Skip to main content
NCBI home page
Springer logoLink to Springer
. 2020 Feb 6;24(4):483–502. doi: 10.1007/s10995-019-02865-7

Factors Associated with Anemia Status Among Children Aged 6–59 months in Ghana, 2003–2014

Luke M Shenton 1,, Andrew D Jones 2, Mark L Wilson 1
PMCID: PMC7078144  PMID: 32030533

Abstract

Background

In 2008, 78% of Ghanaian children under 5 years old were anemic versus 48% of children globally. In this study, we identified proximal and distal determinants of severe–moderate anemia and mild anemia related to socioeconomic status, nutrition, and health access.

Methods

Using data from the 2003, 2008, and 2014 Ghana Demographic and Health Surveys (GDHS), the odds of severe–moderate anemia and mild anemia compared to no anemia, in relation to various hypothesized risk factors, were assessed using a multivariable, multinomial logistic regression, which accounted for survey design.

Results

From among 7739 households sampled, severe–moderate anemia was found in approximately 52%, 56%, and 40% of children during 2003, 2008, and 2014, respectively. The proportion of children diagnosed as not anemic was 26% in 2003, 22% in 2008, and 33% in 2014. There are large disparities in anemia prevalence among regions and between urban and rural areas. In 2014, children who were younger (aged 6–24 months), had a recent fever, were from poorer families, and whose mothers were less educated had greater odds of being severely–moderately anemic. These results remained significant when controlling for other risk factors. Predictors of anemia in Ghana remained relatively consistent among the three time periods when the GDHS was administered.

Conclusions

The prevalence of anemia in Ghana among children aged 6–59 months has remained unacceptably high. To reduce anemia in these children, the Ghanaian government should concentrate on educating women through both the traditional school system and antenatal care visits.

Keywords: Anemia disease risk, West Africa, Childhood health disparities, Demographic and health survey (DHS), Maternal and child nutrition

Significance

What is Already Known on This Subject? Existing literature using GDHS data shows there are child, household, and sociocultural factors associated with anemia in Ghana. What This Study Adds? This is the first article, that we know of, to assess predictors of anemia in Ghana over three rounds of GDHS data. Younger child age, fever in the last 2 weeks, lower household wealth, less maternal education, and maternal anemia were significantly associated with severe–moderate anemia among children in 2014. The predictors remained relatively constant over time, with similar risk factors being seen in 2003 and 2008. These results can inform policy makers in Ghana.

Introduction

Globally, undernutrition is one of the largest contributors to child mortality, causing an estimated 45% of total deaths of children younger than five years (Black et al. 2013). Undernutrition encompasses a broad range of public health problems, including deficiencies of micronutrients, especially iron (WHO 2008a), that often contribute to anemia. Anemia is of particular concern in children because it can cause deficits in cognitive and behavioral development and function (Beard and Connor 2003; McCann and Ames 2007). Understanding the complex etiologies of various types of anemia is of particular importance, due to the high prevalence of anemia in many parts of the world. One 2011 estimate indicated that 43% of children under 5 years old had anemia worldwide, with prevalence as high as 71% in parts of central and western Africa (Stevens et al. 2013).

Because of its large contribution to morbidity and mortality, anemia remains an important public health problem, especially in sub-Saharan Africa. In 2008, 78% of Ghanaian under-five children were anemic, with 56% of these children suffering from severe or moderate anemia (Ewusie et al. 2014). Due to this high prevalence, improved understanding of associated factors is needed to better tailor interventions for reducing the burden of anemia in Ghana.

On a biological level, anemia is usually caused by decreased erythrocyte production or increased erythrocyte loss (Camaschella 2015). In addition to such biological causes, there are many complex, upstream environmental, behavioral and social factors that contribute to risk for anemia, especially in children (Balarajan et al. 2011; Siekmans et al. 2014). These factors are often divided into three major categories. First, there are immediate causes, which include inadequate nutrient and absorption (i.e. nutrient supplementation) and exposure to infectious disease (i.e. fever, malaria, intestinal parasites) (Mueller et al. 2017; Paganini and Zimmermann 2017). Secondly, there are underlying causes at the household/family level, such as access to water and sanitation, availability of health services, childcare practice (e.g. breastfeeding) access to diverse food sources, use of insecticide-treated bednets (ITNs), and knowledge about anemia prevention (Larsen et al. 2017). Lastly, the most distal causes are related to the larger sociocultural context, such as education, wealth, and cultural norms and behavior (Ngnie-Teta et al. 2009). Figure 1 provides a graphical depiction of these hypothesized relationships and more information can be found in the methods section. An updated analysis of the relationship between such risk factors and anemia in a nationally representative sample of Ghanaian children is needed given that most existing studies are limited in some way. Investigations into anemia in Ghana generally have involved small sample sizes, and only evaluated risk within small areas (Egbi et al. 2014; Klinkenberg et al. 2006; VanBuskirk et al. 2014). Other studies that used a nationally representative sample are limited by only considering prevalence estimates for anemia or a sample subset of potential predictors (Ewusie et al. 2014; Saaka and Galaa 2017).

Fig. 1.

Fig. 1

Open in a new tab

Theoretical framework for predictors of anemia

The objective of our study, therefore, was to determine the prevalence and predictors of anemia among Ghanaian children aged 6–59 months using nationally representative samples from the Ghana Demographic and Health Survey (GDHS), covering 2003, 2008, and 2014. Thereby, we undertook a more in-depth analyses of anemia risk that also evaluated whether and how there may have been changes in anemia prevalence and correlates over time. We hypothesized many previously identified predictors of childhood anemia, such as malaria and diarrheal disease, would be associated with anemia, as would maternal factors including education and maternal autonomy (Balarajan et al. 2011; Siekmans et al. 2014). In addition, we hypothesized there would be decreasing anemia prevalence over time commensurate with improvements in equity across various socioeconomic and demographic groups.

Methods

Study Population

This study analyzed Ghana DHS (GDHS) data for 2003, 2008, and 2014. All three surveys and supporting documentation are available from reports published on DHS Program website (Ghana Statistical Service, Ghana Health Service and ICF International 2009, 2015; Ghana Statistical Service, Noguchi Memorial Institute for Medical Research and ORC Macro 2004; United States Agency for International Development 2017). The three surveys used different phases of the DHS; phase IV in 2003, phase V in 2008, and phase VII in 2014. However, the sampling scheme was virtually identical across these phases, so only the 2014 methods are explained here. The 2014 GDHS used the Ghana 2010 Population and Housing Census as the sampling frame, which consists of 37,641 enumeration areas (EAs) that cover the entire country. The 2008 and 2003 GDHS surveys used the 2000 Population and Housing Census; all regions of Ghana showed population growth between the 2000 and the 2010 census (Ghana Statistical Service 2012). EAs are geographic areas that serve as counting units for the Ghanaian governmental census and contained an average of 145 households in the 2010 census.

The GDHS followed a stratified, two-stage, sample design, which allows estimation of key indicators at the national level, in both urban and rural areas, and in each of Ghana’s ten regions. In the first stage, clusters were selected, which consisted of EAs; 216 clusters from urban areas and 211 from rural areas, for a total of 427 clusters.

In the second stage, approximately 30 households were selected from each cluster to yield a total sample size of 12,831 households. The sample design selected an approximately equal sample size in each region; therefore, the sample is not self-weighting at the national level, so weights were calculated such that results are also representative at the national level.

Information about the household, reproductive health, maternal care, childhood immunization, and childcare was collected via in-person interviews with women aged 15–49 years. The population used for analysis was the children from each household aged 6–59 months for whom anemia data are available.

Derived Variables

Our outcome of interest was anemia status in 6–59 month old children, which we grouped into three levels based on Hb concentration: severe–moderate anemia (< 100 g/L), mild anemia (100–109 g/L), or non-anemic (≥ 110 g/L) (WHO 2011). We combined severe and moderate anemia into one category because a very small number of children had severe anemia giving the category very low statistical power for analysis. Blood samples were taken via a finger prick (or heel prick for children age 6–11 months) and collected in a microcuvette. A HemoCue analyzer was used to measure Hb concentration. Hb levels were adjusted for altitude.

The explanatory variables we analyzed were based on various conceptual models of anemia determinants, plus variables found to be important predictors of anemia in previous studies (Balarajan et al. 2011; Saaka and Galaa 2017; Siekmans et al. 2014). These explanatory variables were related to sociodemographic characteristics and health access, and were examined for any relationship with the children's anemia status.

Immediate causes of anemia, which included recent diarrhea (last 2 weeks), recent fever (last 2 weeks), and recent treatment for parasitic worms (last 6 months), were dichotomized into yes or no answers. Underlying causes comprised most variables, and included age of the child’s mother, child’s sex, iron supplementation, childcare practice (e.g. breastfeeding), dietary diversity, environmental health (e.g. access to a toilet facility and clean water), access to ITNs, the number of children in the household, and health insurance coverage. Dietary diversity was characterized by the number of different food groups the child consumed in the previous 24 h. We reclassified the GDHS food data into seven distinct food groups: (i) grains, roots and tubers; (ii) legumes and nuts; (iii) dairy products; (iv) flesh foods (meats/fish/poultry); (v) eggs; (vi) vitamin A-rich fruits and vegetables; and (vii) other fruits and vegetables. These food groups underlie the WHO Minimum Dietary Diversity (MDD) indicator for children—an indicator validated against the micronutrient adequacy of child diets (Working Group on Infant and Young Child Feeding Indicators 2006; WHO 2008). The dietary diversity score, which ranged from zero to seven food groups, was then dichotomized to create the MDD that was met by consuming four or more food groups.

