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Seroepidemiological study of livestock brucellosis in a pastoral region

Published online by Cambridge University Press:  27 July 2011

B. MEGERSA ,
D. BIFFA ,
F. ABUNNA ,
A. REGASSA ,
J. GODFROID  and
E. SKJERVE
B. MEGERSA*
Affiliation:
School of Veterinary Medicine, Hawassa University, Hawassa, Ethiopia Centre for Epidemiology and Biostatistics, Norwegian School of Veterinary Science, Oslo, Norway
D. BIFFA
Affiliation:
School of Veterinary Medicine, Hawassa University, Hawassa, Ethiopia Centre for Epidemiology and Biostatistics, Norwegian School of Veterinary Science, Oslo, Norway
F. ABUNNA
Affiliation:
School of Veterinary Medicine, Hawassa University, Hawassa, Ethiopia
A. REGASSA
Affiliation:
School of Veterinary Medicine, Hawassa University, Hawassa, Ethiopia
J. GODFROID
Affiliation:
Section of Arctic Medicine, Norwegian School of Veterinary Science, Tromsø, Norway
E. SKJERVE
Affiliation:
Centre for Epidemiology and Biostatistics, Norwegian School of Veterinary Science, Oslo, Norway
*
*Author for correspondence: Dr B. Megersa, Center for Epidemiology and Biostatistics, Norwegian School of Veterinary Science, PO Box 8146 Dep., 0033 Oslo, Norway. (Email: bekelebati@yahoo.com)
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Summary

A seroepidemiological study of Brucella infections in multiple livestock species in the Borana pastoral system of Ethiopia was performed between December 2007 and October 2008. A cross-sectional multi-stage sampling technique was employed to select 575 cattle, 1073 camels and 1248 goats from the target populations. Sera were collected from the animals, and serially tested using Rose Bengal test and complement fixation test. Overall prevalence and prevalence with respect to explanatory variables were established, and potential risk factors for seropositivity were analysed using a multivariable logistic regression. The results showed that 8·0% (95% CI 6·0–10·6), 1·8% (95% CI 1·1–2·8) and 1·6% (95% CI 1·0–2·5) of the tested cattle, camels and goats, respectively, had antibodies to Brucella antigen. Positive reactors were found in 93·8% of the villages with more frequent detection of positive cattle (93·3%) than camels (56·3%) and goats (37·5%). Risk factors identified for cattle were: keeping more livestock species at household level (OR 4·1, 95% CI 1·9–8·9), increasing age of the animal (OR 2·8, 95% CI 1·3–6·0) and wet season (OR 3·3, 95% CI 1·6–6·9). Increase in household-level species composition (OR 4·1, 95% CI 1·2–14·2) and wet season (OR 3·7, 95% CI 1·5–9·1) were found to be risk factors for seropositivity in camels and goats, respectively. Existence of more than one seroreactor animal species in most villages and association of increased livestock species composition with seropositivity may add more credence to the possibility of cross-species transmission of Brucella infections. Although no attempt to isolate Brucella spp. was made, our results suggest that cattle are more likely maintenance hosts of Brucella abortus which has spread to goats and camels. This should be substantiated by further isolation and identification of Brucella organisms to trace the source of infection and transmission dynamics in various hosts kept under mixed conditions. In conclusion, the present study suggests the need for investigating a feasible control intervention and raising public awareness on prevention methods of human exposure to brucellosis.

