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Anaemia and associated factors among children aged 6–23 months in agrarian community of Bale zone: a cross-sectional study

Published online by Cambridge University Press:  02 November 2022

Mekonnen Tegegne*
Affiliation:
Department of Nutrition and Dietetics, Faculty of Public Health, Jimma University, Jimma, Ethiopia
Kalkidan Hassen Abate
Affiliation:
Department of Nutrition and Dietetics, Faculty of Public Health, Jimma University, Jimma, Ethiopia
Tefera Belachew
Affiliation:
Department of Nutrition and Dietetics, Faculty of Public Health, Jimma University, Jimma, Ethiopia
*
*Corresponding author: Mekonnen Tegegne, email [email protected]

Abstract

Anaemia remains among the most prevalent nutritional problems among children in developing countries. In Ethiopia, more than half of children <5 years of age are anaemic. In the early stages of life, it leads to poor cognitive performance, delay psychomotor development and decreases working capacity in later life. The present study aimed to assess the prevalence and associated factors of anaemia among children aged 6–23 months in the Bale zone. A community-based cross-sectional study was conducted from 1 to 30 June 2021. Multistage stratified sampling and simple random sampling techniques were employed to select 770 samples. An interviewer-administered questionnaire was used to collect data on socio-demographic, child health and feeding practices. Haemoglobin levels were estimated using a portable Hemosmart machine. Children with haemoglobin values below 11 g/dl were considered anaemic. Binary logistic regression analysis was performed to identify factors associated with anaemia. Statistical significance was set at P < 0⋅05. The prevalence of anaemia was 47⋅9 % (95 % CI (44⋅4, 51⋅5)). The multivariate analysis showed that child age (6–11 months) (AOR 1⋅47; 95 % CI (1⋅06, 2⋅03)), household food insecurity (AOR 1⋅44; 95 % CI (1⋅01, 2⋅04)), having diarrhoea and cough in the past 2 weeks (AOR 1⋅70; 95 % CI (1⋅18, 2⋅44)) and (AOR 1⋅97; 95 % CI (1⋅28, 3⋅04), respectively), not consuming the recommended dietary diversity (AOR 2⋅72; 95 % CI (1⋅96, 3⋅77)) and stunting (AOR 1⋅88; 95 % CI (1⋅31, 2⋅70)) were significantly associated with anaemia. Anaemia in children aged 6–23 months was a severe public health problem in the study area. Integrated nutritional interventions combined with iron fortification and supplementation is recommended.

Type
Research Article
Creative Commons
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Anaemia, a condition marked by low levels of haemoglobin (Hb) concentration in red blood cells (RBCs), affects approximately one-fourth of the world's population(1,Reference Black, Victora and Walker2) . It is a public health problem in both developed and developing countries(Reference McGuire3). Although anaemia occurs at all stages of life, infants and young children are at elevated risk because of their rapid growth and development. In addition, their stored iron gets deficient during this period(Reference Stevens, Finucane and De-Regil4). Globally, 43 % of children under the age of 5 are anaemic with a higher prevalence in Africa and Asia. In 2016, the estimated prevalence was approximately 55 % in South Asia and 60 % in Sub-Saharan Africa(5).

The causes of anaemia in low- and middle-income countries are multifactorial. Even though, there may be many causes dietary iron deficiency is usually the major contributing factor. Other significant nutritional deficiencies (e.g. low intakes of folic acid and vitamin A, B12 and C) and infectious diseases (e.g. malaria and hookworm) may also contribute to anaemia(Reference Allali, Brousse and Sacri6,Reference Lopez, Cacoub and Macdougall7) . In resource-limited settings, the World Health Organization (WHO) recommended haemoglobin concentration level to assess anaemia in under-five children with a cut-off point of less than 11⋅0 grams per decilitre (g/dl)(8). Anaemia in childhood has an irreversible adverse effect on the health, growth and development of children(Reference Black, Quigg and Hurley9). A child with anaemia will have repeated episodes of infection and infection episodes are associated with risk of morbidity and mortality(Reference Jayaweera, Noordeen and Rayes10). Children suffering from iron deficiency anaemia (IDA) have also slower cognitive development and poor school performance and work capacity in later years, which intern reduces the earning potential of individuals and hence damages national economic growth at large(Reference Zimmermann and Hurrell11,Reference Victora, Adair and Fall12) .

The Ethiopian government has made different strategies to alleviate childhood malnutrition in all its forms. For example, the National Nutritional Program II (NNP-II) has planned to reduce anaemia in children under five to 24 % by 2020 through initiatives like identifying and treating anaemia cases, fortification of food and providing micronutrient supplements(13). Despite all efforts, anaemia remains a serious challenge in Ethiopian children. The global burden of diseases study showed that anaemia in children was one of the most common causes of child death in Ethiopia, and continues to be a major public health problem(Reference Misganaw, Haregu and Deribe14). In addition, the 2016 Ethiopia Demographic and Health Survey (EDHS) reported that the prevalence of anaemia among children 6–59 months of age was 57 %. The levels were higher in those aged 6–23 months, with 72 % of these children having anaemia. With a prevalence level higher than 40⋅0 %, the WHO considers anaemia in children as a severe public health problem. Most importantly because of differences in the geographical area and socio-economic characteristics, the magnitude of anaemia showed regional variation ranging from (83 %) in Somali region to (42 %) in Amhara region. Oromia region where this study was conducted is among the highest prevalence (66 %)(15,16) . Previous studies have reported that childhood anaemia is associated with a higher risk of continued breast-feeding, early initiation of complementary feeding, poor dietary diversity, having household food insecurity, drinking water from unsafe sources, not receiving anthelminthic drugs and stunting(Reference Malako, Asamoah and Tadesse1719).

