,016 −6,44 ,48 -,16 -,27 20 ,45 -,01 -,12 1 ,58 -,34 -,42 80 ,33 ,04 -,11 0
Central Africa
 Cameroon 2011 11,732 -,030 −5,79 ,51 -,04 -,11 1 ,42 -,11 -,45 12 ,48 -,44 -,52 63 ,33 -,20 -,59 23
 Congo 2011–12 9329 -,015 −6,31 ,50 -,23 -,32 38 ,61 ,29 ,17 32 ,71 -,08 -,10 6 ,33 -,25 -,28 24
 Gabon 2012 6067 -,022 −6,29 ,48 -,42 -,49 71 ,84 -,17 -,07 7 ,74 -,25 -,15 20 ,33 ,05 ,11 1
 Chad 2014–15 18,623 -,013 −5,69 ,49 -,24 -,51 78 ,20 ,19 ,24 12 ,15 -,04 -,30 2 ,33 -,16 -,10 7
 DRCongo 2013–14 18,716 -,011 −5,93 ,50 -,08 -,27 15 ,31 ,04 -,45 0 ,48 -,05 -,31 11 ,33 -,24 -,67 74
Eastern Africa
 Mozambique 2011 11,102 -,010 −5,91 ,49 -,13 -,37 42 ,28 ,00 -,41 1 ,17 -,15 -,81 35 ,33 -,09 -,43 22
 Comoros 2012 3138 -,029 −6,57 ,49 -,10 -,13 3 ,27 -,58 -,70 56 ,35 -,42 -,53 41 ,33 ,31 -,03 0
 Kenya 2014 20,964 -,012 −6,52 ,49 -,12 -,33 25 ,36 ,33 ,45 69 ,60 -,09 -,06 5 ,33 -,22 -,02 2
 Rwanda 2014–15 7856 -,017 −6,63 ,50 -,23 -,41 42 ,17 ,00 -,40 0 ,34 -,23 -,47 32 ,33 -,22 -,41 26
 Malawi 2015–16 17,286 -,014 −6,42 ,50 -,28 -,50 75 ,13 ,05 -,14 0 ,29 ,05 ,02 0 ,33 -,21 -,33 25
 Tanzania 2015–16 10,233 -,019 −6,31 ,49 -,19 -,31 22 ,27 ,48 ,73 73 ,66 ,08 ,13 5 ,33 -,13 ,30 0
 Ethiopia 2016 10,638 -,022 −6,31 ,48 -,44 -,52 78 ,11 -,36 -,46 13 ,09 -,06 -,27 1 ,33 ,24 ,14 8
 Uganda 2016 15,521 -,019 −6,37 ,50 -,28 -,34 38 ,21 -,16 -,48 13 ,41 -,29 -,50 49 ,33 ,04 -,18 0
 Burundi 2016–17 13,189 -,015 −6,23 ,49 -,13 -,22 15 ,09 ,12 -,46 0 ,25 -,18 -,63 29 ,33 -,26 -,63 56
Southern Africa
 Namibia 2013 5046 -,010 −6,45 ,51 -,06 -,17 8 ,49 -,12 -,48 43 ,77 -,02 -,12 2 ,33 -,14 -,65 47
 Zambia 2013–14 13,446 -,012 −6,27 ,49 -,21 -,50 70 ,34 ,07 ,05 1 ,49 -,15 -,26 27 ,33 -,02 -,08 1
 Lesotho 2014 3138 -,012 −5,97 ,51 -,01 -,11 1 ,29 -,17 -,60 38 ,79 -,29 -,21 62 ,33 ,09 -,21 0
 Zimbabwe 2015 6132 -,026 −6,29 ,51 -,25 -,29 20 ,32 ,16 -,57 0 ,86 -,24 -,09 10 ,33 -,61 -,66 70
 Angola 2015–16 14,319 -,027 −6,36 ,50 -,29 -,28 23 ,60 -,23 -,30 23 ,37 -,06 -,41 5 ,33 -,38 -,67 48

G: Gini index; mean(y): mean of the predicted (ln) death rates; mean: mean of the dummy variable (coded 0/1), corresponds to the proportion of the factor in the country; b: regression coefficient from a multivariate Poisson model (in bold if significant); %Gini: relative factor’s contribution calculated with the regression-based decomposition of the Gini indexh; A few negative contributions were restricted to 0

Fig. 2.

Fig. 2

Classification of the 32 countries according to the main contributors to the variability in U5MR. A factor was defined as a main contributor if its contribution to the variability in U5MR exceeded 25% according to the regression-based decomposition of the Gini index (Table 2). The Venn diagram was developed using the R function “venn.diagram”

Sex of the child

After adjustment for the three other covariates, the U5MR was significantly lower in girls than in boys in 16 countries (Table 2). Among the 12 countries where sex of the child contributed to more than 25% of the variability in U5MR, this factor was the only main contributor in Chad 2014/15, Côte d’Ivoire 2011/12, Ethiopia 2016, Gabon 2012, Malawi 2015/16, and Sierra Leone 2013 (Fig. 2).

Place of residence

The proportion of children living in urban areas varied from 9% in Burundi 2016/17 to 84% in Gabon 2012. After adjustment, the excess rural mortality was significant in Niger 2012, Nigeria 2013, Senegal 2010/11, and Comoros 2012, and the excess urban mortality was significant in Kenya 2014 and Tanzania 2015/16 (Table 2). Among the 8 countries where place of residence contributed to more than 25% of the variability in U5MR, this factor was the only main contributor in Kenya 2014, Niger 2012, Senegal 2010/11, Tanzania 2015/16, and Namibia 2013 (Fig. 2).