The more "distal" hypothesized causes of anemia included household wealth, maternal education, religion, ethnicity, and maternal autonomy. The household wealth index was derived by grouping survey participants into quintiles based on a standardized asset-based score. Measures of maternal autonomy included number of other wives, maternal decision-making autonomy, and maternal attitudes towards being beaten. For decision making autonomy, we classified mothers as having none, some, or full decision-making autonomy based on their answers to questions about decision making behaviors in their households. DHS surveyors asked mothers about who in their household makes decisions related to their own health-care, large household purchases, and visits to relatives. Mothers could answer that they alone make the decision, they jointly make the decision with their husband, their husband alone makes the decision, or someone else makes the decisions. If the mother played a role in all decisions she had full decision-making autonomy, if she played a role in making some decisions she had partial decision-making autonomy, and if she did not play a role in making decisions she had no decision-making autonomy. For attitudes towards being beaten, we dichotomized mothers’ responses to questions about wife beating into yes (beating by their husband is justifiable) or no (not justifiable). DHS surveyors asked mothers if they thought being beaten by their husband was justifiable in five scenarios: they leave the house without telling their husband, they neglect the children, they argue with their husband, they refuse to have sex, and they burn the food.

Statistical Analysis

The distribution of factors are presented using descriptive statistics, and their unadjusted relationship with severe–moderate and mild anemia were assessed through a Rao-Scott chi-square test. A multivariable, multinomial, logistic regression model was developed to determine the associations between independent factors and anemia status. The regression models were built by considering previous studies, and included all factors other than dietary diversity and breastfeeding. Dietary diversity was not included due to a small overall sample size (N = 1373) and breastfeeding was excluded due to high collinearity with child’s age. For all other variables, observations with missing data were removed from the multivariable model. However, the removed observations accounted for only a small proportion of the total number of observations. Ethnicity, originally a nine-category variable, was collapsed into six categories, while maternal education was collapsed from six to three categories, in both cases due to small cell size, which was defined as under 150 observations. The 2003 regression model differed slightly from those of 2008 and 2014 due to missing variables such as iron supplementation, drugs for parasites, and health insurance status. All descriptive, bivariate, and multivariable analyses were conducted using appropriate clustering, stratification, and weighting statements to account for the complex sample design. The regression model generated odds ratios (OR) and 95% confidence intervals (CI). Variance was estimated through the Taylor series linearization method. Significance was assessed at an α level of 0.05, with all analyses being done in SAS version 9.4 (SAS Institute, Cary, NC, USA).

Ethical Approval

This study was exempt from ethical approval because it was limited to publicly available datasets that contained no personally identifiable information. All participants provided informed consent to the GDHS interviewers before being enrolled into the study.

Results

Study Population

The 2003, 2008, and 2014 GDHS datasets provided information on 3183, 2168, and 2388 children aged 6–59 who had Hb measurements taken, respectively. The sociodemographic characteristics of these children are summarized in Table 1. In 2014, ~ 48% of children had slept under a mosquito net the previous night; a significant increase from 2003 when only 15% had. Around 12% of children had diarrhea in the previous 2 weeks, while 15% had a fever in the last 2 weeks, an improvement over previous years. A quarter of children in 2014 had no toilet facility compared to one-third in 2003 and 17% had access to flush toilet in 2014 compared to 7% in 2003. In 2014, 29% of mothers (11% less than in 2003) had completed no education, while only 10% of mothers had completed secondary education or higher. Approximately 58% of mothers had full decision-making autonomy in the household, while 7% had none; in contrast to the 26% and 40% of mothers with no and full decision-making autonomy, respectively in 2003. Across all survey years, the majority (75%) of children belonged to Christian households and were members of the Akan ethnic group (48%).

Table 1.

