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  • Research article
  • Open Access
  • Schistosoma mansoni infection and undernutrition among school age children in Fincha’a sugar estate, rural part of West Ethiopia

    • 1Email author,
    • 1,
    • 1 and
    • 2
    BMC Research Notes20147:763

    https://doi.org/10.1186/1756-0500-7-763

    • Received: 6 January 2014
    • Accepted: 14 October 2014
    • Published:

    Abstract

    Background

    Parasitic infection like schistosomiasis is known to exert a negative effect on nutritional status of school-aged children. However, studies associating parasitic infections with undernutrition are scarce. Thus, this study was primarily to document the association between Schistosoma mansoni infection and undernutrition among school-aged children in a rural setting of Fincha’a Sugar Estate, Ethiopia.

    Methods

    A cross-sectional study was conducted on a total of 453 school-aged children (5-18 years). Stool specimen was collected and examined using the standard Kato-katz technique. Children’s height-for-Age Z-score (HAZ) and Body mass index-for-Age Z- score (BAZ) was determined. Z-Scores for each nutritional index were compared with the WHO child growth standards reference values. Children were considered stunted or wasted as HAZ or BAZ falls below -2 standard deviations, respectively.

    Result

    The overall prevalence of Schistosoma mansoni infection was 53.2%. Out of the total school children examined, 11.5% and 13.2% were stunted and wasted, respectively. Multivariate logistic regression analysis was done to determine the relationship between Schistosoma mansoni infection and nutritional status controlling for other factors. Accordingly, stunting was not significantly associated while wasting was negatively associated with Schistosoma mansoni infection. Paternal occupation was the best predictor of stunting and wasting such that, unemployed fathers have 4.28 (95% CI; 2.13, 8.63) (p < 0.001) and 3.83, 95% CI; 1.89, 7.79) (p < 0.001) chance of having stunted and wasted children, respectively.

    Conclusion

    Schistosoma mansoni infection is highly prevalent in the study area. The high prevalence of wasting, and moderate level of stunting among study subjects in this study area indicate that they are affected by both infection and undernutrition. Therefore, regular preventive chemotherapy against S. mansoni and other control measures are recommended. Moreover, possibilities of synchronized nutritional rehabilitation and creation of employment opportunities to the families should be looked for.

    Keywords

    • Schistosoma mansoni
    • Under nutrition
    • Stunting
    • Wasting
    • School children
    • Ethiopia

    Background

    In the past, nutrition and health of school-aged children and adolescents in the developing world received little attention relative to those less than five years of age. However, there is increasing evidence, resulting in international concern, that the high level of nutritional deprivation combined with the heavy burden of disease in school age group has negative consequences for a child’s long term overall development. This has prompted an increased focus on the diverse needs of the school-aged child [13].

    Recent studies on school-aged children have shed new information on stunting, wasting and underweight for this age group [46]. Currently, about one-fourth of African primary school children lie under the fifth centile of United States- National Center for Health Statistics (US-NCHS) reference for Height-for-Age Z-score (HAZ). While undernutrition prevalence has decreased significantly in most other developing countries in the last few years, it has been nearly static for sub-Sahara Africa [7].

    While factors affecting growth and development of preschool children are well-documented, the factors influencing growth of school-aged children are not as such clearly elucidated [8, 9]. One of the factors emphasized in the 1993 World Bank report was the relationship between parasitic infection and undernutrition [10]. Moreover, the relationship between undernutrition and soil transmitted helminth infection has been well established [1113], but such studies have been limited only to soil transmitted helminth infections in children [1417].

    However, the relationship between undernutrition and schistosomiasis is now gaining more attention. There are few studies which associate the different species of schistosoma with linear growth retardation in children [5, 18, 19]. This parasitic infection is known to exert a negative effect on the nutritional status of school-aged children even at a low to moderate intensity of infection [20, 21]. Such studies are limited in developing countries like Ethiopia, where schistosomiasis is endemic. The aim of this study was, therefore, to investigate the association between S. mansoni infections and prevalence levels of undernutrition, and related associated risk factors influencing this relationship among school-aged children in a rural setting of Fincha’a Sugar Estate, Western Ethiopia.