Keywords

BrucellosisEthiopialivestockpastoral systemprevalencerisk factors
Type
Original Papers
Information
Epidemiology & Infection , Volume 140 , Issue 5 , May 2012 , pp. 887 - 896
Copyright
Copyright © Cambridge University Press 2011

INTRODUCTION

Brucellosis is one of the most widespread zoonoses, mainly caused by Brucella abortus, B. melitensis or B. suis, and is transmitted to people from various animal species. The economic and public health impacts of the disease remain of particular concern in developing countries. It poses a barrier to trade of animals and animal products, and can seriously impair socioeconomic development of livestock owners [1]. Many developing countries with limited resources, including Ethiopia, are concerned with other priority diseases that are more significant and have not yet fully introduced programmes featuring any aspects of brucellosis intervention. The epidemiology of the disease in livestock and humans, and cost-effective prevention measures are not well understood, particularly in sub-Saharan countries [Reference McDermott and Arimi2]. Brucellosis is known to cause abortion in livestock with the subsequent excretion of a large number of organisms which are easily acquired by other animals. Hence, it remains endemic and continues to be a major public and animal health problem in this region of the world [Reference Godfroid3].

Antibodies against Brucella spp. have been detected in various domestic animals in Ethiopia, with large disparities between various regions, production systems, livestock species and time periods as generally seen in sub-Saharan Africa [Reference McDermott and Arimi2]. Seroprevalence records predominantly document cattle [Reference Berhe, Belihu and Asfaw4Reference Ibrahim8], and there are few investigations on camels [Reference Teshome, Molla and Tibbo9, Reference Megersa, Molla and Yigezu10] and small ruminants [Reference Teshale11, Reference Ashenafi12]. Despite the widespread distribution of brucellosis in animals and the close contact between humans and animals, only sparse published information is available regarding the zoonotic transmission of brucellosis in Ethiopia [Reference Kassahun13, Reference Regassa14]. So far, isolation and characterization of Brucella spp. has never been attempted in Ethiopia and all available reports are based on serological evidence. One marked limitation of brucellosis serology is that the tests used worldwide detect antibodies directed against epitopes associated with the smooth lipopolysaccharide (s-LPS) which is shared to a great extent by the different smooth Brucella spp. Thus, it is not possible to ascribe which Brucella spp. (B. abortus, B. melitensis, B. suis) induces antibodies in a given animal species. There are also other cross-reacting organisms that have been extensively reviewed by Corbel [Reference Corbel15]. Therefore, in the absence of isolation of Brucella spp., additional information is needed in order to describe brucellosis epidemiology in husbandry systems in which several animal species, susceptible to different Brucella spp. are maintained together.

Animal brucellosis constitutes significant public health importance for a pastoral community where close intimacy with animals, raw milk consumption and low awareness on zoonoses facilitate zoonotic transmission of the disease. Milk is a major staple food, and is an important source of protein and vitamins for households. Raw milk, which is the mode by which almost all the pastoral community consume it, is also a source of infection with milk-borne zoonoses such as brucellosis [Reference Schelling16]. The overall infection risk is also influenced by the pattern of Brucella spp. present; as B. melitensis often represents a more serious public health hazard than B. abortus [1]. To date, the occurrence of brucellosis has not been investigated in different livestock species sharing common ecozone and management under a pastoral setting in Ethiopia. The present study therefore aimed at investigating the epidemiological situations of brucellosis in the major livestock species kept together in the Borana pastoral system of Ethiopia.

MATERIALS AND METHODS

Study area

The study was conducted in Borana pastoral area, Oromia Regional state of Ethiopia. Generally, the Borana plateau represents a lowland area where altitude gently slopes from North (1650 m a.s.1.) to South (1000 m a.s1.). The area has a bimodal rain pattern with annual average precipitation ranging from 300 mm to 700 mm. The main rainy season (65% of precipitation) extends from March to May, and a minor rainy season is between mid-September and mid-November. The main dry season extends from December to February [Reference Coppock17]. As surface water is very scarce in the area, deep wells, shallow ponds, and large machine-excavated ponds are important sources of water for both livestock and humans. Traditional wells are owned by clans while large ponds are communal and often responsible for aggregation of large numbers of animals at the water points.