Mother’s education

The proportion of children whose mother had at least a primary education level varied from 6% in Niger 2012 to 86% in Zimbabwe 2015. After adjustment, the observed protective effect of mother’s education on U5MR was significant in Gambia 2013, Nigeria 2013, Togo 2013/14, Cameroon 2011, and Uganda 2016. Among the 12 countries where mother’s education contributed to more than 25% of the variability in U5MR, this factor was the only main contributor in Ghana 2014, Gambia 2013, Liberia 2013, and Togo 2013/14, four countries in Western Africa (Fig. 2).

Household wealth

After adjustment, the observed protective effect of household wealth on U5M was significant in 10 countries. Among the 11 countries where household wealth contributed to more than 25% of the variability in U5MR, this factor was the only main contributor in Angola 2015/16, Burkina Faso 2010, DR Congo 2013/14, Guinea 2012, Mali 2012/13, and Zimbabwe 2015 (Fig. 2).

Combination of socioeconomic factors

In some countries, more than one factor contributed to more than 25% of the variability in U5MR: sex of the child and mother’s education in Mozambique 2011, Uganda 2016, Zambia 2013/14, and Rwanda 2014/15; sex of the child and household wealth in Benin 2011/12, sex of the child and place of residence in Congo 2011/12; mother’s education and household wealth in Burundi 2016/17 and Nigeria 2013, household wealth and place of residence in Namibia 2013, mother’s education and place of residence in Comoros 2012 and Lesotho 2014, and sex of the child, mother’s education, and household wealth in Rwanda 2014/15.

Discussion

Main results

This study shows that major inequalities in U5MR still exist in sub-Saharan Africa in 2010–2016 but that there is not just one single story applicable to all countries. The relative contribution of four socioeconomic factors to the variability in U5MR was assessed using a regression-based decomposition of a Gini index.

The main contributors differed according to the country.

In Benin, Chad, Congo, Côte d’Ivoire, Ethiopia, Gabon, Malawi, Mozambique, Rwanda, Sierra Leone, Uganda, and Zambia, considerable inequalities between boys and girls were observed. It has been shown that differences in survival between boys and girls exist at least up to the age of 5 years [14]. An excess male child mortality can be explained by biological factors (lower resistance to infection, higher risk of premature birth, difficult labour related to a larger average body size and head circumference), gender discrimination (differential feeding and medical care practices, or response to HIV-related drugs) [22, 23]. After adjusting for a range of individual, household and community variables (including age, birth order, household wealth, maternal education but also skilled birth attendance and other factors), the excess male mortality remained significant in several countries in Sub-Saharan Africa [24].

In Comoros, Congo, Kenya, Lesotho, Namibia, Niger, Senegal, and Tanzania, considerable inequalities related to the place of residence were observed in this analysis. In Comoros, Lesotho, Namibia, Niger, and Senegal, U5MR was lower in urban areas while in Congo, Kenya, and Tanzania, U5MR was lower in rural areas. The effect of place of residence on U5MR, adjusted for sex of the child, mother’s education, and household wealth, may have operated through ecological setting, political economy and health system [13, 25]. Though the urban-rural difference is narrowing or even reversing in some countries (as a result of a more rapid mortality decline in rural areas than in urban areas and deplorable living conditions in urban slums [26]), an urban advantage persists in many countries. This urban advantage can be attributed to access to health services and better economic opportunities for families [27, 28]. In Niger, the observed excess infant mortality, was partly explained by the existence of a health facility within the community [29].

In Burundi, Cameroon, Comoros, Gambia, Ghana, Lesotho, Liberia, Mozambique, Nigeria, Rwanda, Uganda, and Zambia, considerable inequalities related to the mother’s educational level were observed, with lower mortality rates if the mother had at least a primary educational level. The effect of mother’s education on U5MR, adjusted for sex of the child, place of residence, and household wealth, may have operated through empowerment, health and reproductive behaviour (e.g. birth spacing) or health services utilization (e.g. knowledge, awareness) [13, 25]. This protective effect of maternal education adjusted for more covariates than in the study at hand, was also reported in Ghana [30], and Comoros [31]. Some assumptions suggested in a study on the factors associated with U5MR in rural Ghana were: educated mothers are more likely to receive antenatal care [32] (though the gap seems to be closing over time [33]), and motherhood could be delayed, decreasing the total number of children [34]. A recent study including, among other countries, Ghana and Nigeria showed that women’s education was associated with utilization of maternal health services: type of antenatal care provider, timing and frequency of antenatal care visits, place of delivery and presence of a skilled birth attendant at delivery [35]. Another study including Cameroon and Niger (among other countries), highlighted that the decline in under-five mortality rates, during last two decades, can be partly due to the government policies on women’s education, resulting in increased maternal awareness about child health and hygiene [36].

In Angola, Benin, Burundi, Burkina Faso, DR Congo, Guinea, Mali, Namibia, Nigeria, Rwanda, and Zimbabwe, considerable inequalities related to the household wealth were observed, with lower mortality rates in richest households. The effect of household wealth on U5MR, adjusted for sex of the child, place of residence, and mother’s educational level, may have operated through access to goods and services such as food, housing, transportation, or financial access to care [13, 25]. A study looking at changes in inequalities between the poorest and the least poor in mortality levels, using comparisons between successive surveys, showed that these inequalities widened in some of the afore-mentioned countries: Benin (2001), Namibia (2000) [37], Burundi (2010), Burkina Faso (2010), DR Congo (2007), Mali (2010), Nigeria (2008), and Rwanda (2010) [38].