Sociodemographic profile of children 6–59 months

Characteristics 2003 2008 2014
n Weighted percentages (95% confidence intervals) n Weighted percentages (95% confidence intervals) n Weighted percentages (95% confidence intervals)
Anemia type 3183 2168 2388
 Severe–moderate 52.11 (49.95, 54.27) 55.81 (52.99, 58.63) 39.80 (36.78, 42.83)
 Mild 22.02 (20.39, 23.64) 22.61 (20.54, 24.67) 27.00 (24.89, 29.11)
 None 25.87 (23.98, 27.76) 21.58 (19.34, 23.83) 33.20 (30.18, 36.22)
Region 3183 2168 2388
 Western 10.13 (8.13, 12.12) 9.43 (7.48, 11.38) 10.59 (8.69, 12.50)
 Central 8.86 (6.55, 11.16) 9.01 (7.01, 11.00) 11.69 (7.20, 16.18)
 Greater Accra 10.73 (8.92, 12.54) 11.92 (9.83, 14.02) 15.62 (12.51, 18.73)
 Volta 8.51 (7.47, 9.56) 8.74 (6.81, 10.68) 7.34 (5.67, 9.00)
 Eastern 9.62 (8.22, 11.03) 8.62 (7.28, 9.96) 8.65 (7.10, 10.20)
 Ashanti 17.71 (15.87, 19.55) 19.21 (16.60, 21.81) 17.36 (14.65, 20.06)
 Brong Ahafo 11.25 (9.93, 12.56) 10.44 (8.71, 12.17) 9.60 (7.69, 11.51)
 Northern 13.78 (11.97, 15.60) 14.97 (12.50, 17.43) 12.52 (9.63, 15.40)
 Upper east 3.09 (2.43, 3.76) 4.85 (3.73, 5.98) 4.10 (2.76, 5.44)
 Upper west 6.32 (5.06, 7.58) 2.81 (2.22, 3.40) 2.53 (1.85, 3.21)
Urbanicity 3183 2168 2388
 Urban 32.14 (29.78, 34.50) 36.95 (33.90, 40.00) 45.81 (41.73, 49.88)
 Rural 67.86 (65.50, 70.22) 63.05 (60.00, 66.10) 54.19 (50.12, 58.27)
Child’s age (months) 3183 2168 2388
 6–11 21.56 (20.30, 22.81) 11.40 (9.83, 12.97) 11.28 (9.50, 13.06)
 12–23 21.68 (20.00, 23.37) 23.82 (22.06, 25.59) 24.41 (22.57, 26.24)
 24–35 19.45 (17.94, 20.96) 21.37 (19.35, 23.39) 22.59 (20.52, 24.65)
 36–47 20.16 (18.74, 21.58) 20.66 (18.90, 22.42) 21.48 (19.53, 23.42)
 48–59 17.15 (15.81, 18.49) 22.75 (20.87, 24.62) 20.25 (18.35, 22.14)
Sex 3183 2168 2388
 Male 50.55 (48.73, 52.36) 51.45 (49.11, 53.80) 52.95 (50.59, 55.31)
 Female 49.45 (47.64, 51.27) 48.55 (46.20, 50.89) 47.05 (44.69, 49.41)
Child slept under net previous night 3183 2168 2388
 No 84.65 (82.56, 86.73) 56.05 (52.97, 59.14) 52.22 (48.84, 55.60)
 Yes 15.35 (13.27, 17.44) 43.95 (40.86, 47.04) 47.78 (44.40, 51.16)
Had diarrhea recently 3172 2163 2388
 No 84.11 (82.63, 85.60) 77.59 (75.28, 79.81) 87.39 (85.46, 89.31)
 Yes, last 2 weeks 15.89 (14.40, 17.37) 22.41 (20.19, 24.62) 12.62 (10.69, 14.54)
Had fever recently 3157 2162 2388
 No 77.99 (76.31, 79.68) 77.51 (75.28, 79.74) 84.72 (82.48, 86.95)
 Yes, last 2 weeks 22.01 (20.32, 23.69) 22.49 (20.26, 24.72) 15.28 (13.05, 17.52)
Iron supplementation 2156 2379
 No 71.94 (69.40, 74.49) 76.77 (73.96, 79.59)
 Yes 28.06 (25.51, 30.60) 23.23 (20.41, 26.04)
Drugs for parasites in last 6 mo 2151 2383
 No 57.23 (54.55, 59.91) 62.17 (59.18, 65.15)
 Yes 42.77 (40.09, 45.45) 37.83 (34.85, 40.82)
Breastfeeding 3148 2159 2387
 Previously breastfed 56.58 (55.00, 58.16) 67.40 (65.37, 69.42) 68.00 (65.89, 70.10)
 Never breastfed 0.37 (0.15, 0.58) 1.57 (0.91, 2.23) 1.03 (0.52, 1.54)
 Still breastfeeding 43.06 (41.47, 44.64) 31.04 (29.06, 33.01) 30.98 (28.84, 33.11)
 Dietary diversity (no. of food groups) 1684 1373
 < 4 64.75 (61.52, 67.98) 80.65 (77.41, 83.89)
 ≥ 4 35.25 (32.02, 38.48) 19.35 (16.11, 22.59)
Water source 3155 2156 2343
 Piped water 28.32 (24.85, 31.80) 33.76 (29.59, 37.93) 27.72 (24.17, 31.26)
 Open well water 13.85 (11.29, 16.41) 36.84 (32.69, 40.99) 30.83 (26.35, 35.31)
 Protected well water 31.42 (27.75, 35.10) 7.62 (5.12, 10.12) 10.10 (7.49, 12.70)
 Surface water 25.63 (21.67, 29.58) 15.54 (11.89, 19.19) 10.70 (7.80, 13.61)
 Bottled/sachet water 0.78 (0.32, 1.23) 6.24 (4.46, 8.01) 20.65 (17.47, 23.84)
Toilet 3156 2343
 Flush toilet 6.72 (4.85, 8.59) 8.48 (6.57, 10.40) 17.72 (14.67, 20.77)
 Pit toilet latrine 62.05 (58.72, 65.37) 62.68 (58.75, 66.61) 56.84 (52.72, 60.95)
 No facility 31.23 (28.10, 34.37) 28.69 (25.13, 32.54) 25.44 (21.64, 29.25)
Household wealth quintile 3183 2168 2388
 Poorest 26.50 (23.72, 29.29) 26.10 (22.61, 29.59) 22.82 (19.39, 26.25)
 Poorer 22.51 (20.00, 25.01) 23.35 (20.55, 26.15) 20.47 (18.02, 22.92)
 Middle 20.14 (17.71, 22.58) 17.63 (15.18, 20.08) 20.01 (17.18, 22.85)
 Richer 16.50 (14.39, 18.60) 19.02 (16.55, 21.49) 18.34 (15.24, 21.44)
 Richest 14.35 (12.05, 16.65) 13.90 (11.66, 16.13) 18.35 (15.09, 21.62)
Mother’s age (years) 3183 2168 2388
 15–19 3.54 (2.89, 4.18) 3.45 (2.56, 4.34) 2.74 (1.75, 3.73)
 20–24 18.14 (16.28, 20.00) 18.62 (16.46, 20.78) 15.89 (13.88, 17.89)
 25–29 26.38 (24.32, 28.44) 27.94 (25.31, 30.57) 24.31 (21.48, 27.15)
 30–34 22.18 (20.25, 24.12) 20.38 (18.20, 22.55) 25.90 (23.25, 28.54)
 35–39 17.35 (15.52, 19.18) 18.05 (15.98, 20.12) 19.65 (17.20, 22.11)
 ≥ 40 12.42 (10.91, 13.92) 11.56 (9.94, 13.18) 11.21 (9.78, 13.24)
Maternal education 3183 2168 2388
 No education 40.30 (37.45, 43.14) 33.18 (30.08, 36.28) 28.88 (25.23, 32.53)
 Incomplete primary 16.53 (14.72, 18.34) 18.34 (16.09, 20.58) 13.85 (11.74, 15.97)
 Complete primary 6.64 (5.45, 7.82) 6.28 (5.01, 7.55) 5.89 (4.59, 7.19)
 Incomplete secondary 32.66 (30.44, 34.89) 35.23 (32.25, 38.20) 41.15 (37.48, 44.82)
 Complete secondary 2.78 (1.90, 3.67) 4.63 (3.42, 5.85) 6.99 (5.40, 8.59)
 Higher 1.09 (0.59, 1.60) 2.35 (1.48, 3.22) 3.24 (2.02, 4.45)
Health insurance coverage 2166 2388
 No 62.41 (59.22, 65.61) 33.25 (30.18, 36.33)
 Yes 37.59 (34.39, 40.78) 66.75 (63.67, 69.82)
Maternal anemia type 3147 2150 2370
 Severe–moderate 9.38 (8.07, 10.69) 20.28 (17.88, 22.67) 9.81 (8.18, 11.44)
 Mild 37.90 (35.70, 40.10) 41.31 (38.54, 44.08) 34.06 (31.33, 36.80)
 Not anemic 52.72 (50.27, 55.17) 38.41 (35.37, 41.45) 56.13 (53.06, 59.19)
Number of children in household 3183 2168 2388
 1–2 38.72 (36.36, 41.08) 40.66 (37.65, 43.66) 42.94 (40.05, 45.82)
 3 43.95 (41.60, 46.30) 41.81 (38.53, 45.09) 42.11 (39.04, 45.18)
 ≥ 4 17.33 (15.25, 19.41) 17.53 (14.62, 20.45) 14.95 (12.11, 17.80)
Number of other wives 3182 1965 2094
 0 71.02 (68.71, 73.33) 81.15 (78.34, 83.95) 84.96 (82.41, 87.51)
 1 28.98 (26.67, 31.29) 18.86 (16.05, 21.66) 15.04 (12.49, 17.59)
Maternal decision-making autonomy 3134 1965 2108
 No autonomy 25.52 (22.94, 28.10) 10.27 (8.03, 12.52) 7.71 (5.61, 9.81)
 Partial autonomy 34.95 (32.20, 37.70) 42.07 (38.84, 45.30) 34.70 (31.08, 38.33)
 Full autonomy 39.53 (36.66, 42.40) 47.66 (43.86, 51.45) 57.59 (53.88, 61.29)
Maternal attitudes that justify beating 3182 2168 2388
 No 45.63 (42.93, 48.33) 40.98 (37.73, 44.23) 66.42 (62.48, 70.36)
 Yes 54.37 (51.67, 57.07) 59.02 (55.77, 62.27) 33.58 (29.64, 37.52)
Religion 3181 2163 2388
 Christian 71.37 (68.68, 74.06) 71.29 (67.75, 74.84) 74.90 (71.13, 78.67)
 Islam 17.83 (15.21, 20.45) 17.77 (14.08, 21.46) 18.20 (14.37, 22.03)
 Traditional 4.29 (3.15, 5.43) 6.83 (4.51, 9.14) 3.39 (1.61, 5.18)
 No religion 6.51 (4.94, 8.09) 4.11 (2.98, 5.24) 3.51 (2.47, 4.54)
Ethnicity 3181 2166 2388
 Akan 46.27 (42.98, 49.56) 47.10 (43.31, 50.89) 48.07 (43.30, 52.84)
 Ga/Dangme 7.13 (5.35, 8.91) 4.59 (3.04, 6.15) 5.67 (3.89, 7.44)
 Ewe 12.67 (10.89, 14.45) 12.43 (9.92, 14.94) 13.08 (10.51, 15.64)
 Mole-Dagbani 16.67 (14.12, 19.21) 20.19 (16.64, 23.73) 17.02 (1337, 20.68)
 Gurma 4.36 (2.54, 6.18) 5.49 (3.33, 7.65) 8.31 (5.22, 11.39)
 Other 12.90 (10.62, 15.19) 10.20 (7.94, 12.47) 7.85 (5.94, 9.77)
Open in a new tab

Ghana Demographic and Health Survey, 2003–2014

Prevalence and Distribution of Anemia

Severe–moderate anemia was found in 52%, 56%, and 40% of children during 2003, 2008, and 2014, respectively. The proportion of children diagnosed as not anemic was 26% in 2003, 22% in 2008, and 33% in 2014 (Tables 2, 3, 4). As compared to 2003, the prevalence of severe–moderate anemia increased slightly (4%) in 2008, but had substantially decreased (12%) by 2014. In 2014, 48% of children in rural areas had severe–moderate anemia compared to 30% in urban areas. While this significant disparity persisted through 2014, both urban and rural areas had a 10% drop in severe–moderate anemia as compared with 2003. severe–moderate anemia prevalence also differed by province across all survey years, ranging from 29% in Ashanti region (2014) to 62% in the Northern region (2014).

Table 2.

Rao-Scott chi-square bivariate analysis of anemia type by sociodemographic factors for children 6–59 months from the 2014 Ghana Demographic and Health Survey (n = 2388)