    Methods

    Study area and population

    A cross-sectional study was conducted from February - March, 2011 among school-aged children (5-18 years) residing in a rural village of Fincha’a Sugar Estate in Horo Guduru Wollega, western Ethiopia. Fincha’a Sugar Estate is found in Oromia regional government and located at 350 km west of Addis Ababa (Capital of Ethiopia). Fincha’a valley is bounded by escarpments from east, west and south situated at a latitude of 9° 30′N to 10° 60′N and a longitude of 37° 15′ to 37° 30′E. The area is characterized by a semi-arid type climate having the mean maximum and mean minimum temperatures of 30.6°C and 14.5°C, respectively. It is situated 1,350 m -1,600 m above sea level with mean relative humidity of 62% and receiving mean annual precipitation of 1,485 mm. The population comprises of different ethnic groups that settled at different times in search of job opportunities. The total population of the area is estimated to be over 18,000 according to the 2007 population census, with male/female ratio of approximately 1.1:1.0 [22]. All kind of basic health services were provided by one health center and 5 small clinics to all communities residing in the sugar farm (camp) across the different villages.

    The Fincha’a Sugar Estate was selected purposively as the area is a focus of S. mansoni infections due to its favorable environment (sugarcane cultivation and availability of a special watershed of the hydropower dam reservoir). The sugar factory was organized into 5 farm villages (Village A, B, C, D, and E) and two small towns (Agamsa and Kuyisa). From a total of 5 villages in the area, two (village ‘A’ and ‘E’) were selected using lottery method for this study (Figure 1). The sample size was determined assuming a confidence interval of 95% and a 60% prevalence of S. mansoni in the study area. A sample size of 458 was considered to be adequate, of which 453 students (242 from village ‘A’ and 211 from village ‘E’) participated after the sample size was proportionally distributed over the two villages based on the total households in each of the two villages. Then, one child from each randomly selected household was recruited using simple random sampling technique for inclusion in the study. The variables used for inclusions were age range of 5-18 years, lived primarily in the study village at least for the last two years, provided both child assent and parental consent and being asymptomatic for other diseases at the time of data collection.
    Figure 1
    Figure 1

    Map of study villages within Fincha’a sugar factory, West Ethiopia. [Source: MSc document (Bayissa Chala), AAU, 2007].

    Socio-economic data

    Data on socio-demographic data such as age, sex, parental and maternal educational status and occupational status was obtained by interviewing parents and legal guardians guided by pre-tested structured questionnaire. Data on socio-economic status addressing household durable assets (radio, television, bicycle, mobile phone etc), three components of dwelling structure (roof, floor and wall type) and number of rooms for dwelling were assessed. Questions dealing with household asset index were adopted from Ethiopia demographic and health survey 2005 [23]. A household wealth index was constructed from 20 variables using principal component analysis. Commonly used arbitrary cut-off points were applied to classify children as the lowest 40% of the socio-economic status score into ‘poor’ , the highest 20% as ‘rich’ and the rest as the ‘middle’ group [24].

    Stool examination

    Standard Kato-katz cellophane faecal thick smear method (41.7 mg template) was utilized to examine three consecutive days stool specimen for the presence of Schistosoma mansoni, Ascaris lumbricoides, Trichuris trichiura and hookworm infection. Microscopic examination was done within 30-60 min of smear preparation not to miss hookworm infection since the sensitivity of Kato-katz techniques to detect hookworm decreases after an hour [25]. The mean intensity of infection was expressed as eggs per gram (epg) and classified according to World Health Organization (WHO) criteria as low (1-99 epg), moderate (100-399 epg), and heavy (≥400 epg) intensity infection [26].

    Anthropometric measures

    Body weight with light clothing was measured to the nearest 0.1 kg on a Seca Model 880 Digital scale (Hanover, MD, Germany). Height was measured barefooted to the nearest 0.1 cm using a portable stadiometer that was taped to a wall at the same location for each measurement. Height-for-Age Z-score (HAZ) and Body mass index for-Age Z-score (BAZ) were based on the WHO child growth standards. Body mass index (BMI) is the index of choice for the assessment of recent under-nutrition in both adults and adolescents [27]. Stunting was defined as HAZ < -2 standard deviations (SDs) and wasting or wasted if BAZ < -2 SDs compared with a normal, healthy reference population. As part of data quality assurance, in addition to test-retest and inter-rater reliability assessments, all anthropometric measurements were taken with calibrated and validated instruments.