The current paper focuses on U5MR but a sub-analysis by age group was also conducted (see Appendix 2), distinguishing between neonatal mortality (0–1 month), post-neonatal mortality (1–11 months), infant mortality (0–11 months) and child mortality (12–59 months). This analysis showed that the main sources of inequality vary according to the age group: household wealth and sex of the child for neonatal mortality, mother’s education and sex of the child for infant mortality, mother’s education, household wealth and place of residence for post-neonatal and child mortality. This is in line with previous literature showing changes in the sex ratios of mortality as children get older [14], and suggests that later in the life of children, the socioeconomic factors such as household wealth, mother’s education and place of residence, may become more important sources of inequalities between subgroups. We report here mainly on under− 5 mortality, because it is one of the indicators recommended by the World Health Organization for policy-oriented monitoring of equity (“Under-5 mortality and, where possible, its components assessed separately: neonatal, neonatal, postneonatal, and infant mortality, and mortality among children 1-4 years”) [39]. The small number of deaths in the subgroup 1–4 years made the analysis less reliable. Further analysis should also consider children aged between 5 and 14 years, because about 1 million die globally in this age group [40], but there is very limited research on socioeconomic factors of child mortality beyond age 5.

Limitations

The DHS program provide quality survey data, both through internal quality assurance and control procedures (continuous instrument quality checks, appropriate field personnel training, high response rate [41] and through its transparent data files and survey methods descriptions [42]. However, the cross-sectional design of the survey does not allow accounting for the order of events; information on mother or household characteristics at the time of the interview does not fully reflect the status at child death. Information on child death depends on the mother’s will and ability to communicate the information, and reporting quality may vary across social groups [6]. Moreover, the U5MR estimates based on birth histories may differ from estimates based on vital registration systems, due to recall errors in reporting vital events or ages of children at death or at survey [43]. In addition, due to relatively small sample sizes, some categories have to been pooled together. In this study, mother’s education “secondary or higher” was pooled with primary education because too few cases were present in the former category, resulting in aberrant estimates. This type of transformation is likely to reduce the explanatory power of this variable. Similarly, household wealth tertile was dichotomized to avoid overestimating its contribution. In Sierra Leone, the middle wealth tertile showed the highest U5MR while in Comoros, the middle wealth tertile showed the lowest U5MR, but these differences were not significant. These effects were not shown in the analyses presented above and focusing on a difference between the richest and the others. Finally, it should be kept in mind that the four factors are hierarchically related [44] and the effect of place of residence may have been mediated by mother’s education or household wealth, thereby underestimating its relative contribution.

The study focuses on four known socioeconomic factors, but some external factors, such as conflicts, with potentially large impact on child mortality and socioeconomic resources in a country, were not adjusted for. A study matching birth histories from Demographic and Health Surveys with data on proximity to armed conflict (reported in the Uppsala Conflict Data Program Georeferenced Events Dataset) showed that the risk of dying before reaching age 1 was 5·2 per 1000 births higher for a child born within 50 km of an armed conflict than for a child born in the same region during periods without conflict (corresponding to a 7·7% increase above baseline) [45]. Among the 32 countries included in this study, 11 countries were affected by an armed conflict during the survey or in the five preceding years. The most affected countries were DR Congo (6617 armed-related deaths during the defined period), Nigeria (3169 deaths), and Mali (1349 deaths) [46]. However, studying how the socioeconomic factors contributing to under-five mortality in Sub-Saharan Africa change in conflict-affected settings is beyond the scope of this paper. More broadly, any positive or negative change in the organization or resources of a country or a community (health insurance, epidemics, pollution, migration or fertility) is likely to impact the distribution of the socioeconomic resources and their combined effect on child health.

Perspectives

First, the study focuses on relative inequality in U5MR between subgroups of the population. Considering absolute differences between groups is as important [47] because a low relative difference may hide a high absolute difference in high-mortality countries. The use of multivariate additive hazard models, also combining the prevalence and impact of the factors, [48, 49] could allow balancing the importance in absolute differences of each factor controlling for others, with a possibility to consider the “background” contribution of the factors not included.

Second, the identification of the main socioeconomic contributors to the variability in U5MR among the four factors deserve more investigations. To this end, other known factors associated with U5MR (such as antenatal care, skilled attendance at birth, access to sanitation facilities, age of the mother at birth, parity, region etc.) could be added in the multivariate models in order to explain the observed differences (but in DHS, some of these factors are known only for the surviving children). In addition, if a wealth-related inequality in U5MR is concerning, a regression-based decomposition of the concentration index could be performed, as was done before [11].

Third, another way forward would be to assess the association between changes in the socioeconomic factors and changes in U5MR over time, as Demographic and Health surveys, are being conducted every 5 years and allow exploring the impact of possible changes in the socioeconomic resources induced by major policies or crises in a country.

Fourth, although we found no significant correlation between U5MR and the Gini index related to sex of the child, place of residence, mother’s education or household wealth, this observation does not exclude a correlation with the Gini index commonly used to measure income-related inequality in a country [46]. Possible correlations between indicators such as U5MR, the “traditional Gini Index”, “Gross Domestic Product”, and other country-level indicators could be done using the data provided with the World Bank. Such an ecological (country-level) study was conducted on under-five mortality trends in sub-Saharan Africa between 1960 and 2000 and showed that U5MR was negatively associated with per capita income and urbanization, and positively associated with illiteracy [50]. Another study showed that the decline in U5MR was associated with several Worldwide Governance Indicators: government effectiveness, rule of law, control of corruption, regulatory quality, political stability and absence of violence [38].

Finally, in this study, the independent effect of the four socioeconomic factors on U5MR determined their contributions to the variability in U5MR. However, these factors may have interacting effects and the major differences could be between subgroups defined by several dimensions (e.g. girls from richest households living in urban areas vs boys from poorest households living in rural areas). A more in-depth detection of inequalities could be studied by including interaction terms into the regression models, or by using tools handling unspecified complex interactions such as classification and regression trees [51] and random forest [52].

Conclusions

Socioeconomic inequalities in U5MR exist in all countries, but the socioeconomic dimensions may differ across countries. Identifying these main contributors is important to guide research and interventions aiming at reducing U5MR in all population subgroups. Mother’s educational level appeared as an important factor in a majority of countries, followed by sex of the child, household wealth, and place of residence.