Severe–moderate anemia (weighted %) Mild anemia (weighted %) Non-anemic (weighted %) P-value
Region < 0.0001
 Western 37.94 29.78 32.28
 Central 46.70 26.66 26.65
 Greater Accra 29.55 28.81 41.64
 Volta 43.45 27.25 29.30
 Eastern 38.52 28.00 33.48
 Ashanti 29.32 24.79 45.89
 Brong Ahafo 34.02 29.52 36.46
 Northern 61.57 22.93 15.50
 Upper east 43.95 30.61 25.44
 Upper west 52.28 21.36 26.36
 Urbanicity < 0.0001
 Urban 30.48 28.99 40.54
 Rural 47.69 25.31 27.00
Child’s age (months) < 0.0001
 6–11 52.16 26.26 21.58
 12–23 52.25 24.61 23.14
 24–35 35.20 30.86 33.94
 36–47 33.77 27.44 38.79
 48–59 29.45 25.50 45.05
Sex 0.8514
 Male 39.21 27.50 33.30
 Female 40.47 26.44 33.09
Child slept under net previous night 0.0404
 No 36.70 27.97 35.33
 Yes 43.20 25.93 30.87
Had diarrhea recently 0.0158
 No 38.48 27.40 34.12
 Yes, last 2 weeks 49.00 24.19 26.81
Had fever recently < 0.0001
 No 36.85 27.75 35.40
 Yes, last 2 weeks 56.15 22.84 21.02
Iron supplementation 0.0015
 No 42.09 25.23 32.67
 Yes 34.75 32.91 34.75
Drugs for parasites in last 6 mo < 0.0001
 No 44.10 26.18 29.73
 Yes 32.69 28.36 38.95
Breastfeeding < 0.0001
 Ever breastfed 32.97 28.38 38.65
 Never breastfed 43.89 17.84 38.26
 Still breastfeeding 54.74 24.14 21.11
Dietary diversity (no. of food groups) 0.2195
 < 4 48.75 25.11 26.14
 ≥ 4 40.72 28.44 30.84
Water source < 0.0001
 Piped water 35.44 27.07 37.49
 Tube well water 49.98 23.38 26.64
 Dug well 50.21 23.85 25.94
 Surface water 52.08 25.79 22.13
 Bottled/sachet water 20.74 32.79 46.46
Toilet < 0.0001
 Flush toilet 18.36 34.19 47.46
 Pit toilet latrine 40.32 24.84 34.84
 No facility 54.98 25.45 19.57
Wealth < 0.0001
 Poorest 54.96 25.81 19.23
 Poorer 51.02 25.60 23.38
 Middle 43.21 20.11 36.69
 Richer 26.47 33.64 39.89
 Richest 18.05 30.91 51.04
Mother’s age (years) 0.1247
 15–19 59.09 18.41 22.50
 20–24 46.00 26.88 27.12
 25–29 39.63 26.09 34.28
 30–34 36.21 27.14 36.64
 35–39 37.78 27.84 34.38
 ≥ 40 38.54 29.35 32.11
Maternal education < 0.0001
 No education 54.20 25.93 19.87
 Incomplete primary 41.57 27.42 31.01
 Complete primary 48.48 18.32 33.20
 Incomplete secondary 32.74 27.81 39.45
 Complete secondary 24.54 30.31 45.15
 Higher 10.76 33.03 56.21
Covered by health insurance 0.0006
 No 46.57 25.80 27.63
 Yes 36.43 27.59 35.97
Mother’s anemia level < 0.0001
 Moderate–severe 53.76 27.69 18.55
 Mild 45.40 25.59 29.00
 Not anemic 34.06 27.82 38.12
Number of children in household < 0.0001
 1–2 32.58 28.39 39.03
 3 44.15 25.66 30.19
 ≥ 4 48.31 26.77 24.92
Number of other wives < 0.0001
 0 37.60 26.51 35.89
 ≥ 1 53.05 27.26 37.60
Maternal decision-making autonomy 0.0336
 No autonomy 51.50 25.86 22.64
 Partial autonomy 41.57 27.17 31.27
 Full autonomy 37.24 26.79 35.97
Maternal attitudes that justify beating < 0.0001
 No 34.27 23.75 25.51
 Yes 50.75 28.64 37.09
Religion < 0.0001
 Christian 36.23 27.21 36.56
 Islam 46.92 27.04 26.04
 Traditional 72.76 15.85 11.39
 No religion 47.22 33.00 19.78
Ethnicity < 0.0001
 Akan 34.76 25.83 39.41
 Ga/Dangme 37.51 29.30 33.20
 Ewe 36.15 30.29 33.56
 Mole-Dagbani 45.83 26.50 27.67
 Gurma 59.39 26.15 14.46
 Other 44.61 29.00 26.39
Open in a new tab

P-values show whether there is a statistically significant difference between categories of each variable

Table 3.

Rao-Scott chi-square bivariate analysis of anemia type by sociodemographic factors for children 6–59 months from the 2008 Ghana Demographic and Health Survey (n = 2168)

Severe–moderate anemia (weighted %) Mild anemia (weighted %) Non anemic (weighted %) P-value
Region < 0.0001
 Western 62.03 17.36 20.61
 Central 62.55 22.89 14.57
 Greater Accra 30.99 31.33 37.68
 Volta 60.26 19.21 20.53
 Eastern 48.28 25.11 26.61
 Ashanti 56.38 23.39 20.23
 Brong Ahafo 54.12 23.91 21.98
 Northern 65.47 16.54 17.99
 Upper east 58.33 30.62 11.05
 Upper west 74.51 13.55 11.94
Urbanicity < 0.0001
 Urban 43.29 24.29 32.41
 Rural 63.15 21.62 15.23
Child’s age (months) < 0.0001
 6–11 67.34 17.89 14.77
 12–23 64.33 20.76 14.90
 24–35 57.61 22.40 19.98
 36–47 48.47 25.57 25.96
 48–59 46.08 24.41 29.52
Sex 0.4260
 Male 56.77 22.86 20.37
 Female 54.80 22.34 22.86
Child slept under net previous night 0.1338
 No 54.02 22.78 23.19
 Yes 58.09 22.38 19.53
Had diarrhea recently < 0.0001
 No 53.12 23.16 23.72
 Yes, last 2 weeks 65.26 20.55 14.19
Had fever recently 0.0015
 No 53.80 22.84 23.36
 Yes, last 2 weeks 62.49 22.00 15.51
Iron supplementation 0.6630
 No 55.80 23.08 21.12
 Yes 55.70 21.48 22.82
Drugs for parasites in last 6 mo 0.0021
 No 58.91 22.32 18.77
 Yes 51.83 23.02 25.15
Breastfeeding < 0.0001
 Ever breastfed 50.70 23.98 25.32
 Never breastfed 40.41 24.99 34.60
 Still breastfeeding 67.44 19.82 12.74
Dietary diversity (no. of food groups) 0.9970
 < 4 59.61 21.46 18.92
 ≥ 4 59.50 21.40 19.10
Water source < 0.0001
 Piped water 48.52 24.99 26.49
 Tube well water 62.51 22.21 15.28
 Dug well 54.07 24.49 21.44
 Surface water 66.68 17.05 16.27
 Bottled/sachet water 30.01 23.87 46.11
Toilet < 0.0001
 Flush toilet 28.56 28.91 42.52
 Pit toilet latrine 54.53 23.52 21.94
 No facility 66.38 18.74 14.88
Wealth < 0.0001
 Poorest 66.84 20.35 12.81
 Poorer 61.55 22.28 16.17
 Middle 60.53 20.33 19.14
 Richer 48.57 21.85 29.57
 Richest 29.36 31.31 39.32
Mother’s age (years) 0.0198
 15–19 68.88 19.98 11.14
 20–24 59.76 23.77 16.46
 25–29 57.89 21.11 21.01
 30–34 48.43 25.65 25.93
 35–39 54.61 22.35 23.04
 ≥ 40 55.42 20.18 24.41
Maternal education < 0.0001
 No education 64.95 18.45 16.60
 Incomplete primary 58.58 22.56 18.87
 Complete primary 53.48 26.02 20.50
 Incomplete secondary 50.85 25.40 23.75
 Complete secondary 36.16 23.24 40.60
 Higher 24.52 29.40 46.08
Covered by health insurance < 0.0001
 No 59.79 21.39 18.82
 Yes 49.12 24.67 26.21
Mother’s anemia level < 0.0001
 Moderate–severe 69.23 17.80 12.97
 Mild 56.79 22.41 20.80
 Not anemic 47.44 25.48 27.08
Number of children in household 0.1567
 1–2 53.88 22.85 23.28
 3 55.17 23.01 21.82
 ≥ 4 61.82 21.10 17.08
Number of other wives 0.0023
 0 54.23 22.86 22.91
 ≥ 1 64.73 19.40 15.87
Maternal decision-making autonomy 0.0489
 No autonomy 65.03 20.87 14.10
 Partial autonomy 56.70 21.19 22.11
 Full autonomy 53.89 23.68 22.43
Maternal attitudes that justify beating < 0.0001
 No 50.71 25.29 24.00
 Yes 63.16 18.74 18.10
Religion 0.0008
 Christian 52.88 23.78 23.33
 Islam 62.28 17.92 19.81
 Traditional 66.75 20.64 12.61
 No religion 61.40 24.93 13.68
Ethnicity 0.0010
 Akan 52.56 23.61 23.83
 Ga/Dangme 43.75 26.47 29.78
 Ewe 55.67 24.10 20.23
 Mole-Dagbani 60.98 19.96 19.07
 Gurma 74.56 17.16 8.27
 Other 55.85 22.72 21.42
Open in a new tab

P-values show whether there is a statistically significant difference between categories of each variable

Table 4.