    Age of each participant was collected from the mother and counter checked using vaccination cards, baptismal certificates or other forms of informal recording. When these recordings were not available, a calendar of locally important events was used. The 15th day of the month was used when the date of birth is unknown and if the month of birth is unknown, the midpoint of the year of birth was used.

    Data processing

    Data were coded and entered into SPSS for windows version 17 statistical software package for analysis of variables after being checked for completeness and cleaned of any inconsistencies. Simple frequency and percentages were used as the statistical parameter in the descriptive analysis. Bivariate logistic regression was used to identify predictors for under-nutrition. Multivariate logistic regression analysis was used to provide independent estimates of the relationships of interest. P <0.05 was considered significant.

    Ethical consideration

    Ethical clearance was obtained from Ethical Clearance Committee of Jimma University. The study participants involved in the study after informed written consent was obtained from their parents or guardians and assent from participating children. Children positive for S. mansoni have received single dose of praziquantel (Biltricide®, Bayer AG, Germany), 40 mg/kg body weight according to standard treatment guideline of Ethiopia (2010) and study participants identified as stunted and wasted were referred to Fincha’a sugar estate health center for necessary interventions.

    Results

    A total of 458 children between 5-18 years of age were recruited in the study. Complete parasitological results were available for 453 (98.9%), as 5 were withdrawn since they were unfit to the inclusion criteria. Out of the total study participants 216 (47.7%) were males and 237 (52.3%) were females. Most of the study participants (62.7%) belongs to the age group 10-14 followed by 25.6% in the age group 5-9 (Table 1). The mean HAZ and BAZ were -0.69 ± 1.13 SD and -0.83 ± 0.96 SD, respectively. The overall prevalence of stunting was 11.5% and 13.2% were wasted. The overall prevalence of S. mansoni infection was 53.2% with a mean ± SD intensity of 358 ± 477 epg. The infection intensity was light in 21.4%, moderate in 15.7% and heavy in 16.1% of the participants. Soil transmitted helminthes were not detected in any of the study participants.
    Table 1

    Socio-demographic characteristics of school age children, Fincha’a Sugar Estate, Horo Guduru Wollega, Ethiopia, Feb-Mar, 2011

    Socio-demographic variables

    Frequency

    Total

    n (%)

    n (%)

    Gender

    Male

    216 (47.7)

    453 (100)

    Female

    237 (52.3)

    Age group

    5-9

    116 (25.6)

    453 (100)

    10-14

    284 (62.7)

    15-18

    53 (11.7)

    Maternal literacy

    Illiterate

    338 (74.6)

    453 (100)

    Literate

    115 (25.4)

    Paternal literacy

    Illiterate

    321 (70.8)

    453 (100)

    Literate

    132 (29.2)

    Maternal occupation

    Unemployed

    395 (87.2)

    453 (100)

    Employed

    58 (12.8)

    Paternal occupation

    Unemployed

    48 (10.6)

    453 (100)

    Employed

    405 (89.4)

    Total

    453 (100)

    Stunting and Schistosoma mansoni infection

    Bivariate logistic regression analysis showed that, stunting was not associated with S. mansoni infection. However, it was related with mother’s literacy and father’s occupational status. Accordingly, children born from illiterate mothers were about 3 times (95% CI; 1.19, 6.89) more likely to be stunted (p = 0.02) than their counterparts. Children of unemployed fathers had about 5 times (95% CI; 2.49, 9.86) higher risk of being stunted (p <0.001) than children of employed fathers (Table 2).
    Table 2

    Bivariate and multivariate logistic regression analysis of factors associated with stunting amongst school age children residing in Fincha’a Sugar Estate, Horo Guduru Wollega, Ethiopia, Feb-Mar, 2011

    Variables

    Stunted

    Normal

    COR

    P-value

    AOR

    P-value

    n (%)

    n (%)

    (95% CI)

    (95% CI)

    Gender

    Female

    23 (9.7)

    214 (90.3)

    1.00

     

    1.00

     

    Male

    29 (13.4)

    187 (86.6)

    1.44 (0.81, 2.58)