Despite their increased vulnerability, little was known about the magnitude and associated factors of anaemia among infants and young children aged 6–23 months in the study area. Identifying the magnitude, distribution and risk factors of IDA in different contexts in countries like Ethiopia with different lifestyle and cultural practices is a crucial step in eradicating the consequences of childhood anaemia. Moreover, information on the magnitude and factors associated with childhood anaemia in different settings and age groups provide important inputs to design inclusive strategies to achieve sustainable development goal 3 ‘Ensure healthy lives and promote well-being for all at all ages’. Therefore, the present study intended to assess the magnitude and associated factors of anaemia among children 6–23 months in Bale Zone, South-East Ethiopia.

Methods and materials

A community-based cross-sectional study was conducted from 1 to 30 June 2021 among children aged 6–23 months in the Bale zone, to determine the magnitude of anaemia and its associated factors. Bale zone is one of the twenty administered zones in Oromia regional state, located in the southeastern part of Ethiopia. The capital of Bale zone is Robe town which is located 430 km away from Addis Ababa, the national capital. According to the Bale zone health office, the zone has an estimated population of 269 950 in 2019 of which 208 653 are under five and 72 514 are under two children. There is 1 referral, 2 genera, 1 primary hospital, 54 health centres and 223 health posts in the Zone. Farming and livestock keeping are the largest source of livelihood and wheat barely teff and legumes are the major crops grown in the zone.

Sample size, sampling technique and procedures

The present study is the baseline for a quasi-experimental study conducted to assess the effect of soaking complementary food flours on haemoglobin, nutrition and health status of children 6–23 months in an agrarian community of Bale Zone (Clinical trial.gov NCTO5254717). The sample size for the baseline survey was determined using single population proportion formula with the following assumption: confidence interval (CI) of 95 %, a margin of error of 5 %, design effect of 2, non-response rate of 10 % and the proportion of child anaemia (65⋅5 %), stunting (37 %), underweight (24 %), and wasting (10 %) taken from EDHS 2016 for Oromia region(16). Since the sample size calculated for the variable stunting is the largest = 787, it was taken as the estimated sample size for this study.

Multistage stratified followed by a simple random sampling procedure was employed to reach the study subjects. In the first stage out of seven agrarian districts in the Bale zone, two districts namely Agarfa and Goba were selected randomly. Kebeles (the smallest administrative unit in Ethiopia) found in the selected districts were stratified as urban and rural. In the selected districts, a total of eight (six rural and two urban) kebeles were selected randomly. After the total number of households with children aged 6–23 months in each selected kebeles was obtained from the health extension workers registry, the total sample size was proportionally allocated for each selected kebeles. At the third stage, a list of identification numbers for each household with an eligible child (a child aged 6–23 months) in randomly selected kebeles was developed and study participants were selected using a computer-generated simple random sampling method.

Data collection and measurements

A pretested, semi-structured and interviewer-administered questionnaires which were developed by reviewing different relevant literature(Reference Black, Quigg and Hurley9,16,Reference Belachew and Tewabe18) , and guidelines(19,20) , were used to collect data. Questionnaires were initially prepared in English and translated into each local language the participants spoke; (Afaan Oromo and Amharic) and retranslated back to English to maintain consistency. The questionnaire was composed of data on household socio-demographic and economic status, Household Food Security Status (HHFSS), maternal and child health, child feeding practices and household's source of drinking water and availability of latrine. Household wealth was assessed using questioner adapted from the Ethiopian demographic and health survey (EDHS 2016) and household food insecurity was determined by using the Household Food Insecurity Access Scale (HFIAS) developed by Food and Nutritional Technical Assistance (FANTA). The HFIAS tools have nine occurrence questions that represent an increasing level of severity of food insecurity (access) and nine ‘repetitiveness of occurrence’ questions that are asked as a follow-up for each occurrence question to determine how often the condition occurred during the last 4 weeks. The frequency of occurrence of the event was ranked as ‘rarely’ (1), ‘sometimes’ (2) and ‘often’ (3). Scores to the answer of each question were summed to create a household food security score, with a minimum score of ‘0’ and a maximum score of ‘27’. The higher the score, the more food insecurity the household experience, and the lower the score, the less food insecurity the household experiences. Households with an HFIAS score of 0–1 are categorised as food secure and 2 and above were considered as food insecure(Reference Coates, Swindale and Bilinsky21).

Child meal frequency and dietary diversity scores were determined by using tools of WHO Infant and Young Child Feeding (IYCF) indicators with some modifications to fit the local context. This is based on the mother's recall of all food her child consumed and the number of times her child took solid, semi-solid, or soft food in the previous 24 h. Children's health status was assessed from the history of a symptom of cough, fever and diarrhoea in the last 2 weeks preceding the survey.

The anthropometric measurement (length and weight) which is used to determine a child nutritional status were taken using standard techniques. The length of the child was taken in the recumbent position using a wooden measuring board and recorded to the nearest 0⋅1 cm, while weight was taken using a weighing scale with minimum clothing and recorded to the nearest 10 g.