Acknowledgments

We thank the Measure Demographic and Health Survey Program for the datasets. We are grateful to Cesar Victora (International Center for Equity in Health, Pelotas, Brazil) for reviewing the original draft of the paper and for raising awareness about the hierarchical relations between determinants. We are also grateful to the reviewers for their comments and suggestions.

Abbreviations

DHS

Demographic and Health Survey

DR Congo

the Democratic Republic of the Congo

SDG3

The third Sustainable Development Goal

U5MR

Under-five mortality rate

Appendix 1

Overview of the R code used

# packages requiredlibrary(survey);library(foreign);library(car); library(party) ; library(decomp) ; library(VennDiagram)# import data and specify the survey designBenin<-read.dta("Benin.dta")Beninc<-svydesign(id=as.formula("~PSU+household"), weight=as.formula("~weights"), strata=as.formula("~region"),data=Benin)# Poisson regression-based decomposition methodm<-svyglm(deadu5~female+rural+ed+richest,offset=log(time),Beninc, family="quasipoisson")pr <- as.numeric(predict(m, newdata = m$model[, -1],vcov = FALSE))Benin$pr<-prc<-contribution(m,Benin$pr)# Venneuler (csv file one column by determinant coded 1/0 important or not)d<-read.csv("Imp.csv", sep=";", header=T)venn.diagram(x = list(Sex = which(d[,1]==1),Residence = which(d[,2]==1),Education = which(d[,3]==1),Wealth = which(d[,4]==1)),imagetype = "svg",fill = c("plum", "palegreen3", "cornflowerblue", "tan1"), filename="venn.svg");# Figure 1 map, example for U5Mlibrary(maptools) ; library(sp) ; library(lattice) ; library(shapefiles)library(RColorBrewer) ; library(classInt)shp<-readShapePoly("AfricanCountires")shp=merge(shp,result,by='COUNTRY', all.x=T, duplicateGeoms=T)quantile(shp$U5M[shp$U5M>0], probs = (0:5)/5)brks<-classIntervals(shp$U5M,n=5,style="fixed", fixedBreaks=c(0,49,63,68.8,93,119.2,152))cols<-brewer.pal(6, "Reds")plot(shp, col=cols[findInterval(shp$U5M, brks$brks, all.inside=T)])legend("bottomleft", legend=leglabs(round(brks$brks,1), under="<", over=">", between="-"),fill=cols, title= "Under-five mortality (‰)", inset = .12, cex=0.8)

Appendix 2

Analysis by age group

Table 3.

Neonatal mortality (0–1 month)

Sex of the child Place of residence Mother’s education Household wealth
Female Urban Primary+ Richest
n G mean(y) mean b c %Gini mean b c %Gini mean b c %Gini mean b c %Gini
Angola 2015–16 445 −.213 −.32 .41 −.15 −.45 40 .51 .01 −.07 0 .31 .12 .07 4 .29 −.26 −.51 56
Benin 2011–12 406 −.065 −.28 .43 .01 .22 6 .43 .00 −.05 0 .13 .12 .87 73 .34 −.03 −.35 21
Burkina Faso 2010 560 −.102 −.29 .44 .03 .32 13 .15 −.07 −.76 25 .06 .08 −.17 0 .29 −.09 −.69 62
Burundi 2016–17 395 −.121 −.31 .46 −.07 −.33 29 .12 −.05 .04 0 .26 −.09 −.36 23 .34 .12 .44 48
Cameroon 2011 434 −.090 −.22 .49 −.03 −.21 14 .38 −.02 .38 0 .44 .03 .48 32 .29 .06 .69 55
Chad 2014–15 712 −.192 −.24 .44 −.10 −.42 42 .20 −.13 −.02 1 .16 −.09 −.39 12 .31 .17 .38 45
Comoros 2012 100 −.255 −.35 .43 −.03 −.17 2 .19 −.10 −.23 5 .33 .06 .33 7 .36 .33 .64 85
Congo 2011–12 250 −.173 −.29 .38 .01 .01 0 .64 .20 .36 90 .71 .03 .24 10 .30 −.01 .02 0
Cote d’Ivoire 2011–12 367 −.122 −.21 .30 −.07 −.66 51 .37 −.07 .16 0 .16 .06 .42 15 .37 .07 .39 34
DRCongo 2013–14 711 −.114 −.30 .47 −.05 −.28 20 .29 −.12 −.55 53 .48 .10 .20 27 .31 .01 −.26 0
Ethiopia 2016 419 −.232 −.30 .33 −.24 −.57 63 .12 .09 .26 4 .10 −.10 −.20 3 .38 .16 .34 30
Gabon 2012 209 −.152 −.38 .42 .03 .18 4 .87 −.10 −.07 11 .66 −.13 −.19 27 .24 .21 .66 58
Gambia 2013 251 −.214 −.36 .45 .04 .10 2 .51 −.09 .15 0 .29 −.16 −.19 10 .33 .34 .67 87
Ghana 2014 208 −.139 −.22 .43 .04 .36 22 .45 −.04 −.09 5 .55 .09 .45 69 .35 .03 .12 4
Guinea 2012 298 −.119 −.24 .46 −.06 −.39 37 .23 .08 −.09 0 .08 −.05 −.59 9 .31 −.11 −.47 54
Kenya 2014 609 −.108 −.30 .46 .02 .15 4 .41 .07 −.06 0 .60 .07 .05 6 .36 −.16 −.54 90
Lesotho 2014 135 −.234 −.21 .45 .00 .00 0 .18 −.02 −.11 1 .70 −.20 −.30 83 .26 .14 .22 16
Liberia 2013 276 −.138 −.23 .46 .03 .18 8 .49 .12 .51 84 .29 .03 .34 8 .34 −.05 .26 0
Malawi 2015–16 586 −.174 −.25 .41 −.12 −.50 54 .14 .19 .70 41 .31 −.02 −.09 1 .34 −.07 −.05 3
Mali 2012–13 437 −.178 −.22 .39 −.06 −.30 18 .14 .16 .45 25 .08 −.24 −.92 47 .26 −.08 −.18 10
Mozambique 2011 441 −.168 −.26 .43 −.11 −.40 41 .29 .03 .41 8 .15 −.08 −.01 0 .35 .12 .55 50
Namibia 2013 136 −.126 −.30 .41 −.07 −.39 30 .45 .02 .27 6 .80 −.09 −.11 21 .29 .09 .61 44
Niger 2012 422 −.142 −.39 .44 −.15 −.40 49 .10 −.16 −.08 2 .04 −.09 −.35 2 .29 .17 .51 46
Nigeria 2013 1465 −.137 −.21 .45 −.08 −.55 72 .31 −.06 −.33 21 .40 .00 −.03 0 .29 −.02 −.31 7
Rwanda 2014–15 227 −.180 −.38 .48 −.22 −.52 81 .14 .14 .47 14 .34 −.02 −.11 1 .34 −.11 −.07 4
Senegal 2010–11 476 −.105 −.26 .38 −.10 −.60 79 .31 .07 .28 21 .11 .00 .26 0 .29 −.03 .03 0
Sierra Leone 2013 562 −.119 −.24 .47 −.08 −.47 63 .30 −.03 −.02 1 .26 −.07 −.42 27 .37 .05 .14 10
Tanzania 2015–16 355 −.238 −.32 .44 −.12 −.30 17 .36 .33 .64 82 .74 −.04 −.02 1 .42 −.14 .27 0
Togo 2013–14 224 −.141 −.21 .41 −.06 −.19 12 .33 .18 .37 55 .26 −.10 −.51 33 .33 −.12 .23 0
Uganda 2016 574 −.141 −.34 .45 −.08 −.30 22 .20 .09 .28 11 .44 −.15 −.47 66 .37 .03 .03 1
Zambia 2013–14 436 −.089 −.29 .42 −.02 −.33 9 .32 .03 .40 15 .49 −.08 −.25 41 .34 .07 .38 35
Zimbabwe 2015 206 −.234 −.22 .46 −.17 −.54 81 .29 −.07 −.29 12 .84 −.09 −.05 7 .28 .02 −.27 0