    0.22

    1.25 (0.69, 2.29)

    0.46

    Age group

    5 – 9

    12 (10.3)

    104 (89.7)

    1

     

    -

     

    10 – 14

    30 (10.6)

    254 (89.4)

    1.02 (0.51, 2.08)

    0.95

    -

     

    15 – 18

    10 (18.9)

    43 (81.1)

    2.02 (0.81, 5.01)

    0.13

    -

     

    S. mansoni

    Uninfected

    26 (12.3)

    186 (87.7)

    1.00

     

    -

     

    Infected

    26 (10.8)

    215 (89.2)

    0.86 (0.48, 1.54)

    0.62

    -

     

    SES Index

    Poor

    21 (11.6)

    160 (88.4)

    1.00

     

    -

     

    Middle

    23 (12.7)

    158 (87.3)

    1.12 (0.59, 2.09)

    0.75

    -

     

    Rich

    8 (8.8)

    83 (91.2)

    0.73 (0.31, 1.73)

    0.48

    -

     

    Maternal literacy

    Literate

    6 (5.2)

    109 (94.8)

    1.00

     

    1.00

     

    Illiterate

    46 (13.6)

    292 (86.4)

    2.86 (1.19, 6.89)

    0.02

    2.30 (0.94, 5.63)

    0.07

    Paternal literacy

    Literate

    16 (12.0)

    117 (88.0)

    1.00

     

    -

     

    Illiterate

    36 (11.2)

    284 (88.8)

    0.93 (0.49, 1.74)

    0.81

    -

     

    Maternal occupation

    Employed

    5 (8.6)

    53 (91.4)

    1.00

     

    -

     

    Unemployed

    47 (11.9)

    348 (88.1)

    1.43 (0.55, 3.76)

    0.47

    -

     

    Paternal occupation

    Employed

    37 (9.1)

    368 (90.9)

    1.00

     

    1.00

     

    Unemployed

    15 (31.2)

    33 (68.8)

    4.96 (2.49, 9.86)

    <0.001

    4.28 (2.13, 8.63)

    < 0.001

    Total

    52

    401

     

    Multivariate logistic regression analysis was conducted to fit into a model including all variables with a P-value <0.25 in the bivariate analysis for stunting. Therefore, gender, age group of the study participants, mother’s educational status and paternal occupation were included in the model for analysis. Controlling for other factors, paternal employment was the best predictor of stunting among school-age children such that, unemployed fathers have about 4 times (95% CI; 2.13, 8.63) more chance of having stunted children (p < 0.001) (Table 2).

    Wasting and Schistosoma mansoni infection

    Wasting was significantly associated with S. mansoni infection. Overall, S. mansoni infected children were 0.45 times (95% CI; 0.25, 0.81) less likely to be wasted (Table 3), where as children with light infection (21.4%) were about 2 times less likely to be wasted than uninfected children (p = 0.01). Wasting was also associated with gender, maternal literacy and paternal occupation. Males were 2.69 times (95% CI; 1.51, 4.79) more likely to be wasted than their female counters (p = 0.001). Children born from illiterate mothers were about 4 times (95% CI; 1.67, 10.96) more likely to be wasted than children born from literate mothers (p = 0.002). Likewise, children born from unemployed fathers were about 4 times (95% CI; 2.29, 8.69) more likely to be wasted than their counter parts (p <0.0001). Controlling for other factors, the AOR indicates that father’s employment status is the best predictor of wasting among school age children (AOR = 3.83, 95% CI; 1.89, 7.79) (p < 0.001).
    Table 3

    Bivariate and multivariate logistic regression analysis of factors associated with wasting amongst school age children residing in Fincha’a Sugar Estate, Horo Guduru Wollega, Ethiopia, Feb-Mar, 2011

    Variables

    Wasted

    Normal

    COR

    P-value

    AOR

    P-value

    n (%)

    n (%)

    (95% CI)

    (95% CI)

    Gender

     

    Female

    19 (8.0)

    218 (91.0)

    1.00

     

    1.00

     

    Male

    41 (19.0)

    175 (81.0)

    2.69 (1.51, 4.79)

    0.001

    2.18 (1.19, 3.96)

    0.01

    Age group

    5 – 9

    11 (9.5)