The livestock production system is predominantly extensive, where animals are allowed to forage freely during day time and kept in open enclosures during the night. The major livestock species kept by households in Borana include cattle, goats, camels and sheep [Reference Solomon, Snyman and Smit18]. These livestock species share common grazing areas and watering points, and probably intermingle at villages although separate enclosures are used for each species. Mobile herds are often maintained together with five or more village herds to reduce labour demand, a condition which facilitates transmission of the disease from infected to susceptible herds.

The pastoral village, Olla in Borana, is characterized by the clustering of households with close proximity of houses in a pastoral camp. Each village we visited, varying in size between 7 and 20 households, is traditionally administered by a village chief, Abba Olla, who is an important contact person in facilitating cooperation between livestock owners. Keeping multiple livestock species and seasonal herd mobility are part of the dynamic nature of the pastoral production system. Livestock constitute the principal source of livelihood for Borana households. Nearly 70% of household cash revenues come from pastoral sources, mainly from livestock sales with sales from dairy products constituting only a small proportion [Reference Coppock17].

Study design and sample size determination

The study was performed between December 2007 and October 2008. Administratively, the Borana zone is subdivided into districts, pastoral associations (PA) and villages. Yabello district was selected for convenience, considering its livestock species diversity, spatial distribution patterns of ethnic groups, existence of laboratory facilities and its central geographical location in the zone. This study involved a cross-sectional multistage sampling technique. Selection of six out of 18 PAs in Yabello, and 16 villages from a total of 80 villages was based on random sampling. However, in some cases restrictions on selection were imposed, based on the accessibility of the villages by vehicle, the proximity to roads, and the presence of the three livestock species. Briefly, a total of 37 villages with the three livestock species were listed and used as a sampling frame. Taking the minimum number of each animal species to be sampled from each village into account, it was feasible to randomly sample about half of the eligible villages. Subsequently, sampling of households was by convenience, with the assumption that there were an average of 10 households per village and 50% of them may keep two or more livestock species. Households with two or more livestock species were identified and approached for permission to sample their animals. Two of the selected villages could not be sampled due to road damage and inaccessibility, and were replaced by accessible villages. Furthermore, two camel herders and one cattle herder were uncooperative, complaining that their animals were in poor condition due to dry period feed shortage and should not be bled for serum sampling. The design was thus a mix of random selection and, by necessity, some convenience decisions which may constrain the study.

Cattle, camels and goats are the three major livestock species kept in most villages and are regarded as study animals. The average number of animal species per household was estimated to be 20 cattle, 15 goats and 10 camels with possible variation between ethnic groups [Reference Coppock17, Reference Solomon, Snyman and Smit18]. Factors such as presence of three animal species per village, species of animals per household, willingness of herders to cooperate and availability of herds during the visit were taken into consideration to estimate the number of each animal species to be sampled per village. Within these constraints, we aimed to sample at least 30 cattle in each village (from a finite population of 200 cattle on average); corresponding to a confidence level of 95% and expected prevalence of 10%, using the formula to detect disease. Similarly, sampling of 60 animals each in cases of camels and goats was targeted from an estimated village population of 150 goats and 100 camels with expected prevalence of 5% and a confidence level of 95% [Reference Dohoo, Martin and Stryhn19]. It worth noting that sampling to detect the presence of disease is fundamentally different from sampling to estimate the prevalence of disease. We assumed that if a contagious disease such as brucellosis was present in a population, it would be most unlikely that <1% of the population would be infected [Reference Dohoo, Martin and Stryhn19]. Based on this assumption, the required sample size for one village (a finite population) can be reasonably calculated this way. With availability of field logistic facilities, a total of 575 cattle, 1073 camels and 1248 goats were serum sampled from targeted villages. Villages were visited and sampled during the dry (December 2007 to January 2008) and wet (April to May, 2008) seasons to investigate possible seasonal effects. Cattle from one village (Bildim) had moved location and were unavailable for sampling. Some goats were also additionally sampled from villages other than those selected.