G: Gini index; mean(y): mean of the predicted (ln) death rates; mean: mean of the dummy variable (coded 0/1), corresponds to the proportion of the factor in the country; b: regression coefficient from a multivariate Poisson model (in bold if significant); %Gini: relative factor’s contribution calculated with the regression-based decomposition of the Gini indexh; A few negative contributions were restricted to 0

Table 4.

Post-neonatal mortality (1–11 months)

Sex of the child Place of residence Mother’s education Household wealth
Female Urban Primary+ Richest
n G mean(y) mean b c %Gini mean b c %Gini mean b c %Gini mean b c %Gini
Angola 2015–16 3069 −.042 −4.48 .50 −.10 −.26 7 .59 −.10 −.34 11 .39 −.04 −.45 4 .33 −.68 −.67 79
Benin 2011–12 2762 −.050 − 4.5 .48 −.27 −.26 14 .41 .11 −.21 0 .18 −.07 −.49 3 .34 −.87 −.66 83
Burkina Faso 2010 3264 −.036 −3.87 .50 −.05 −.24 4 .16 −.07 −.78 6 .07 −.36 −.84 16 .33 −.47 −.67 74
Burundi 2016–17 2684 −.047 −4.26 .48 −.01 −.20 0 .10 .43 −.43 0 .26 −.45 −.63 34 .33 −.67 −.66 65
Cameroon 2011 2603 −.042 −4.07 .49 −.14 −.16 7 .43 −.10 −.39 10 .47 −.49 −.53 71 .33 −.12 −.55 12
Chad 2014–15 3957 −.033 −3.77 .48 −.14 −.38 20 .21 .12 .07 1 .17 −.67 −.83 78 .33 −.01 −.11 0
Comoros 2012 658 −.093 −5 .51 .20 .15 3 .27 −.56 −.58 19 .35 −1.60 −.65 78 .36 .06 −.13 0
Congo 2011–12 2056 −.022 −4.59 .51 −.29 −.47 68 .61 −.21 −.22 28 .72 .09 .01 1 .34 −.04 −.29 4
Cote d’Ivoire 2011–12 1763 −.035 −4.06 .50 −.37 −.39 50 .36 −.07 −.36 7 .19 −.39 −.76 38 .33 −.07 −.37 6
DRCongo 2013–14 4102 −.025 −4.04 .50 .05 .14 3 .30 .26 −.25 0 .50 −.17 −.36 24 .33 −.43 −.63 73
Ethiopia 2016 2120 −.043 −4.47 .51 −.32 −.32 28 .12 −.68 −.83 35 .12 −.72 −.86 37 .35 .02 −.08 0
Gabon 2012 1352 −.029 −4.82 .48 −.33 −.37 42 .84 −.58 −.16 56 .77 −.03 −.12 2 .35 .03 .00 0
Gambia 2013 1826 −.032 −4.89 .52 −.07 −.14 3 .46 .37 .11 12 .33 −.59 −.67 85 .31 .03 .05 0
Ghana 2014 1239 −.028 −4.87 .47 −.01 −.13 1 .45 .28 .11 10 .59 −.51 −.41 89 .32 .02 .03 0
Guinea 2012 1579 −.063 −4.01 .48 −.11 −.22 4 .26 .28 −.51 0 .14 −.78 −.82 30 .32 −.94 −.64 66
Kenya 2014 4028 −.024 −4.5 .50 −.25 −.22 25 .35 .30 .30 29 .61 −.29 −.28 46 .32 −.02 −.04 0
Lesotho 2014 740 −.051 −4.29 .53 −.42 −.31 32 .26 .40 .49 23 .82 −.51 −.11 20 .31 .40 .43 24
Liberia 2013 1712 −.025 −4.21 .47 .21 .35 32 .49 .18 .01 1 .32 −.30 −.62 56 .31 −.17 −.25 12
Malawi 2015–16 3296 −.018 −4.62 .48 .00 .16 0 .14 −.15 −.82 20 .30 .02 −.05 0 .33 −.30 −.67 80
Mali 2012–13 2171 −.039 −4.33 .49 −.01 −.21 1 .20 −.43 −.79 40 .10 −.04 −.74 2 .35 −.44 −.65 58
Mozambique 2011 2474 −.031 −4.03 .49 .10 .20 8 .27 −.14 −.63 20 .18 −.19 −.74 21 .32 −.29 −.67 52
Namibia 2013 1111 −.036 −4.52 .51 .26 .30 23 .45 −.42 −.43 47 .78 −.40 −.16 30 .29 .25 −.14 0
Niger 2012 2694 −.024 −4.14 .48 .10 .37 18 .13 −.65 −.87 73 .06 .20 .10 1 .33 −.05 −.40 7
Nigeria 2013 6797 −.046 −4.07 .51 −.14 −.18 7 .35 −.06 −.47 5 .46 −.44 −.53 58 .33 −.27 −.62 30
Rwanda 2014–15 1632 −.047 −4.93 .50 −.28 −.28 16 .18 .23 −.37 0 .36 −.24 −.38 13 .35 −.77 −.66 71
Senegal 2010–11 2600 −.046 −4.66 .48 .27 .23 14 .37 −.45 −.58 44 .11 −.80 −.87 36 .32 −.08 −.48 6
Sierra Leone 2013 2753 −.019 −3.5 .49 .06 .21 10 .25 .00 −.54 0 .24 −.26 −.76 70 .33 −.08 −.55 20
Tanzania 2015–16 2038 −.006 −4.45 .49 −.02 −.17 4 .27 .02 −.29 0 .67 .07 .15 25 .32 −.11 −.60 71
Togo 2013–14 1433 −.032 −4.35 .48 .01 .17 0 .34 −.07 −.52 9 .31 −.52 −.69 81 .31 −.08 −.56 10
Uganda 2016 3089 −.055 −4.65 .50 −.33 −.26 16 .19 −.10 −.28 2 .42 −.89 −.58 82 .32 .22 −.16 0
Zambia 2013–14 2621 −.020 −4.34 .48 −.13 −.21 16 .35 .35 .30 42 .52 −.19 −.34 40 .34 −.19 −.03 2
Zimbabwe 2015 1205 −.024 −4.3 .50 −.08 −.22 9 .26 −.24 −.73 44 .85 −.18 −.15 22 .29 −.13 −.71 25