Rao-Scott chi-square bivariate analysis of anemia type by sociodemographic factors for children 6–59 months from the 2003 Ghana Demographic and Health Survey (n = 3183)

Severe–moderate anemia (weighted %) Mild anemia (weighted %) Non anemic (weighted %) P-value
Region < 0.0001
 Western 56.33 22.33 21.34
 Central 52.54 23.85 23.60
 Greater Accra 37.33 23.32 39.35
 Volta 48.52 24.76 26.71
 Eastern 48.26 20.67 21.07
 Ashanti 55.34 21.91 22.75
 Brong Ahafo 50.44 21.39 28.18
 Northern 60.12 19.01 20.87
 Upper east 51.50 22.49 26.01
 Upper west 57.30 22.83 19.87
Urbanicity < 0.0001
 Urban 40.94 25.27 33.79
 Rural 57.40 20.47 22.12
Child’s age (months) < 0.0001
 6–11 47.39 18.52 34.09
 12–23 64.60 19.12 16.28
 24–35 55.75 21.59 22.65
 36–47 49.91 24.17 25.92
 48–59 40.72 28.01 31.27
Sex 0.9986
 Male 52.06 22.04 25.90
 Female 52.16 21.99 25.84
Child slept under net previous night 0.3841
 No 52.64 21.90 25.47
 Yes 49.21 22.68 28.11
Had diarrhea recently 0.0043
 No 50.85 22.09 27.06
Yes, last 2 weeks 58.66 21.46 19.88
Had fever recently < 0.0001
 No 49.58 22.60 27.82
 Yes, last 2 weeks 60.56 20.49 18.95
Iron supplementation
 No
 Yes
Drugs for parasites in last 6 mo
 No
 Yes
Breastfeeding 0.0002
 Ever breastfed 48.53 24.69 26.78
 Never breastfed 34.67 26.55 38.78
 Still breastfeeding 57.16 18.54 24.29
Dietary diversity (no. of food groups)
 < 4
 ≥ 4
Water source < 0.0001
 Piped water 41.10 24.24 34.66
 Open well water 56.11 24.73 19.17
 Protected well water 56.78 19.90 23.31
 Surface water 56.77 20.21 23.02
 Bottled/sachet water 45.98 30.72 23.30
Toilet < 0.0001
 Flush toilet 30.92 32.23 36.84
 Pit toilet latrine 51.36 21.70 26.94
 No facility 58.02 20.42 21.56
Wealth < 0.0001
 Poorest 61.72 18.77 19.50
 Poorer 56.41 21.85 21.73
 Middle 54.38 22.50 23.13
 Richer 44.76 22.13 33.11
 Richest 32.89 27.45 39.66
Mother’s age (years) 0.0689
 15–19 49.48 25.07 25.45
 20–24 58.67 17.09 24.23
 25–29 52.53 22.53 24.93
 30–34 47.66 25.69 25.65
 35–39 51.66 21.74 26.60
 ≥ 40 50.97 21.06 27.97
Maternal education < 0.0001
 No education 58.74 20.20 21.05
 Incomplete primary 54.06 22.07 23.87
 Complete primary 54.49 24.28 21.23
 Incomplete secondary 44.53 23.34 32.13
 Complete secondary 33.29 29.19 37.52
 Higher 38.34 16.58 45.08
Covered by health insurance
 No
 Yes
Mother’s anemia level 0.0013
 Moderate–severe 48.65 22.80 28.55
 Mild 55.99 20.63 23.38
 Not anemic 56.33 23.82 19.85
Number of children in household 0.0030
 1–2 47.59 23.71 28.71
 3 53.93 21.77 24.31
 ≥ 4 57.62 18.87 23.51
Number of other wives < 0.0001
 0 49.67 22.25 28.08
 ≥ 1 58.23 21.51 20.26
Maternal decision-making autonomy 0.0093
 No autonomy 54.43 21.77 23.80
 Partial autonomy 54.58 18.97 26.46
 Full autonomy 48.60 24.93 26.46
Maternal attitudes that justify beating 0.0033
 No 54.58 22.15 23.27
 Yes 49.21 21.87 28.91
Religion 0.0547
 Christian 50.52 22.16 27.32
 Islam 54.79 22.15 23.06
 Traditional 61.99 20.40 17.61
 No religion 55.85 20.69 23.47
Ethnicity 0.0381
 Akan 50.82 22.35 26.83
 Ga/Dangme 47.49 21.38 31.12
 Ewe 48.96 22.35 28.70
 Mole-Dagbani 56.66 22.65 20.69
 Gurma 62.98 15.94 21.08
 Other 52.86 21.82 25.32
Open in a new tab

P-values show whether there is a statistically significant difference between categories of each variabl

Factors Associated with Mild Anemia

In the 2014 multivariable logistic regression model, few factors were significantly associated with mild anemia (Table 5). Children aged 48–59 months were less likely to be anemic (OR 0.49; 95% CI 0.31, 0.79) than children aged 12–23 months. Children of mothers with severe–moderate anemia were more likely to be anemic (OR 2.04, 95% CI 1.13, 3.66) than children whose mothers did not have severe–moderate anemia. In 2008, no factors examined were significantly associated with mild anemia. In 2003, child’s age (OR 0.43, 95% CI 0.30, 0.64) and mother’s anemia status (OR 1.65, 95% CI 1.11, 2.45) were associated with child’s anemia status; in addition, using open well water versus piped water was associated with higher odds of mild anemia (OR 1.62, 95% CI 1.03, 2.55).

Table 5.

Adjusted odds ratios for anemia type by sociodemographic covariates for children 6–59 months from the 2003, 2008, and 2014 Ghana Demographic and Health Surveys