Haemoglobin levels were determined using portable Hemosmart Gold (England, Serial No.Ax006/04) machine within the home by trained data collectors. For Haemoglobin test, a sample of blood was obtained by pricking fingertip of older children and heel of smaller children and the pricked finger or heel was gently pressed to get a sample of a drop of blood on the microcuvette and then the microcuvette was inserted into the Hemosmart machine. To prevent contamination of the blood sample, the finger or heel was cleaned with an alcohol swab and the first drop of blood was wiped off with clean cotton and the next drop was collected into a disposable microcuvette. After adjusting for altitude, Haemoglobin level was recorded to the nearest 0⋅1 g/dl. The altitude of the area's was measured by using a portable GPS (global positioning system) (GPS 72H GARMIN Idn. 1T72400267-Taiwan). Equipment like lancet, microcuvette and gloves were used for each child and discarded properly after use.

Data were collected by eight BSc Nurses and supervised by two Health officers who are fluent in speaking both Afaan Oromo and Amharic languages.

Data quality assurance

The questionnaire was pretested in 5 % of the total sample before actual data collection outside the selected districts and modification was made based on the findings. Three days training were given to data collectors and supervisors. The focus of the training was on the objective of the study, interview techniques, basic skills of haemoglobin and anthropometric measurements, and on calibrations of equipment. The training also covered measures to be taken to prevent the transmission of COVID-19 during the data collection process.

To maintain the accuracy of weight measurement, the weight scale was returned to 0 before every measurement and calibrated using 1 kg standard weight. While the length measuring board was checked with other meter taps on daily bases. For each measurement of length and weight, reading was taken twice, and in cases when there was a difference the average of the two was taken.

Operational definitions

  • Anaemia among children 6–23 months: A child is considered to be anaemic if the adjusted haemoglobin count is less than 11⋅0 grams per decilitre (g/dl) against the World Health Organization (WHO) reference range. Haemoglobin value of 10–10⋅9 g/dl, 7⋅0–9⋅9 g/dl and less than 7 g/dl were considered as mild, moderate and severe anaemia, respectively(20).

  • Stunting: A child is considered to be stunted when a child's length-for-age Z-scores was less than −2 Standard Deviation (sd) from the sex-specific reference population of the World Health Organization (WHO) Multicentre Growth Study(22).

  • Wasting: A child is considered to be wasted when the child's weight-for-length Z-scores were less than −2 Standard Deviation (sd) from the sex-specific reference population of the World Health Organization (WHO) Multicentre Growth Study(22).

  • Underweight: A child is considered to be underweight when a child's weight-for-age Z-scores were less than −2 Standard Deviation (sd) from the sex-specific reference population of the World Health Organization (WHO) Multicentre Growth Study, was defined as underweight(22).

  • Minimum meal frequency: Breast-fed and non-breast-fed children aged 6–23 months who received solid, semi-solid or soft foods (but also including milk feeds for non-breast-fed children) with the minimum number of times or more. For breast-feeding, children minimum is defined as two times for infants 6–8 months and three times for children 9–23 months. For non-breast-feed, children minimum is defined as four times for children 6–23 months. ‘Meals’ include both meals and snacks (other than trivial amounts), and frequency is based on caregiver reports(23).

  • Minimum dietary diversity: Consumption of four or more food groups from the WHO recommended seven food groups within 24 h day or night before the survey. The seven foods groups used for tabulation of this indicator are: grains, roots and tubers; legumes and nuts; dairy products (milk, yogurt, cheese); flesh foods (meat, fish, poultry and liver/organ meats); eggs; vitamin-A-rich fruits and vegetables and other fruits and vegetables(23).

  • Diarrhoea: The passage of three or more loose or watery stools over 24 h period or more frequently than normal for a child in the last 2 weeks(24).

  • Fever: Mothers’ perception of increased body temperature per day in the last 2 weeks(24).

  • Cough: Mother's perception of cough in the last 2 weeks(25).

Data management and analysis

Data were checked for completeness, coded and entered into Epidata version 3.1 and exported to SPSS version 23.0 for analysis. The household wealth index was assessed based on household asset data using principal component analysis (PCA). Kaiser–Meyer–Olikin (KMO) test and Bartlett's Test of Sphericity (BTS) were done to determine sampling adequacy for PCA. To check the pattern of relationships between variables and components of communality was determined for every item, and items with communality less than 50 % were removed from the analysis. Components with Eigenvalues greater than 1, total variance explained more than 60 % and items loaded of at least 0⋅40 were retained to construct factor scores. Finally, factor scores computed by the PCA were summed and ranked as tertile (low, medium and high)(Reference Van den Broeck, Willie and Younger26).

The WHO Anthro version 3.2.2 software was used to convert the anthropometric measures; weight, length and age values to Z-scores of the indices, and the WHO nutrition indices were used to classify the nutritional status as stunting, wasting and underweight(Reference Van den Broeck, Willie and Younger27).

Descriptive statistics were used to summarise the characteristics of the study subjects. Bivariate and multivariate logistic regression analysis was carried out to assess any association between each independent variable and the dependent variable. Independent variables found to have P-value less than 0⋅05 at bivariate logistic regression were included in multivariable logistic regression for controlling the possible effect of confounders. Those variables with P < 0⋅05 in multivariable logistic regression analysis were considered to have statistical significance. The characteristics of association were determined based on odds ratio (OR) with a 95 % CI. The goodness of model fit was tested using Hosmer–Lemeshow test at P > 0⋅05.