    105 (90.5)

    1.00

     

    -

     

    10 – 14

    38 (13.4)

    246 (86.6)

    1.29 (0.65, 2.59)

    0.46

    -

     

    15 – 18

    11 (20.7)

    42 (79.3)

    2.27 (0.93, 5.55)

    0.07

    -

     

    S. mansoni

    Uninfected

    38 (17.9)

    174 (82.1)

    1.00

     

    1.00

     

    Infected

    22 (9.1)

    219 (90.9)

    0.46 (0.26, 0.81)

    0.01

    0.45 (0.25, 0.81)

    0.00

    SES Index

    Poor

    25 (13.8)

    156 (86.2)

    1.00

     

    -

     

    Middle

    20 (11.0)

    161 (89.0)

    0.78 (0.41, 1.45)

    0.43

    -

     

    Rich

    15 (16.5)

    76 (83.5)

    1.23 (0.61, 2.47)

    0.56

    -

     

    Maternal Literacy

    Literate

    5 (4.3)

    110 (95.7)

    1.00

     

    1.00

     

    Illiterate

    55 (16.3)

    283 (83.7)

    4.28 (1.67, 10.96)

    0.002

    3.56 (1.36, 9.30)

    0.01

    Paternal literacy

    Literate

    15 (11.3)

    118 (88.7)

    1.00

     

    -

     

    Illiterate

    45 (14.2)

    272 (85.8)

    1.29 (0.69, 2.40)

    0.43

    -

     

    Maternal occupation

    Employed

    5 (8.6)

    53 (91.4)

    1.00

     

    -

     

    Unemployed

    55 (13.9)

    340 (86.1)

    1.72 (0.66, 4.48)

    0.27

    -

     

    Paternal occupation

    Employed

    43 (10.6)

    361 (89.4)

    1.00

     

    1.00

     

    Unemployed

    17 (34.7)

    32 (65.3)

    4.46 (2.29, 8.69)

    0.00

    3.83 (1.89, 7.79)

    0.00

    Total

    60

    393

        

    Discussion

    Undernutrition continues to be a major health burden in developing countries. Since parasitic infections cause anorexia and poor absorption of nutrients and promote the deviation of nutrients to the organism's defense mechanisms, they contribute to the onset or exacerbation of weight and height deficits [28, 29]. Previous cross-sectional studies have reported clear relationship between S. mansoni infection and nutritional status.

    The mean HAZ and BAZ were below zero indicating that the distribution was shifted downwards [30]. The overall prevalence of stunted and wasted school-aged children in Fincha’a Sugar Estate was 11.5% which is considered low (<20%) according to the WHO classification [30]. Similarly, the prevalence of wasting was 13.2%, which is considered high (10-14%).

    When these figures were compared with other study, stunting was almost 1/3 of the prevalence reported among school-aged children of Peru [31]. This could be attributed to the difference in transmission of geo-helminth in the two study areas. In our study, STH infection was not detected from any of the participants. However, 86% of the children from Peru were infected with at least one helminth and these may also have had an impact on nutritional status and contributed to high prevalence of stunting. Previously, it has been established that soil transmitted helminth infections are associated with stunting in pre-school and school children [32, 33]. The prevalence of wasting on the other hand was comparable with this study. This could be due to wasting being an indicator of acute nutritional insult might not be affected by intestinal parasites. This has been confirmed by significant negative relation between intestinal helminth infections and children’s growth in a study carried out in São Paulo, Brazil [17].

    The prevalence of S. mansoni infection was 53.2% which is considered a high prevalence according to WHO classification of prevalence of S. mansoni[34]. Stunting was not statistically associated with S. mansoni infection. This was not the case in a previous cross-sectional study in the northeastern Brazilian town of Nazaré, Bahia [35]. In this study, children infected with S. mansoni were significantly more malnourished than children with a negative stool sample for several anthropometric variables. The reason for this contradicting finding could be due to difference in transmission of geo-helminthes. The study population in Brazil was highly infected with soil transmitted helminthes (STHs). The prevalence of Ascaris lumbricoides and Trichuris trichiura infections among those children were 71.8 and 67.9%, respectively. However, in our case none of the STHs were detected in stool examination. One major reason for the absence of STHs in our study area could be the regular administration of anti-helminthic (mass chemotherapy) to children at the beginning of every school year according the source of the Fincha’a health center authorities.