G: Gini index; mean(y): mean of the predicted (ln) death rates; mean: mean of the dummy variable (coded 0/1), corresponds to the proportion of the factor in the country; b: regression coefficient from a multivariate Poisson model (in bold if significant); %Gini: relative factor’s contribution calculated with the regression-based decomposition of the Gini indexh; A few negative contributions were restricted to 0

Table 5.

Infant mortality (0–11 months)

Sex of the child Place of residence Mother’s education Household wealth
Female Urban Primary+ Richest
n G mean(y) mean b c %Gini mean b c %Gini mean b c %Gini mean b c %Gini
Angola 2015–16 3514 −.047 −3.61 .49 −.31 −.31 28 .58 −.20 −.32 22 .38 −.06 −.42 6 .32 −.35 −.66 44
Benin 2011–12 3168 −.033 − 3.61 .47 −.21 −.24 19 .41 .12 −.20 0 .17 −.23 −.75 23 .34 −.35 −.63 58
Burkina Faso 2010 3824 −.035 −3.26 .49 −.12 −.27 13 .16 −.01 −.69 1 .07 −.24 −.84 13 .32 −.38 −.68 73
Burundi 2016–17 3079 −.027 − 3.51 .48 −.08 −.20 9 .10 .32 .18 6 .26 −.30 −.69 59 .33 −.18 −.42 26
Cameroon 2011 3037 −.030 −3.31 .49 −.09 −.13 6 .42 −.13 −.47 25 .46 −.23 −.53 55 .32 −.08 −.56 14
Chad 2014–15 4669 −.031 −3.11 .47 −.20 −.39 37 .21 .05 .08 1 .17 −.41 −.83 61 .33 .02 .13 1
Comoros 2012 758 −.051 −3.72 .50 −.12 −.19 6 .26 −.59 −.72 57 .35 −.36 −.49 33 .36 .32 .06 4
Congo 2011–12 2306 −.037 −3.75 .50 −.45 −.50 81 .61 .18 .08 7 .72 .04 .08 2 .33 −.21 −.21 10
Cote d’Ivoire 2011–12 2130 −.059 −3.22 .47 −.64 −.54 85 .36 −.09 −.01 0 .18 −.26 −.45 11 .34 .16 .13 4
DRCongo 2013–14 4813 −.018 −3.34 .50 −.07 −.25 13 .30 .08 −.33 0 .49 −.02 −.25 3 .33 −.26 −.67 84
Ethiopia 2016 2539 −.062 −3.48 .48 −.71 −.52 83 .12 −.18 −.12 1 .11 −.46 −.43 11 .35 .21 .16 6
Gabon 2012 1561 −.041 −3.75 .47 −.26 −.36 30 .84 .03 −.02 0 .75 −.45 −.24 52 .33 −.23 −.36 18
Gambia 2013 2077 −.036 −3.83 .51 −.15 −.20 11 .46 .30 .36 37 .32 −.43 −.33 33 .31 .18 .44 18
Ghana 2014 1447 −.022 −3.62 .47 −.08 −.29 13 .45 −.06 .04 0 .59 −.28 −.32 64 .32 .27 .22 23
Guinea 2012 1877 −.047 −3.23 .47 −.10 −.24 7 .26 .02 −.53 0 .13 −.60 −.87 43 .32 −.38 −.62 49
Kenya 2014 4637 −.025 −3.62 .49 −.21 −.32 36 .36 .29 .50 55 .61 −.17 −.08 9 .33 −.05 .17 0
Lesotho 2014 875 −.055 −3.38 .52 −.39 −.34 37 .25 −.04 −.05 0 .80 −.71 −.18 55 .30 .33 .15 8
Liberia 2013 1988 −.019 −3.47 .47 .12 .30 25 .49 .11 .09 7 .32 −.23 −.60 65 .31 .07 .09 3
Malawi 2015–16 3882 −.018 −3.54 .47 −.22 −.53 83 .14 .12 .43 11 .30 −.01 −.11 0 .33 −.11 −.12 6
Mali 2012–13 2608 −.047 −3.33 .48 −.29 −.29 26 .19 −.08 −.70 7 .10 −.16 −.62 6 .33 −.44 −.66 61
Mozambique 2011 2915 −.020 −3.3 .48 −.14 −.37 37 .28 .00 −.22 0 .17 −.29 −.83 63 .33 .02 −.07 0
Namibia 2013 1247 −.020 −3.73 .50 −.11 −.22 16 .45 −.20 −.38 44 .78 −.21 −.18 40 .29 .16 −.03 0
Niger 2012 3116 −.022 −3.46 .48 −.08 −.42 22 .12 −.52 −.88 74 .06 −.07 −.62 3 .32 .02 −.07 0
Nigeria 2013 8262 −.044 − 3.2 .50 −.24 −.22 19 .34 −.14 −.50 17 .45 −.30 −.53 51 .32 −.10 −.58 14
Rwanda 2014–15 1859 −.032 −3.9 .50 −.32 −.40 52 .17 .02 −.29 0 .36 −.15 −.40 17 .34 −.23 −.49 31
Senegal 2010–11 3076 −.031 −3.54 .47 −.19 −.31 25 .36 −.28 −.64 58 .11 −.10 −.51 5 .31 −.08 −.50 12
Sierra Leone 2013 3315 −.015 −2.93 .49 −.03 −.15 4 .26 .07 .19 7 .25 −.20 −.75 84 .34 .03 .20 4
Tanzania 2015–16 2393 −.034 −3.53 .48 −.20 −.33 27 .28 .36 .72 60 .68 .11 .14 9 .34 .03 .50 4
Togo 2013–14 1657 −.033 −3.47 .47 −.16 −.30 19 .34 −.14 −.07 3 .31 −.43 −.69 78 .32 .20 −.03 0
Uganda 2016 3663 −.039 −3.58 .49 −.31 −.37 41 .19 −.04 −.15 1 .42 −.42 −.45 57 .33 .26 .02 1
Zambia 2013–14 3057 −.021 −3.51 .47 −.22 −.53 73 .34 .00 .02 0 .51 −.15 −.26 27 .34 .06 .00 0
Zimbabwe 2015 1411 −.024 −3.36 .49 −.19 −.43 36 .27 .35 −.34 0 .85 −.14 −.09 10 .29 −.43 −.49 54

G: Gini index; mean(y): mean of the predicted (ln) death rates; mean: mean of the dummy variable (coded 0/1), corresponds to the proportion of the factor in the country; b: regression coefficient from a multivariate Poisson model (in bold if significant); %Gini: relative factor’s contribution calculated with the regression-based decomposition of the Gini indexh; A few negative contributions were restricted to 0

Table 6.

Child mortality (11–59 months)