Ethical clearance

This study was conducted according to the guidelines laid down in the declaration of Helsinki and all procedures involving study subjects were approved by the Institutional Review Board of Jimma University (Ref. No. JHRPG1/776/20). Permission letters were also secured from the Bale zone health bureau and the respective district health offices. Informed written consent was obtained from study subjects after a brief explanation of the risks and benefits of participating in the study. For the issue of confidentiality, a unique identification number was given to subjects. Children aged 6–23 months who appear with severe acute malnutrition were referred to a health facility for treatment. Maximum precautions per WHO guidelines for the prevention of COVID-19 transmission were taken throughout the data collection period. All data collectors and supervisors wore face masks throughout the data collection period. Studied mothers who appeared without face masks were provided face masks. Data collectors cleaned their hands and equipment with sanitizer (60 % alcohol) after every contact and each procedure.

Results

Socio-economic and demographic-related characteristics

A total of 770 respondents was included in the final analysis, giving a response rate of 97⋅8 %. The mean age (±sd) of children and mothers were 11⋅58 (±2⋅750) months and 25⋅57 (±4⋅863) years, respectively. One hundred and seventy-four (22⋅6 %) of mothers and thirty-seven (4⋅8 %) of fathers were unable to read and write. Of the surveyed households, 287 (37⋅3 %) earned less than one thousand Birr per month, 256 (33⋅2 %) were ranked at a low wealth index level and 307 (39⋅8 %) were food insecure (Table 1).

Table 1. Socio-demographic and economic status of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021 (n 707)

HH, household; ETB, Ethiopian Birr.

Maternal and child health-related characteristics

The majority 732 (95⋅1 %) of the mothers had received at least one antenatal care service (ANC), of which only 202 (26⋅1 %) have four or more ANC contacts during their last pregnancy. More than half 403 (52⋅3 %) of the mothers were taking iron folate supplementation, and the majority 653 (84⋅8 %) gave birth to their last child at the health facility. More than half 414 (53⋅8 %) of the mothers received postnatal service at least once during their last delivery. Nearly half 422 (54⋅8 %) of the children received vitamin A supplements in the previous 6 months and nearly one-third 227 (29⋅5 %) attended growth monitoring and promotion services. Four hundred and twenty-eight (55⋅6 %) of the studied children had a history of illness 2 weeks before this study. Diarrhoea was experienced by 208 (27⋅2 %), fever was experienced by 135 (17⋅5 %) and Cough was experienced by 126 (16⋅4 %) of the children 2 weeks before the survey (Table 2).

Table 2. Maternal and child health-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021(n 707)

ANC, antenatal care; IYCF, Infant and Young Child Feeding; IFA, iron folic acid; PNC, postnatal care.

Child feeding practice

Six hundred and seventy-nine (88⋅2 %) of mothers fed colostrum to their children within the first 5 days after delivery and 679 (88⋅2 %) were reported giving pre-lacteal feeding. The majority 654 (84⋅9 %) of the mother were practicing exclusively breast-feeding for the first 6 months. Seven hundred and forty (96⋅1 %) children were introduced complementary feeding at age of 6 months. Nearly two-thirds 555 (72⋅1 %) of the children received the recommended minimum meal frequency and more than one-third 292 (37⋅9 %) of them received minimum dietary diversity. Regarding nutritional status, about 112 (14⋅5 %) of the children were wasted, 259 (33⋅6 %) were stunted and 87 (11⋅3 %) were underweight (Table 3).

Table 3. Child feeding practice-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021

BF, Breast-feeding.

Water source sanitation and hygienic

Six hundred and ninety-three (90 %) of the households were used pipe water as their source for drinking water. The majority of the households 697 (90⋅1) owned latrine/toilet in their house (Table 4).

Table 4. Water source sanitation and hygienic-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021

VIP, ventilated improved pit latrine.

Prevalence of anaemia

The mean ± sd haemoglobin concentration was 11⋅23 ± 1⋅26 g/dl with a range of 7⋅8–15⋅6 g/dl. The overall prevalence of anaemia among children aged 6–23 months was 47⋅9 % (95 % CI 44⋅4, 51⋅5). Among anaemic children, 113 (14⋅7 %) had moderate anaemia, 256 (33⋅2 %) had mild anaemia and no child had severe anaemia. Anaemia was highest among children aged 6–11 months (52⋅1 %) than children aged 12–23 (44⋅3 %) (Fig. 1).

Fig. 1. Prevalence of anaemia among children age 6–23 months in agrarian community of Bale zone, South East, Ethiopia, 2021.