Covariates 2003 (n = 3028) 2008 (n = 1888) 2014 (n = 2030)
Severe–moderate anemia versus non-anemic Mild anemia versus non-anemic Severe–moderate anemia versus non-anemic Mild anemia versus non-anemic Severe–moderate anemia versus non-anemic Mild anemia versus non-anemic
Urbanicity
 Urban Ref Ref Ref Ref Ref Ref
 Rural 1.12 (0.76, 1.66) 0.96 (0.62, 1.48) 1.61 (1.05, 2.47) 1.37 (0.88, 2.13) 0.84 (0.55, 1.27) 0.92 (0.60, 1.41)
Child’s age (months)
 6–11 0.31 (0.22, 0.42) 0.43 (0.30, 0.64) 0.90 (0.52, 1.58) 0.84 (0.44, 1.61) 1.39 (0.81, 2.38) 1.43 (0.82, 2.49)
 12–23 Ref Ref Ref Ref Ref Ref
 24–35 0.61 (0.44, 0.87) 0.83 (0.57, 1.21) 0.62 (0.39, 1.00) 0.71 (0.41, 1.21) 0.48 (0.32, 0.73) 1.06 (0.69, 1.63)
 36–47 0.46 (0.33, 0.66) 0.83 (0.55, 1.23) 0.40 (0.25, 0.64) 0.67 (0.39, 1.16) 0.32 (0.21, 0.48) 0.64 (0.42, 0.98)
 48–59 0.32 (0.22, 0.45) 0.80 (0.56, 1.14) 0.34 (0.22, 0.55) 0.54 (0.32, 0.93) 0.20 (0.13, 0.31) 0.49 (0.31, 0.79)
Sex
 Male Ref Ref Ref Ref Ref Ref
 Female 1.07 (0.86, 1.32) 1.07 (0.84, 1.36) 0.84 (0.65, 1.08) 0.81 (0.60, 1.11) 0.84 (0.62, 1.14) 0.86 (0.61, 1.21)
Child slept under net previous night
 No Ref Ref Ref Ref Ref Ref
 Yes 0.79 (0.59, 1.06) 0.96 (0.70, 1.31) 1.11 (0.83, 1.50) 1.01 (0.72, 1.42) 1.03 (0.75, 1.42) 0.94 (0.70, 1.28)
Had diarrhea recently
 No Ref Ref Ref Ref Ref Ref
 Yes, last 2 weeks 1.14 (0.83, 1.55) 1.15 (0.79, 1.67) 1.37 (0.93, 2.02) 1.37 (0.87, 2.15) 1.13 (0.68, 1.85) 1.01 (0.60, 1.70)
Had fever recently
 No Ref Ref Ref Ref Ref Ref
 Yes, last 2 weeks 1.60 (1.20, 2.13) 1.20 (0.88, 1.63) 1.59 (1.10, 2.29) 1.36 (0.88, 2.09) 2.39 (1.58, 3.63) 1.32 (0.87, 2.01)
Iron supplementation
 No Ref Ref Ref Ref
 Yes 0.94 (0.67, 1.33) 0.86 (0.57, 1.30) 0.76 (0.53, 1.08) 1.30 (0.89, 1.88)
Drugs for parasites in last 6 mo
 No Ref Ref Ref Ref
 Yes 1.01 (0.72, 1.42) 1.01 (0.71, 1.43) 1.05 (0.73, 1.49) 1.11 (0.79, 1.55)
Water source
 Piped water Ref Ref Ref Ref Ref Ref
 Open well water 1.34 (0.87, 2.06) 1.62 (1.03, 2.55) 1.13 (0.71, 1.80) 1.28 (0.77, 2.15) 1.25 (0.78, 2.01) 1.08 (0.69, 1.69)
 Protected well water 1.10 (0.73, 1.64) 1.08 (0.68, 1.71) 1.12 (0.58, 2.17) 1.60 (0.88, 2.89) 1.31 (0.67, 2.55) 1.08 (0.58, 2.01)
 Surface water 1.07 (0.68, 1.68) 1.12 (0.67, 1.88) 0.99 (0.56, 1.76) 0.84 (0.43, 1.64) 1.19 (0.66, 2.13) 1.23 (0.64, 2.35)
 Bottled/sachet water 2.30 (0.58, 9.12) 2.10 (0.53, 8.31) 0.59 (0.31, 1.14) 0.50 (0.23, 1.10) 0.91 (0.54, 1.55) 1.41 (0.90, 2.21)
Toilet
 Flush toilet Ref Ref Ref Ref Ref Ref
 Pit toilet latrine 1.07 (0.67, 1.72) 0.69 (0.48, 0.99) 1.47 (0.81, 2.67) 1.30 (0.71, 2.40) 1.51 (0.84, 2.70) 0.75 (0.46, 1.21)
 No facility 1.01 (0.60, 1.71) 0.69 (0.45, 1.07) 1.73 (0.82, 3.63) 1.12 (0.52, 2.45) 1.93 (0.99, 3.77) 1.10 (0.62, 1.95)
Wealth
 Poorest Ref Ref Ref Ref Ref Ref
 Poorer 0.96 (0.65, 1.40) 1.24 (0.85, 1.81) 1.13 (0.69, 1.87) 0.98 (0.55, 1.75) 1.14 (0.72, 1.81) 1.11 (0.65, 1.89)
 Middle 0.91 (0.60, 1.39) 1.27 (0.82, 1.99) 1.05 (0.55, 2.01) 0.67 (0.32, 1.41) 0.67 (0.38, 1.18) 0.52 (0.28, 0.96)
 Richer 0.59 (0.34, 1.02) 0.82 (0.45, 1.48) 0.70 (0.34, 1.43) 0.63 (0.30, 1.34) 0.48 (0.22, 1.05) 0.90 (0.43, 1.89)
 Richest 0.42 (0.22, 0.81) 0.87 (0.46, 1.65) 0.58 (0.24, 1.40) 1.04 (0.41, 2.65) 0.33 (0.14, 0.74) 0.45 (0.19, 1.09)
Mother’s age (years)
 15–19 0.69 (0.38, 1.26) 1.14 (0.57, 2.30) 1.05 (0.35, 3.22) 1.14 (0.31, 4.17) 4.95 (1.17, 21.13) 3.18 (0.71, 14.22)
 20–24 Ref Ref Ref Ref Ref Ref
 25–29 0.90 (0.65, 1.26) 1.30 (0.91, 1.87) 0.94 (0.60, 1.48) 0.78 (0.46, 1.32) 0.86 (0.50, 1.47) 0.77 (0.41, 1.42)
 30–34 0.79 (0.57, 1.09) 1.33 (0.92, 1.92) 0.76 (0.48, 1.22) 0.77 (0.43, 1.40) 1.03 (0.63, 1.69) 0.99 (0.57, 1.72)
 35–39 0.68 (0.48, 0.98) 0.97 (0.64, 1.45) 0.95 (0.54, 1.66) 0.76 (0.39, 1.49) 1.08 (0.62, 1.87) 0.97 (0.56, 1.70)
 ≥ 40 0.70 (0.47, 1.05) 0.86 (0.53, 1.39) 0.75 (0.45, 1.26) 0.72 (0.37, 1.38) 0.70 (0.40, 1.22) 0.89 (0.47, 1.71)
Maternal education
 No education Ref Ref Ref Ref Ref Ref
 Primary (complete or incomplete) 0.87 (0.63, 1.22) 1.03 (0.74, 1.44) 0.87 (0.56, 1.36) 1.30 (0.81, 2.09) 0.67 (0.44, 1.03) 0.74 (0.47, 1.16)
 Secondary or higher 0.58 (0.42, 0.79) 0.80 (0.57, 1.11) 0.92 (0.57, 1.49) 1.36 (0.80, 2.32) 0.53 (0.34, 0.81) 0.81 (0.51, 1.27)
Covered by health insurance
 No Ref Ref Ref Ref
 Yes 0.69 (0.51, 0.93) 0.82 (0.57, 1.17) 0.74 (0.53, 1.04) 0.97 (0.70, 1.36)
Mother’s Anemia Level
 Moderate–severe 1.73 (1.19, 2.51) 1.65 (1.11, 2.45) 2.89 (1.90, 4.38) 1.30 (0.81, 2.10) 2.66 (1.46, 4.83) 2.04 (1.13, 3.66)
 Mild 1.35 (1.10, 1.66) 1.11 (0.85, 1.44) 1.345 (0.972, 1.86) 1.15 (0.78, 1.69) 1.80 (1.28, 2.54) 1.28 (0.87, 1.89)
 Not anemic Ref Ref Ref Ref Ref Ref
Number of children in household
 1–2 Ref Ref Ref Ref Ref Ref
 3 1.26 (1.02, 1.57) 1.02 (0.80, 1.30) 0.99 (0.73, 1.34) 1.07 (0.75, 1.528) 1.32 (0.93, 1.87) 1.24 (0.87, 1.76)
 ≥ 4 1.21 (0.89, 1.64) 0.87 (0.62, 1.22) 1.04 (0.68, 1.59) 1.05 (0.65, 1.689) 1.57 (0.97, 2.56) 1.51 (0.94, 2.44)
Number of other wives
 0 Ref Ref Ref Ref Ref Ref
 ≥ 1 1.36 (1.07, 1.71) 1.36 (1.05, 1.76) 1.13 (0.75, 1.70) 1.10 (0.69, 1.748) 1.22 (0.78, 1.91) 1.21 (0.73, 2.00)
Maternal decision-making autonomy
 No autonomy Ref Ref Ref Ref Ref Ref
 Partial autonomy 0.94 (0.67, 1.25) 0.78 (0.56, 1.07) 0.53 (0.31, 0.90) 0.60 (0.35. 1.008) 1.02 (0.50, 2.05) 0.84 (0.42, 1.68)
 Full autonomy 0.90 (0.67, 1.22) 1.06 (0.77, 1.45) 0.56 (0.32, 0.98) 0.67 (0.38, 1.206) 0.69 (0.36, 1.32) 0.81 (0.41, 1.60)
Maternal attitudes that justify beating
 Yes Ref Ref Ref Ref Ref Ref
 No 0.97 (0.77, 1.22) 0.90 (0.70, 1.16) 1.00 (0.73, 1.37) 1.41 (1.00, 2.00) 0.81 (0.58, 1.12) 1.01 (0.74, 1.36)
Religion
 Christian Ref Ref Ref Ref Ref Ref
 Islam 1.03 (0.74, 1.42) 1.02 (0.70, 1.49) 1.14 (0.67, 1.93) 0.78 (0.42, 1.450) 1.35 (0.81, 2.24) 1.19 (0.75, 1.86)
 Traditional 1.17 (0.74, 1.86) 1.28 (0.71, 2.29) 1.14 (0.61, 2.13) 1.19 (0.56, 2.503) 2.02 (0.74, 5.50) 1.01 (0.31, 3.22)
 No religion 0.89 (0.62, 1.28) 1.09 (0.67, 1.75) 1.14 (0.51, 2.55) 1.43 (0.62, 3.306) 1.91 (0.81, 4.51) 3.04 (1.33, 6.93)
Ethnicity
 Akan Ref Ref Ref Ref Ref Ref
 Ga/Dangme 0.80 (0.49, 1.33) 0.80 (0.48, 1.34) 0.96 (0.48, 1.94) 1.41 (0.78, 2.526) 1.92 (1.05, 3.50) 1.27 (0.67, 2.39)
 Ewe 0.77 (0.55, 1.08) 0.87 (0.60, 1.27) 1.20 (0.71, 2.00) 1.41 (0.80, 2.467) 0.88 (0.52, 1.47) 1.15 (0.72, 1.81)
 Mole-Dagbani 0.88 (0.58, 1.33) 1.20 (0.78, 1.86) 0.95 (0.55, 1.62) 1.45 (0.79, 2.656) 0.62 (0.34, 1.12) 0.95 (0.53, 1.70)
 Gurma 0.90 (0.51, 1.58) 0.93 (0.50, 1.75) 2.05 (1.04, 4.05) 1.73 (0.75, 3.971) 1.10 (0.42, 2.86) 1.50 (0.65, 3.46)
 Other 0.77 (0.50, 1.18) 0.96 (0.60, 1.55) 0.93 (0.52, 1.66) 1.36 (0.72, 2.565) 0.87 (0.47, 1.60) 1.30 (0.70, 2.40)
Open in a new tab

Bolded values are significant at the < 0.05 level

Factors Associated with Severe–Moderate Anemia

In 2014, child’s age had a strong association with severe–moderate anemia. As children aged, their odds of anemia became progressively lower; as compared to children 12–23 months old, those aged 24–35 months had 0.48 (95% CI 0.32, 0.73) times the odds of anemia, and others aged 48–59 months had 0.20 (95% CI 0.13, 0.31) times the odds of anemia. Fever in the previous 2 weeks was significantly associated with increased odds of severe–moderate anemia (OR 2.39, 95% CI 1.58, 3.63).

The other variables significantly associated with childhood severe–moderate anemia in 2014 were directly related to maternal characteristics or household factors. Mothers who had secondary or higher education were less likely to have moderately to severely anemic children compared to uneducated mothers (OR 0.53, 95% CI 0.34, 0.81). Children were significantly more likely to be moderately-severely anemic when their mothers had mild anemia (OR 1.80, 95% CI 1.28, 2.54) or severe–moderate anemia (OR 2.66, 95% CI 1.46, 4.83). Lastly, children in the richest wealth quintile had 0.33 (95% CI 0.14, 0.74) times the odds of severe–moderate anemia compared to children in the poorest wealth quintile (Table 5).