Sex of the child Place of residence Mother’s education Household wealth
Female Urban Primary+ Richest
n G mean(y) mean b c %Gini mean b c %Gini mean b c %Gini mean b c %Gini
Angola 2015–16 10,805 −.025 −7.94 .51 −.01 −.11 0 .61 .14 −.12 0 .37 −.70 −.63 79 .34 −.22 −.59 21
Benin 2011–12 10,239 −.035 − 7.79 .49 −.10 −.17 3 .39 −.60 −.58 50 .14 −.63 −.79 26 .33 −.30 −.61 22
Burkina Faso 2010 11,215 −.026 −6.86 .49 −.11 −.22 7 .17 −.45 −.81 35 .07 −.64 −.90 24 .34 −.30 −.63 35
Burundi 2016–17 10,110 −.022 −7.63 .50 −.10 −.19 6 .09 −1.35 −.91 67 .25 −.16 −.66 16 .33 −.10 −.58 12
Cameroon 2011 8695 −.052 −6.95 .51 .21 .17 5 .42 −.18 −.41 9 .48 −.85 −.51 58 .34 −.51 −.60 28
Chad 2014–15 13,947 −.012 −6.78 .49 −.18 −.36 42 .19 .26 .49 32 .14 .11 .37 7 .33 −.26 −.17 19
Comoros 2012 2380 −.037 −8.5 .49 .01 .13 0 .27 −.39 −.48 16 .35 −.79 −.62 54 .33 −.50 −.56 29
Congo 2011–12 7022 −.021 −7.55 .51 .24 .28 22 .60 .38 .07 10 .70 −.48 −.27 58 .33 −.21 −.22 10
Cote d’Ivoire 2011–12 5645 −.028 −7.22 .51 −.41 −.35 36 .38 −.17 −.32 10 .18 −.74 −.82 54 .33 .03 −.24 0
DRCongo 2013–14 13,901 −.018 −7.18 .50 −.05 −.13 3 .31 .07 −.38 0 .47 −.41 −.53 76 .33 −.16 −.54 21
Ethiopia 2016 8099 −.030 −8.05 .48 .01 .25 1 .11 −2.03 −.89 81 .08 −.42 −.87 13 .33 .22 .20 6
Gabon 2012 4502 −.037 −7.65 .48 −.77 −.50 66 .84 −.52 −.04 6 .74 −.21 −.06 4 .33 .59 .35 24
Gambia 2013 6009 −.034 −8.29 .49 .23 .17 7 .48 .23 .13 5 .32 −1.15 −.68 87 .34 .14 .06 1
Ghana 2014 4435 −.065 −8.75 .48 −.35 −.16 5 .45 −.25 −.34 7 .58 −1.77 −.42 76 .34 −.38 −.56 13
Guinea 2012 5161 −.035 −7.02 .49 −.11 −.24 6 .26 −.39 −.73 31 .12 −.10 −.60 3 .34 −.67 −.66 61
Kenya 2014 16,323 −.021 −8.33 .49 .15 .12 5 .36 .46 −.11 0 .59 −.28 −.30 26 .34 −.64 −.62 69
Lesotho 2014 2263 −.033 −7.72 .50 .96 .50 94 .30 .10 .16 2 .78 −.11 −.12 4 .35 .01 .12 0
Liberia 2013 5618 −.003 −7.2 .49 −.06 −.50 68 .50 .03 .25 18 .32 .00 .05 0 .34 .03 .32 14
Malawi 2015–16 13,401 −.017 −8.09 .51 .14 .25 13 .13 −.46 −.86 38 .29 −.10 −.43 9 .33 −.26 −.65 41
Mali 2012–13 7717 −.043 −7.47 .49 −.38 −.26 15 .19 −.12 −.68 5 .09 −1.50 −.91 40 .33 −.60 −.64 40
Mozambique 2011 8187 −.007 −7.44 .50 −.07 −.29 20 .28 −.04 −.52 11 .16 −.19 −.84 51 .34 −.05 −.51 18
Namibia 2013 3798 −.022 −8.1 .52 .35 .28 29 .50 .58 .29 47 .77 −.21 −.09 9 .35 −.38 −.20 15
Niger 2012 9420 −.021 −6.7 .50 .04 .23 4 .13 −.99 −.87 82 .05 −.35 −.85 12 .34 .10 .12 3
Nigeria 2013 23,219 −.048 −7.05 .49 −.05 −.13 1 .35 −.39 −.55 23 .45 −.48 −.51 33 .34 −.66 −.66 44
Rwanda 2014–15 5995 −.037 −8.34 .49 −.07 −.17 2 .17 .02 −.35 0 .33 −1.26 −.67 90 .33 −.14 −.53 8
Senegal 2010–11 9250 −.187 −9.81 .49 −.06 −.22 0 .39 −1.03 −.56 12 .12 −15.5 −.88 87 .34 .02 −.31 0
Sierra Leone 2013 8622 −.017 −6.83 .51 −.24 −.33 34 .25 −.01 −.12 0 .20 −.47 −.80 64 .33 .15 .04 2
Tanzania 2015–16 7838 −.024 −7.8 .50 −.01 −.13 0 .27 .83 .33 40 .65 −.48 −.30 51 .33 −.49 −.11 10
Togo 2013–14 5320 −.035 −7.46 .50 −.01 −.14 0 .36 .03 −.47 0 .30 −.54 −.56 34 .34 −.78 −.66 65
Uganda 2016 11,858 −.036 −8.03 .50 −.24 −.15 6 .22 −.32 −.64 15 .41 −.39 −.49 27 .34 −.67 −.66 51
Zambia 2013–14 10,389 −.019 −7.64 .50 −.04 −.13 2 .34 .23 −.33 0 .49 −.38 −.49 54 .33 −.39 −.59 44