Factors associated with anaemia

In Bivariable logistic regression analysis, child's age, maternal age, maternal educational status, household monthly income, household source of drinking water, availability of latrine, HHFSS, maternal iron folic acid (IFA) intake, child's growth promotion service utilisation, child's history of cough and diarrhoea in the past 2 weeks, child minimum dietary diversity practice, stunting and underweight were factors associated with anaemia at a P-value of less than 0⋅5. Subsequently, these variables were fitted to multivariate logistic regression model, and it was observed that child age, household food insecurity, child's history of cough and diarrhoea morbidity, poor dietary diversity practice and stunting were significantly associated with anaemia at a P-value of 0⋅05. According to the multivariable logistic regression analysis, the odds of anaemia among children aged 6–11 months were 1⋅47 times more likely to compare with those aged 12–23 months (AOR 1⋅47; 95 % CI (1⋅06, 2⋅03)). Similarly, the odds of anaemia children among food insecure household were 1⋅44 times more likely to compare with those from food secure households (AOR 1⋅44 (1⋅28; 95 % CI (1⋅01, 2⋅04))). Having cough morbidity in the past 2 weeks before the survey (AOR 1⋅97; 95 % CI (1⋅28, 3⋅04)) and diarrhoea morbidity in the past 2 weeks before the survey (AOR 1⋅70; 95 % CI (1⋅18, 2⋅44)) were also associated with increased odds of anaemia. Higher odds of anaemia were observed among children who did not receive minimum dietary diversity (AOR 2⋅72; 95 % CI (1⋅96, 3⋅77)). Relative to not stunted children, increased odds of anaemia were observed among stunted children (AOR 1⋅88; 95 % CI (1⋅31, 2⋅70)) (Table 5).

Table 5. Factors associated with anaemia among children aged 6–23 months, agrarian community of Bale zone, South East, Ethiopia, 2021

ETB, Ethiopian Birr; HH, household; OR, odds ratio; CI, confidence interval, 1 = reference.

a Statistically significant association at P < 0⋅05.

Discussion

The study revealed that the prevalence of anaemia among children aged 6–23 was 47⋅9 %. According to the WHO classification, anaemia becomes a severe public health problem when the magnitude is above 40 % in certain population groups(28). Thus, the magnitude of anaemia in children 6–23 months in the study area was classified as a severe public health problem. A similar magnitude was reported in Deber Berhan town, North Shewa Ethiopia (47⋅5 %)(Reference Molla, Egata and Mesfin29), Damot Sore district, South Ethiopia (52⋅6 %)(Reference Malako, Teshome and Belachew30), Brazil (51 %)(Reference Leite, Cardoso and Coimbra31) and Romania (46 %)(Reference Stativa, Rus and Stanescu32). However, the finding was higher than the study conducted in Huaihua china (29⋅73 %)(Reference Huang, Jiang and Li33) and Northern Angola (44⋅4 %)(Reference Fançony, Soares and Lavinha34). The possible explanation for the variations in magnitude could be due to geographical and seasonal variations of risk factors and differences in the socio-economic status of the population. On the other hand, the prevalence of anaemia in children in this study is lower than the prevalence of the EDHS 2016 regional report for the Oromia region which was 66 %(16). The discrepancies may be due to variations in the data collection period and the change in access and utilisation of health services by subjects’ overtime. Moreover, the present study was conducted among agrarian communities while the EDHS data include both agrarian and pastoralist communities. People living in pastoralist communities commonly feed their children camel, cattle and goat milk which are known for inhibiting iron absorption(Reference Tassew, Tekle and Belachew35). The result of the present study is also lower than studies conducted in agro-ecological zones of rural Ethiopia (53⋅7 %)(Reference Roba, O'Connor and Belachew36), Wag-Himra zone in North Ethiopia (66⋅6 %)(Reference Woldie, Kebede and Tariku37), Egypt (66 %)(Reference Elalfy, Hamdy and Maksoud38) and rural Cameroon (66⋅7 %)(Reference Sop, Mananga and Tetanye39). The possible reason for this discrepancy could be due to differences in socio-economic status, place of residence and feeding practices. In addition, the lower occurrence of anaemia in the study area might be related to the lower prevalence of malaria.

Child age, household food security, having cough and diarrhoea morbidity 2 weeks before the study, dietary diversity practice and stunting were variables that have shown a significant association with childhood anaemia.

According to the present study, children aged 6–11 months had significantly higher odds of being anaemic as compared with children aged 12–23 months. The present study's finding is in line with other studies conducted in Somali region, Eastern Ethiopia(Reference Abdi Guled, Mamat and Balachew40). Kilte Awulaelo Woreda, Northern Ethiopia(Reference Terefe, Birhanu and Nigussie41), Hohoe Municipality, Ghana(Reference Khan, Awan and Misu42) and Bangladesh(43). This could be due to the inadequate iron supply by breast milk despite a high iron requirement to support the rapid body growth and development at this age(Reference Kotecha44). Moreover, the low iron containing plant-based monotonous foods feed to children of developing countries during the early stage of complementary feeding, may put them at higher risk of developing anaemia(Reference Campbell, Akhter and Sun45).

Household food insecurity, a condition in which household members lack access to adequate food because of limited resources, is another factor that showed significant association with anaemia. This finding is supported by similar studies conducted in Damot Sore District, Wolaita Zone, South Ethiopia(Reference Malako, Asamoah and Tadesse17), Wag-Himra zone North Ethiopia(Reference Woldie, Kebede and Tariku37) and Indonesia(Reference Gupta and Freedman46). This could be because children from food insecure households are less likely to get essential nutrients including iron and important micronutrients such as vitamin A and C, which are very important for the bioavailability of iron. In addition, household food insecurity has been associated with caregiver depression and anxiety, which interferes with caregiver practice and adversely impacts children's well-being(Reference Wang, Wang and Chang47).

Having diarrhoea and cough 2 weeks before the study were also significantly associated with anaemia. The finding is supported by studies done in the Wag-Himra zone, North Ethiopia(Reference Woldie, Kebede and Tariku37) Deber Berhan town, North Shewa Ethiopia(Reference Molla, Egata and Mesfin29) and Burmac(Reference Zhao, Zhang and Peng48). Several mechanisms can explain the higher odds of anaemia among children with infectious diseases. Infectious diseases can decrease intake and absorption of nutrients, cause intestinal mucosa injury and induce autoimmune reactions leading to anaemia.