    It has been reported that intestinal helminthiasis may play a contributory role in the occurrence of childhood malnutrition [29, 36, 37]. One reason why our reports contradicts with the finding of the Brazil study might be that in endemic areas where more than one species of parasite prevails and that the interaction of these parasites with each other may modulate or change the parasite nutritional status relationships. Hence, we presume that a synergistic effect of STH and S. mansoni infection could be accountable for the nutritional deficit. Furthermore, the nutritional status of our participants might have been boosted by subsequent treatments.

    In contrary to stunting S. mansoni was associated with wasting. However, the relation was surprising that infected children were less likely to be wasted than their uninfected counterparts. Wasting indicates recent nutritional condition and is generally associated with recent illness and failure to gain weight or a loss of weight [38]. S. mansoni infection, on the other hand, is a chronic disease and it’s relation with undernutrition is better explained by stunting. Therefore, we assumed long-term linear growth retardation might have relative protection of weight and height based indices (BAZ). Similar scenario has been reported in Philippines [39].

    Our results on socio-economic status showed that Father’s occupation was the best predictor of both stunting and wasting among school age children. Similar study conducted in India indicated that the poor nutritional status was associated with socioeconomic variables such as sex of the child and father’s occupation [40]. In contrast to this, the study conducted in Peru and Peruvian Andes showed that father’s engagement on any type of occupation did not have differential impact on child undernutrition [41].

    Moreover, the results of the study indicated that there seemed a conflicting relationship between SES of no association and paternal employment as a predictor of stunting/wasting. Although, most of the time wealth index is taken as proxy to employment, this conflicting relationship could be justified as 1) paternal employment might not necessarily be reliable indicator for wealth index in the study area and 2) most of the time, people do not disclose genuine enough information on their SES.

    Our finding of maternal literacy as an associated factor with wasting is in line with the findings of several other studies conducted in India [40], Pakistan [42] Bolivia [43] Kenya [44] and Jamaica [45] which indicated that uneducated mothers were likely to have malnourished children than those educated. In contrast to the above findings, study conducted by Mazumdar in Egypt did not find any significant relationship between long-run child undernutrition indicator (stunting) and maternal education [46]. However, as undernutrition is the product of the interaction of many factors and confounded by those factors [38], it is difficult to reach on conclusive comparison on similarity and differences among different studies including the present study.

    Limitation of the study

    We acknowledge inaccuracy of the age of the included children (for some of our study subjects) due to lack of birth certificates and recall bias that can be considered as one of the limitation of this study. Moreover, we use only BMI which depends upon weight and the square of height, it ignores basic scaling laws whereby mass increases to the 3rd power of linear dimensions. Lastly we admit the effect of the study design as well.

    Conclusion

    The high prevalence of S. mansoni infection and wasting, moderate level of stunting, and observed significant association mean that school children in these schistosomiasis endemic areas were affected by both infection and undernutrition. Therefore, regular screening and provision of mass treatment (preventive chemotherapy) against S. mansoni infections with other control measures are recommended. Moreover, possibilities of synchronized nutritional rehabilitation and creation of employment opportunities to the family of the child should be looked for.

    Abbreviations

    HAZ: 

    Height-for-Age Z-score

    BAZ: 

    Body mass index for-Age Z-score

    BMI: 

    Body mass index

    SD: 

    Standard deviations

    AOR: 

    Adjusted odds ratio

    epg: 

    Eggs per gram.

    Declarations

    Acknowledgements

    We thank Jimma University Postgraduate School and VLIR-JU/IUC project for supporting the study financially. We are also very grateful to Fincha’a Sugar Estate factory managements and community representatives of the villages. Our gratitude also extends to the study participants who voluntarily participated in the study.

    This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

    Authors’ Affiliations

    (1)
    Department of Medical Laboratory Sciences and Pathology, College of Public Health and Medical Sciences, Jimma University, P.O. Box 378, Jimma, Ethiopia
    (2)
    Department of Pharmacy, College of Public Health and Medical Sciences, Jimma University, P.O. Box 378, Jimma, Ethiopia

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