Zimbabwe 2015 4721 −.024 −7.99 .51 .00 .16 0 .33 .72 −.52 0 .86 −.42 −.12 14 .35 −1.22 −.65 86

Senegal: this analysis is not reliable (aberrant value for the regression coefficient of mother’s education) because no death occurred in the sub-group of women with an educational level of at least primary

G: Gini index; mean(y): mean of the predicted (ln) death rates; mean: mean of the dummy variable (coded 0/1), corresponds to the proportion of the factor in the country; b: regression coefficient from a multivariate Poisson model (in bold if significant); %Gini: relative factor’s contribution calculated with the regression-based decomposition of the Gini indexh; A few negative contributions were restricted to 0

Fig. 3.

Fig. 3

Classification of the 32 countries according to the main contributors to the variability in U5M. A factor was defined as a main contributor if its contribution to the variability in U5M exceeded 25% according to the regression-based decomposition of the Gini index (Tables)

Authors’ contributions

CVM, AA, AB, BM, HVO and NS contributed to the conceptualization and methodology; CVM and BM contributed to the formal analysis; CVM contributed to the original draft; NS and HVO contributed to the supervision, and all authors contributed to the writing - review and editing of the final manuscript. All authors have read and approved the manuscript.

Funding

The work received no specific funding.

Availability of data and materials

The data that support the findings of this study are available from the Measure DHS program (https://dhsprogram.com/) but restrictions apply to the availability of these data, which were used under license for the current study, and so are not publicly available. Data are however available from the authors upon reasonable request and with permission of the Measure DHS program.

Ethics approval and consent to participate

The study was based on publicly available data from the DHS program (permission was granted to download data). Ethical approval was the responsibility of the institutions which collected the data.

Consent for publication

Not Applicable.

Competing interests

The authors declare that they have no competing interests.

Footnotes

Publisher’s Note

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Contributor Information

Carine Van Malderen, Email: carine.vanmalderen@uclouvain.be.

Agbessi Amouzou, Email: aamouzo1@jhu.edu.

Aluisio J. D. Barros, Email: abarros.epi@gmail.com

Bruno Masquelier, Email: bruno.masquelier@uclouvain.be.

Herman Van Oyen, Email: Herman.VanOyen@sciensano.be.

Niko Speybroeck, Email: niko.speybroeck@uclouvain.be.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The data that support the findings of this study are available from the Measure DHS program (https://dhsprogram.com/) but restrictions apply to the availability of these data, which were used under license for the current study, and so are not publicly available. Data are however available from the authors upon reasonable request and with permission of the Measure DHS program.


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