Another factor that showed association with anaemia was dietary diversity practice. This is consistence with studies conducted in Damot Sore district, Southern Ethiopia(Reference Malako, Asamoah and Tadesse17) and China(Reference Wang, Wang and Chang47).

This could be because the more diversified a child's diet is, the larger the variety of nutrients he/she receives which enhances his/her health and nutrition. Increased dietary diversity is also associated with a higher likelihood of meeting children's recommended nutrient intake levels that may include important nutrients such as iron and other vitamins(Reference Moursi, Arimond and Dewey49). On the other hand, the negative association between anaemia and dietary diversity practice was observed in other studies(Reference Zhao, Zhang and Peng48).

Stunted children were more likely to be anaemic compared with children who were not stunted. This is in agreement with a study conducted in Damot Sore district, Southern Ethiopia(Reference Malako, Asamoah and Tadesse17), Dilla Town, Southern Ethiopia(Reference Jembere, Kabthymer and Deribew50), two agro-ecological zones of rural Ethiopia(Reference Roba, O'Connor and Belachew36) and Angola(Reference Fançony, Soares and Lavinha51). This could be because stunting is a consequence of malnutrition and it is a significant risk factor for anaemia. In addition, deficiencies of other micronutrients and stunting may synergistically increase the risk for anaemia.

The study has the following limitations. First, because of the cross-sectional nature of the design, a causal relationship cannot be established. Second, because the study only used haemoglobin values to determine anaemia status of children, a specific type of anaemia could not be determined. Third, recall and social desirability bias may also affect the IYCF and household food insecurity questionnaires.

Conclusion

Anaemia in children aged 6–23 months was a severe public health problem in the study area. Being in the age group of 6–11, being from a food insecure household, having cough and diarrhoea morbidity, poor dietary diversity practice and stunting was significantly associated with child anaemia. The most critical period in human life for IDA to develop is 6–23 months of age because the iron requirement reaches the highest during this period, i.e. almost ten times higher by body weight than adults. According to the WHO, in the absence of special intervention such as fortification and supplementation, the bioavailability of iron is often poor, especially in developing countries where child diet is predominately monotonous plant source. Therefore, we recommend the concerned bodies to plan integrated nutritional intervention strategies combined with iron fortification and supplementation for tackling anaemia in this critical stage of life.

Acknowledgements

We would like to acknowledge Jimma University for the support given to undertake this study. We also express our gratitude to our study participants who voluntarily participated in this study.

This study received no specific funding for this work.

M. T. conceived the study, carried out the statistical analysis, interpreted results, drafted the manuscript and coordinated the overall activity. K. H. worked on the analysis of data, on the interpretation of results and revising the manuscript. T. B. participated in data analysis, supervised all activities and reviewed the work critically. All the authors read this article.

We declare that there is no competing interest.