In 2008, child’s age, fever in the previous 2 weeks, and maternal anemia status were significantly associated with childhood severe–moderate anemia, similar to 2014. However, household wealth (OR 0.92, 95% CI 0.57, 1.49) and maternal education (OR 0.58, 95% CI 0.24, 1.40) were not associated with childhood severe–moderate anemia. In 2008, unlike in 2014, children were significantly less likely to have severe–moderate anemia if their mother's decision-making autonomy was partial (OR 0.53, 95% CI: 0.31, 0.90) or full (OR 0.56, 95% CI 0.32, 0.98). Furthermore, those children in families with health insurance had lower odds of anemia compared to other children without access to health insurance (OR 0.69, 95% CI 0.51, 0.93).

In 2003, child’s age was significantly associated with severe–moderate anemia, similar to 2008 and 2014. As in 2014, but unlike 2008, household wealth and maternal education did have a significant association with severe–moderate anemia during childhood in 2003.

Discussion

Anemia prevalence in Ghana is exceptionally high. Globally, anemia prevalence in young children (6–59 months old) is estimated at 43% as compared with 67% in Ghana (Stevens et al. 2013). From our analysis, ~ 40% of Ghanaian children aged 6–59 months had severe–moderate anemia in 2014. Although this represents a substantial improvement over 2003 and 2008, there is evidence of widening disparities across regions of Ghana. In 2003, severe–moderate anemia prevalence difference was 23% between the highest (Northern region) and the lowest (Greater Accra region). However, that gap increased to 34% in 2008 and 32% in 2014. There was also an urban–rural disparity in severe–moderate anemia prevalence (17% higher in rural areas in 2014), but this disparity has remained relatively constant over time.

Across all three survey years, child’s age was negatively associated with severe–moderate anemia, as older children had lower odds of anemia than younger children. The high prevalence of severe–moderate anemia in children under 2 years old appears related to poor maternal nutrition, as children born to malnourished mothers have poor stores of many essential micronutrients, such as iron, zinc, vitamin A and B12 and folate (Kotecha 2011; Neumann et al. 2004). Our finding that children with mothers who have anemia have higher odds of developing anemia themselves, provides further evidence for this (Table 5).

Complementary foods and feeding practices are especially important for determining the micronutrient adequacy of 6–23 month-old children, as breast milk makes a progressively smaller contribution to an infant’s nutritional requirements into late infancy and early childhood (Saaka and Galaa 2017; Woldie et al. 2015). Our findings are consistent with this observation, in that the prevalence of severe–moderate anemia was higher among children who were still being breastfed than those who never or formerly breastfed (Tables 2, 3, 4). This likely reflects inadequate consumption of high quality complementary foods with continued breastfeeding rather than a deleterious effect of continued breastfeeding itself on iron status or anemia (Cumber et al. 2017; Lander et al. 2009). Reverse causality may also underlie this association (i.e., smaller, malnourished children may be weaned later because of perceived vulnerability) (Habicht 2000; Simondon et al. 2001).

Infants also generally have a higher incidence of infectious diseases, which can reduce their ability to ingest and absorb iron, perhaps further explaining the higher prevalence of anemia among younger children (Villalpando et al. 2003). From bivariate analyses across all years, we determined that a higher prevalence of anemia was associated with diarrhea or fever experienced within the previous 2 weeks (Tables 2, 3, 4). Although diarrhea and fever were associated with anemia, the cross-sectional nature of observations precludes determining the direction of the association. Participant-reported diarrhea or fever was asked for a period preceding the Hb measurement, although we cannot determine the temporal pattern of any association. One published prospective study has suggested that anemia may be a precursor of diarrheal disease (Levy et al. 2005). The relationship could also be cyclic, with diarrhea initially decreasing the body's ability to ingest and absorb iron, hence increasing subsequent risk of anemia, and anemia then increasing the risk of additional diarrheal episodes (Semba et al. 2008).

The association between fever in the past 2 weeks and severe–moderate anemia persisted in the multivariable model for all survey years, however, this was not the case for diarrheal illness. In our model, we controlled for both water source and toilet type (often a proxy for sanitation), which could have attenuated any association between diarrheal illness and anemia, as cleaner water and improved sanitation are associated with a lower risk of diarrheal pathogen exposure and illness (WHO 2014). More broadly, socioeconomic status (e.g. household wealth and education) also has been shown to predict health outcomes (Cameron and Williams 2009; Feinstein 1993). We included both household wealth and education in our multivariable models, which could have controlled for the association between two health indicators, such as diarrhea and anemia (see Fig. 1).

In 2003 and 2014, children from higher-income households and children with more highly educated mothers had lower odds of severe–moderate anemia in multivariable analysis. (For 2008, these associations were only significant in bivariate analysis.) It seems reasonable that households with higher incomes are better equipped to keep their children healthy due to a greater ability to purchase health services and food with higher nutritional value. Additionally, highly educated mothers are more likely to be knowledgeable about how to care for their own health, and that of their child.

Limitations and Strengths

Our findings should be interpreted within the context of several limitations. The cross-sectional nature of the GDHS allows us to look for statistical associations, but not to assess temporality or causality. Survivor bias is also a possible issue; we only included surviving children and deaths could have resulted from complications due to anemia. Although this study analyzed data from three rounds of the GDHS, and each year's survey was similar, some variables such as health insurance coverage, iron supplementation, and parasites treatment were only available in later datasets, requiring slightly different multivariable models by year. Additionally, all datasets lacked information on factors such as malaria infection, so we were unable to consider the impact they had on anemia.

This study also has many strengths. The large sample size helped avoid small cell sizes in the multivariable analysis, allowing us to test multiple associations between potential predictors and anemia status with adequate statistical power. To the authors knowledge, this is the first study to assess predictors of anemia in Ghana over three different rounds of GDHS data.

Conclusions

The prevalence of anemia among children aged 6–59 months in 2014 remains unacceptably high, even though substantial improvement has occurred since 2003. Despite overall advances, Ghana has experienced widening disparities in the prevalence of anemia among regions, and a persistent disparity between urban and rural areas. Results demonstrate that younger child age, fever in the last 2 weeks, lower household wealth, less maternal education, and maternal anemia are significantly associated with greater severe–moderate anemia. Associations have remained relatively consistent over the 2003, 2008 and 2014 time periods. In order to decrease anemia prevalence among children, the Ghanaian government should concentrate on educating women, both through the traditional education system and through antenatal care visits. Antenatal care visits could also provide an opportunity to ensure mothers are receiving adequate nutrition during pregnancy, as this has significant implications for the amount of iron available to infants through breastfeeding. A focus on improving water sources and sanitation in Ghana would also be beneficial, since they are often seen as predictive of diarrheal disease, which may have a cyclic effect on anemia.

Acknowledgements

We are grateful to the interviewers and program staff who have conducted this survey.

Author Contributions

LS conceived of the data analysis plan, completed the data analysis, and draft the manuscript. AJ contributed to the data analysis plan, helped interpret the data, and revised the manuscript for important intellectual content. MW contributed to the data analysis plan, helped interpret the data, and revised the manuscript for important intellectual content. All authors gave final approval of the manuscript to be published and agree to act as guarantors of the work.

Funding

Bill and Melinda Gates Foundation (OPP1154099).

Compliance with Ethical Standards

Conflict of interests

The authors have no conflicts of interest relevant to this article to disclose.

Footnotes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Contributor Information