References

World Health Organization (WHO) (2011) Haemoglobin Concentrations for the Diagnosis of Anaemia and Assessment of Severity. Vitamin and Mineral Nutrition Information System. Document Reference WHO. Geneva, Switzerland: World Health Organization.Google Scholar
Black, RE, Victora, CG, Walker, SP, et al. (2013) Maternal and child undernutrition and overweight in low-income and middle-income countries. Lancet 382, 427451.CrossRefGoogle ScholarPubMed
McGuire, S (2015) World Health Organization. Comprehensive implementation plan on maternal, infant, and young child nutrition. Geneva, Switzerland, 2014. Adv Nutr 6, 134135. doi:10.3945/an.114.007781.CrossRefGoogle Scholar
Stevens, GA, Finucane, MM, De-Regil, LM, et al. (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. Lancet Glob Health 1, e16. doi:10.1016/S2214-109X(13)70001-9.CrossRefGoogle ScholarPubMed
The World Bank (2016) Prevalence of Anemia among Children (% of Children Under 5), World Development Indicators. World Bank, IBRD and IDA.Google Scholar
Allali, S, Brousse, V, Sacri, AS, et al. (2017) Anemia in children: prevalence, causes, diagnostic work-up, and long-term consequences. Expert Rev Hematol 10, 10231028. doi:10.1080/17474086.2017.1354696.CrossRefGoogle ScholarPubMed
Lopez, A, Cacoub, P, Macdougall, IC, et al. (2016) Iron deficiency anaemia. Lancet 387, 907916. doi:10.1016/S0140-6736(15)60865-0.CrossRefGoogle ScholarPubMed
WHO (2014) Global Nutrition Targets 2025: Anaemia Policy Brief (WHO/NMH/NHD/144). Geneva: World Health Organization.Google Scholar
Black, MM, Quigg, AM, Hurley, KM, et al. (2011) Iron deficiency and iron-deficiency anemia in the first two years of life: strategies to prevent loss of developmental potential. Nutr Rev 69, S64S70. doi:10.1111/j.1753-4887.2011.00435.x.CrossRefGoogle ScholarPubMed
Jayaweera, JAAS, Noordeen, F & Rayes, MLM (2016) Human metapneumovirus associated pneumonia and severe bronchiolitis in a 9-month-old infant admitted to a Sri Lankan hospital. SAJID 6, 5963.Google Scholar
Zimmermann, MB & Hurrell, RF (2007) Nutritional iron deficiency. Lancet 370, 511520.CrossRefGoogle ScholarPubMed
Victora, CG, Adair, L & Fall, C (2008) Maternal and child undernutrition: consequences for adult health and human capital. Lancet 371, 302302.CrossRefGoogle ScholarPubMed
Federal Democratic Republic of Ethiopia (2016) National Nutrition Program 2016–2020. Addis Ababa: Federal Democratic Republic of Ethiopia.Google Scholar
Misganaw, A, Haregu, TN, Deribe, K, et al. (2017) National mortality burden due to communicable, non-communicable, and other diseases in Ethiopia, 1990–2015: findings from the Global Burden of Disease Study 2015. Popul Health Metr 15, 29. doi:10.1186/s12963-017-0145-1.CrossRefGoogle ScholarPubMed
World Health Organization (WHO) (2001) Iron Deficiency Anaemia: Assessment. Prevention and Control. A Guide for Programme Managers. Geneva: World Health Organization.Google Scholar
Central Statistical Agency [Ethiopia] & ORC Macro (2016) Ethiopia Demographic and Health Survey. Addis Ababa: Central Statistical Agency and ORC Marco.Google Scholar
Malako, BG, Asamoah, BO, Tadesse, M, et al. (2019) Stunting and anemia among children 6–23 months old in Damot Sore district, southern Ethiopia. BMC Nutr 7, 3. doi:10.1186/s40795-018-0268-1.CrossRefGoogle Scholar
Belachew, A & Tewabe, T (2020) Under-five anemia and its associated factors with dietary diversity, food security, stunted, and deworming in Ethiopia. Syst Rev 9. doi:10.1186/s13643-020-01289-7.CrossRefGoogle ScholarPubMed
World Health Organization (2016 ) Guideline Daily Iron Supplementation in Infant and Children. Geneva: World Health Organization.Google Scholar
World Health Organization (2011) Haemoglobin Concentrations for the Diagnosis of Anaemia and Assessment of Severity. Geneva: World Health Organization.Google Scholar
Coates, J, Swindale, A & Bilinsky, P (2007) Household Food Insecurity Access Scale (HFIAS) for Measurement of Food Access: Indicator Guide Version 3. Washington, DC: FANTA, Academy for Educational Development.CrossRefGoogle Scholar
World Health Organization & United Nations Children Fund (2009) WHO. Child Growth Standards and the Identification of Severe Acute Malnutrition in Infants and Children: A Joint Statement by the World Health Organization and the United Nations Children's Fund. Geneva: World Health Organization.Google Scholar
World Health Organization (2010) Indicator for Assessing Infant and Young Child Feeding Practice: Part 2: Measurement. Geneva: WHO Press.Google Scholar
World Health Organization (2009) Diarrhoea: Why Children Are Still Dying and What Can Be Done. Geneva: World Health Organization.Google Scholar
Demographic E, (2016) Health Survey( EDHS), Key Indicators Report, Central Statistical Agency Addis Ababa Ethiopia. The DHS program ICF Rock Ville, Maryland, USA.Google Scholar
Van den Broeck, J, Willie, D & Younger, N (2009) Multivariate Data Analysis. A Global Perspective (Vol. 7).Google Scholar
Van den Broeck, J, Willie, D & Younger, N (2009) The World Health Organization child growth standards: expected implications for clinical and epidemiological research. Eur J Pediatr 168, 247. doi:10.1007/s00431-008-0796-9.CrossRefGoogle ScholarPubMed
United Nations Children's Fund (UNICEF), United Nations University (UNU) and World Health Organization (WHO) (2001) WHO: Iron Deficiency Anaemia: Assessment, Prevention, and Control. A Guide for Programme Managers. Geneva: UNICEF, UNU and WHO.Google Scholar
Molla, A, Egata, G, Mesfin, F, et al. (2020) Prevalence of anemia and associated factors among infants and young children aged 6–23 months in Debre Berhan Town, North Shewa, Ethiopia. J Nutr Metab 2020, 2956129. doi:10.1155/2020/2956129.CrossRefGoogle ScholarPubMed