Luke M. Shenton, Email: lshenton@umich.edu

Andrew D. Jones, Email: jonesand@umich.edu

Mark L. Wilson, Email: wilsonml@umich.edu

References

  1. Balarajan Y, Ramakrishnan U, Ozaltin E, Shankar AH, Subramanian SV. Anaemia in low-income and middle-income countries. Lancet. 2011;378:2123–2135. doi: 10.1016/S0140-6736(10)62304-5. [DOI] [PubMed] [Google Scholar]
  2. Beard JL, Connor JR. Iron status and neural functioning. Annual Review of Nutrition. 2003;23(1):41–58. doi: 10.1146/annurev.nutr.23.020102.075739. [DOI] [PubMed] [Google Scholar]
  3. Black, R. E., Victora, C. G., Walker, S. P., Bhutta, Z. A., Christian, P., de Onis, M., … Maternal and Child Nutrition Study Group. (2013). Maternal and child undernutrition and overweight in low-income and middle-income countries. Lancet (London, England),382(9890), 427–451. 10.1016/S0140-6736(13)60937-X. [DOI] [PubMed]
  4. Camaschella C. Iron-deficiency anemia. New England Journal of Medicine. 2015;372(19):1832–1843. doi: 10.1056/NEJMra1401038. [DOI] [PubMed] [Google Scholar]
  5. Cameron L, Williams J. Is the relationship between socioeconomic status and health stronger for older children in developing countries? Demography. 2009;46(2):303–324. doi: 10.1353/dem.0.0054. [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Cumber SN, Bongkiynuy N, Jaila S, Tsoka-Gwegweni JM. Poor complementary feeding practices among young children in Cameroon. South African Journal of Clinical Nutrition. 2017;30(2):37–38. doi: 10.1080/16070658.2016.1251685. [DOI] [Google Scholar]
  7. Egbi, G., Steiner-Asiedu, M., Kwesi, F. S., Ayi, I., Ofosu, W., Setorglo, J.,… Armar-Klemesu, M. (2014). Anaemia among school children older than five years in the Volta Region of Ghana. The Pan African Medical Journal,17(Suppl 1), 10. 10.11694/pamj.supp.2014.17.1.3205. [DOI] [PMC free article] [PubMed]
  8. Ewusie JE, Ahiadeke C, Beyene J, Hamid JS. Prevalence of anemia among under-5 children in the Ghanaian population: Estimates from the Ghana demographic and health survey. BMC Public Health. 2014;14(1):626. doi: 10.1186/1471-2458-14-626. [DOI] [PMC free article] [PubMed] [Google Scholar]
  9. Feinstein JS. The relationship between socioeconomic status and health: A review of the literature. The Milbank Quarterly. 1993;71(2):279–322. doi: 10.2307/3350401. [DOI] [PubMed] [Google Scholar]
  10. Ghana Statistical Service. (2012). 2010 Population and housing census final results. Retrieved December 2017, from https://www.statsghana.gov.gh/docfiles/2010phc/2010_POPULATION_AND_HOUSING_CENSUS_FINAL_RESULTS.pdf.
  11. Ghana Statistical Service, Ghana Health Service, & ICF International. (2009). Ghana Demographic and Health Survey 2008. Retrieved August 13, 2012, from https://dhsprogram.com/pubs/pdf/FR221/FR221.pdf.
  12. Ghana Statistical Service, Ghana Health Service, & ICF International. (2015). Ghana Demographic and Health Survey 2014. Retrieved December 2017, from www.DHSprogram.com.
  13. Ghana Statistical Service, Noguchi Memorial Institute for Medical Research, & ORC Macro. (2004). Ghana Demographic and Health Survey 2003. Retrieved December 2017, from https://dhsprogram.com/pubs/pdf/FR152/FR152.pdf.
  14. Habicht JP. The association between prolonged breastfeeding and poor growth—What are the implications? Advances in Experimental Medicine and Biology. 2000;478:193–200. [PubMed] [Google Scholar]
  15. Klinkenberg, E., McCall, P. J., Wilson, M. D., Akoto, A. O., Amerasinghe, F. P., Bates, I.,… Donnelly, M. J. (2006). Urban malaria and anaemia in children: A cross-sectional survey in two cities of Ghana. Tropical Medicine and International Health,11(5), 578–588. 10.1111/j.1365-3156.2006.01609.x. [DOI] [PubMed]
  16. Kotecha PV. Nutritional anemia in young children with focus on Asia and India. Indian Journal of Community Medicine: Official Publication of Indian Association of Preventive & Social Medicine. 2011;36(1):8–16. doi: 10.4103/0970-0218.80786. [DOI] [PMC free article] [PubMed] [Google Scholar]
  17. Lander, R., Enkhjargal, T., Batjargal, J., Bolormaa, N., Enkhmyagmar, D., Tserendolgor, U.,… Gibson, R. (2009). Poor dietary quality of complementary foods is associated with multiple micronutrient deficiencies during early childhood in Mongolia. Public Health Nutrition,13(9), 1304–1313. 10.1017/S1368980009991856. [DOI] [PubMed]
  18. Larsen DA, Grisham T, Slawsky E, Narine L. An individual-level meta-analysis assessing the impact of community-level sanitation access on child stunting, anemia, and diarrhea: Evidence from DHS and MICS surveys. PLOS Neglected Tropical Diseases. 2017;11(6):e0005591. doi: 10.1371/journal.pntd.0005591. [DOI] [PMC free article] [PubMed] [Google Scholar]
  19. Levy A, Fraser D, Rosen SD, Dagan R, Deckelbaum RJ, Coles C, Naggan L. Anemia as a risk factor for infectious diseases in infants and toddlers: Results from a prospective study. European Journal of Epidemiology. 2005;20(3):277–284. doi: 10.1007/s10654-004-6515-6. [DOI] [PubMed] [Google Scholar]
  20. McCann JC, Ames BN. An overview of evidence for a causal relationship between iron deficiency during development and deficits in cognitive or behavioral function. The American Journal of Clinical Nutrition. 2007;85:931–945. doi: 10.1093/ajcn/85.4.931. [DOI] [PubMed] [Google Scholar]
  21. Mueller I, Rarau P, Vaucher P, Lombardo P, Senn N, Favrat B. Hemoglobin levels and the risk of malaria in Papua New Guinean infants: A nested cohort study. The American Journal of Tropical Medicine and Hygiene. 2017 doi: 10.4269/ajtmh.17-0093. [DOI] [PMC free article] [PubMed] [Google Scholar]
  22. Neumann CG, Gewa C, Bwibo NO. Child nutrition in developing countries. Pediatric Annals. 2004;33(10):658. doi: 10.3928/0090-4481-20041001-09. [DOI] [PubMed] [Google Scholar]
  23. Ngnie-Teta I, Kuate-Defo B, Receveur O. Multilevel modelling of sociodemographic predictors of various levels of anaemia among women in Mali. Public Health Nutrition. 2009;12(9):1462–1469. doi: 10.1017/S1368980008004400. [DOI] [PubMed] [Google Scholar]
  24. Paganini D, Zimmermann MB. Effects of iron fortification and supplementation on the gut microbiome and diarrhea in infants and children: A review. The American Journal of Clinical Nutrition. 2017 doi: 10.3945/ajcn.117.156067. [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Saaka M, Galaa SZ. How is dietary diversity related to haematological status of preschool children in Ghana? Food & Nutrition Research. 2017;61(1):1333389. doi: 10.1080/16546628.2017.1333389. [DOI] [PMC free article] [PubMed] [Google Scholar]
  26. Semba RD, de Pee S, Ricks MO, Sari M, Bloem MW. Diarrhea and fever as risk factors for anemia among children under age five living in urban slum areas of Indonesia. International Journal of Infectious Diseases. 2008;12(1):62–70. doi: 10.1016/J.IJID.2007.04.011. [DOI] [PubMed] [Google Scholar]
  27. Siekmans K, Receveur O, Haddad S. Can an integrated approach reduce child vulnerability to anaemia? Evidence from three African countries. PLoS ONE. 2014 doi: 10.1371/journal.pone.0090108. [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Simondon KB, Costes R, Delaunay V, Diallo A, Simondon F. Children’s height, health and appetite influence mothers’ weaning decisions in rural Senegal. International Journal of Epidemiology. 2001;30(3):476–481. doi: 10.1093/ije/30.3.476. [DOI] [PubMed] [Google Scholar]
  29. Stevens, G. A., Finucane, M. M., De-Regil, L. M., Paciorek, C. J., Flaxman, S. R., Branca, F. … Nutrition Impact Model Study Group (Anaemia). (2013). Global, regional, and national trends in haemoglobin concentration and prevalence of total and severe anaemia in children and pregnant and non-pregnant women for 1995–2011: A systematic analysis of population-representative data. The Lancet Global Health,1(1), e16–25. 10.1016/S2214-109X(13)70001-9. [DOI] [PMC free article] [PubMed]
  30. United States Agency for International Development. (2017). The DHS Program. Retrieved July 27, 2017, from https://www.dhsprogram.com/.
  31. VanBuskirk KM, Ofosu A, Kennedy A, Denno DM. Pediatric anemia in rural ghana: A cross-sectional study of prevalence and risk factors. Journal of Tropical Pediatrics. 2014;60(4):308–317. doi: 10.1093/tropej/fmu020. [DOI] [PubMed] [Google Scholar]
  32. Villalpando, S., Shamah-Levy, T., Ramírez-Silva, C. I., Mejía-Rodríguez, F., & Rivera, J. A. (2003). Prevalence of anemia in children 1 to 12 years of age. Results from a nationwide probabilistic survey in Mexico. Salud Publica de Mexico, 4(Suppl 4), S490–S498. [DOI] [PubMed]
  33. WHO . Haemoglobin concentrations for the diagnosis of anaemia and assessment of severity. Geneva: World Health Organization; 2011. [Google Scholar]
  34. Woldie H, Kebede Y, Tariku A. Factors associated with anemia among children aged 6–23 months attending growth monitoring at Tsitsika Health Center, Wag-Himra Zone, Northeast Ethiopia. Journal of Nutrition and Metabolism. 2015;2015:928632. doi: 10.1155/2015/928632. [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Working Group on Infant and Young Child Feeding Indicators. (2006). Developing and Validating Simple Indicators of Dietary Quality and Energy Intake of Infants and Young Children in Developing Countries: Summary of findings from analysis of 10 data sets. Retrieved December 2017, from www.fantaproject.org.
  36. World Health Organization. (2008a). Indicators for assessing infant and young child feeding practices: Part 1 Definition. Retrieved from https://apps.who.int/iris/bitstream/handle/10665/43895/9789241596664_eng.pdf?sequence=1.
  37. World Health Organization. (2008b). The Global Burden of Disease: 2004 update. 10.1038/npp.2011.85.
  38. World Health Organization. (2014). Preventing diarrhoea through better water, sanitation and hygiene. Geneva. Retrieved from https://apps.who.int/iris/bitstream/handle/10665/150112/9789241564823_eng.pdf;jsessionid=5758DFB95F57DB9CF8362A5A6FEBEDDA?sequence=1.

Articles from Maternal and Child Health Journal are provided here courtesy of Springer

RESOURCES