Malako, BG, Teshome, MS & Belachew, T (2018) Anemia and associated factors among children aged 6–23 months in Damot Sore District, Wolaita Zone, South Ethiopia. BMC Hematol 18, 14. doi:10.1186/s12878-018-0108-1.CrossRefGoogle ScholarPubMed
Leite, MS, Cardoso, AM, Coimbra, CE Jr, et al. (2013) Prevalence of anemia and associated factors among indigenous children in Brazil: results from the first national survey of indigenous people's health and nutrition. Nutr J 12. doi:10.1186/1475-2891-12-69.CrossRefGoogle ScholarPubMed
Stativa, E, Rus, AV, Stanescu, A, et al. (2016) Prevalence and predictors of anaemia in Romanian infants 6–23 months old. J Public Heal (Oxf) 38, e272e281. doi:10.1093/pubmed/fdv145. Epublication 22 October 2015.CrossRefGoogle ScholarPubMed
Huang, Z, Jiang, FX, Li, J, et al. (2018) Prevalence and risk factors of anemia among children aged 6–23 months in Huaihua, Hunan Province. BMC Public Health 18, 126. doi:10.1186/s12889-018-6207.CrossRefGoogle ScholarPubMed
Fançony, C, Soares, Â, Lavinha, J, et al. (2020) Iron deficiency anaemia among 6-to-36-month children from northern Angola. BMC Pediatr 20, 2. doi:10.1186/s12887-020-02185-8.CrossRefGoogle ScholarPubMed
Tassew, AA, Tekle, DY, Belachew, AB, et al. (2019) Factors affecting feeding 6–23 months age children according to minimum acceptable diet in Ethiopia: a multilevel analysis of the Ethiopian demographic health survey. PLoS ONE 14, e0203098. doi:10.1371/journal.pone.020.CrossRefGoogle ScholarPubMed
Roba, KT, O'Connor, TP, Belachew, T, et al. (2016) Anemia and undernutrition among children aged 6–23 months in two agroecological zones of rural Ethiopia. Pediatr Health Med Ther 7, 131140. doi:10.2147/PHMT.S109574.CrossRefGoogle ScholarPubMed
Woldie, H, Kebede, Y & Tariku, A (2015) Factors associated with anemia among children aged 6–23 months attending growth monitoring at Tsitsika health center, Wag-Himra Zone, Northeast Ethiopia. J Nutr Metab 2015. doi:10.1155/2015/928632.CrossRefGoogle Scholar
Elalfy, MS, Hamdy, AM, Maksoud, SSA, et al. (2012) Pattern of milk feeding and family size as risk factors for iron deficiency anemia among poor Egyptian infants 6 to 24 months old. Nutr Res 32, 9399. doi:10.1016/j.nutres.2011.12.017.CrossRefGoogle ScholarPubMed
Sop, MMK, Mananga, MJ, Tetanye, E, et al. (2015) Risk factors of anemia among young children in rural Cameroon. Int J Curr Microbiol Appl Sci 4, 925935.Google Scholar
Abdi Guled, R, Mamat, NM, Balachew, T, et al. (2017) Predictors and prevalence of anemia, among children aged 6 to 59 months in Shebelle zone, Somali region, eastern Ethiopia: a cross sectional study. Int J Dev Res 7, 1118911196.Google Scholar
Terefe, B, Birhanu, A, Nigussie, P, et al. (2015) Effect of maternal iron deficiency anemia on the iron store of newborns in Ethiopia. Anemia 2015, 808204. doi:10.1155/2015/808204.CrossRefGoogle ScholarPubMed
Khan, JR, Awan, N & Misu, F (2016) Determinants of anemia among 6–59 months aged children in Bangladesh: evidence from nationally representative data. BMC Pediatr 16. doi:10.1186/s12887-015-0536-z.CrossRefGoogle ScholarPubMed
World Health Organization (2011) Serum Ferritin Concentrations for the Assessment of Iron Status and Iron Deficiency in Populations (No. WHO/NMH/NHD/MNM/11.2). Geneva: World Health Organization.Google Scholar
Kotecha, PV (2011) Nutritional anemia in young children with focus on Asia and India. Indian J Community Med 36, 8.CrossRefGoogle ScholarPubMed
Campbell, AA, Akhter, N, Sun, K, et al. (2011) Relationship of household food insecurity to anaemia in children aged 6–59 months among families in rural Indonesia. Ann Trop Paediatr 31, 321330.CrossRefGoogle ScholarPubMed
Gupta, NR & Freedman, DA (2021) Food security moderates relationship between perceived food environment and diet quality among adults in communities with low access to healthy food retail. Public Health Nutr 24, 29752986.CrossRefGoogle ScholarPubMed
Wang, J, Wang, H, Chang, S, et al. (2015) The influence of malnutrition and micronutrient status on anemic risk in children under 3 years old in poor areas in China. PLoS ONE 10, e0140840. doi:10.1371/journal.pone.0140840.Google ScholarPubMed
Zhao, A, Zhang, Y, Peng, Y, et al. (2012) Prevalence of anemia and its risk factors among children 6–36 months old in Burma. Am J Trop Med Hyg 87, 306. doi:10.4269/ajtmh.2012.11-0660.CrossRefGoogle ScholarPubMed
Moursi, MM, Arimond, M, Dewey, KG, et al. (2008) Dietary diversity is a good predictor of the micronutrient density of the diet of 6- to 23-month-old children in Madagascar. J Nutr 138, 24. doi:10.3945/jn.108.093971.CrossRefGoogle ScholarPubMed
Jembere, M, Kabthymer, RH & Deribew, A (2020) Determinants of anemia among children aged 6 to 59 months in Dilla town, southern Ethiopia: a facility based case control study. Glob Pediatr Health 20, 7. doi:10.1177/2333794X20974232.Google Scholar
Fançony, C, Soares, Â, Lavinha, J, et al. (2020) Iron deficiency anaemia among 6- to 36-month children from northern Angola. BMC Pediatr 20, 2. doi:10.1186/s12887-020-02185-8.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Socio-demographic and economic status of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021 (n 707)

Figure 1

Table 2. Maternal and child health-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021(n 707)

Figure 2

Table 3. Child feeding practice-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021

Figure 3

Table 4. Water source sanitation and hygienic-related characteristics of respondents in agrarian community of Bale zone, South East, Ethiopia, 2021

Figure 4

Fig. 1. Prevalence of anaemia among children age 6–23 months in agrarian community of Bale zone, South East, Ethiopia, 2021.

Figure 5

Table 5. Factors associated with anaemia among children aged 6–23 months, agrarian community of Bale zone, South East, Ethiopia, 2021