Serum sample collection and testing

For ease of access to animals and convenience to livestock owners, blood sample collection was performed early in the morning before the animals were taken out for grazing. Blood samples of about 10 ml were aseptically collected from cattle and camels, and about 5 ml from goats using plain tubes through jugular venepuncture. Serum was separated within 12 h of collection, transported to the laboratory using an ice box and stored at −20°C until tested. Information on potential risk factors related to environment, animal factors, and husbandry practices was recorded separately for each animal species during blood sampling. Serum samples were tested by Rose Bengal test (RBT) using RBT antigen (Institut Pourquier, France) as a presumptive test. Briefly, RBT antigen (30 μl) was added onto a glass slide next to an equal amount of cattle or camel serum sample, but a threefold amount of goat serum sample was used. For goats, in order to improve the sensitivity of RBT it is recommended to use alternatively one volume of antigen and three volumes of serum (e.g. 25 μl with 75 μl) instead of an equal volume of each [20]. The antigen and test serum were mixed thoroughly in a plastic applicator, shaken for 4 min, and agglutination was read immediately.

RBT-positive samples were subjected to complement fixation test (CFT) as a confirmatory test at the National Veterinary Institute (NVI), Debre Zeit, Ethiopia. CFT was performed using Brucella antigen and control sera (positive and negative) produced by Veterinary Laboratories Agency (UK). The antigen was standardized at 1:20 working dilution (strength). Serial dilutions of test sera (1:5, 1:10, 1:20, 1:40) were prepared in microtitre plates prior to adding Brucella antigen, complement and 3% sensitized sheep red blood cells. The warm fixation method was used in this study by incubating serum, antigen and complement at 37°C for 30 min. CFT was regarded positive when the reading was as partial fixation (50% haemolysis) or complete fixation (no haemolysis) at 1:10 dilution. This cut-off point, which is used by National Veterinary Institute, was taken to optimize the specificity of the test and to ensure that seropositive cases resulted from Brucella infection. The test was validated if the negative and positive control sera showed complete haemolysis and inhibition of haemolysis, respectively. It is also worth reiterating that serological tests developed for the detection of brucellosis in cattle, sheep and goats have not been validated in camels, and there is as yet no standard set of serological tests for the diagnosis of brucellosis in camels. In our study, the test procedure outlined for cattle was used to detect brucellosis in camels [1]. An animal was considered positive if it tested seropositive on both RBT and CFT in serial interpretation. Similarly, a herd or a village was considered seropositive when at least one animal in a herd or one of the animal species in a village tested positive.

Data collection and analysis

Putative biological and environmental factors believed to be associated with epidemiology of brucellosis were recorded. These included individual animal identification, sex, age, species, herd size and stock composition. Information on ethnic group, village size (number of households per village), study season and type of permanent water sources were also recorded. Data entry, dataset establishment and storage were performed in Microsoft Excel. All statistical analyses were performed using Stata SE 10 for Windows (StataCorp, USA). The overall seroprevalence for each livestock species was established based upon the Stata survey command with seropositivity as outcome variable of interest. A univariable analysis of association between explanatory variables and seropositivity to Brucella antigen was assessed using logistic regression analysis. Subsequently, a multivariable logistic regression model was established to identify risk factors associated with seroprevalence with adjustment for clustering by village. Variables with a P<0·25 from univariable analysis were included in the multivariable logistic model. The final model was built using a backward-selection procedure with a likelihood-ratio test at P=0·05 as variable selection criteria. Prior to building a final model, variables were tested for interaction effects using cross-product terms and any collinearity using a multicollinearity matrix index. The validity of the model to the observed data was assessed by computing the Hosmer–Lemeshow goodness-of-fit test using a default approach of grouping the dataset into 10 categories. The ability of the model to predict brucellosis seropositivity was assessed by establishing the receiver operating characteristic (ROC) procedure.

RESULTS

Out of 575 cattle, 1073 camel and 1248 goat serum samples screened by RBT, 54 (9·4%), 23 (2·1%), and 25 (2·0%), respectively, were found to be seropositive. With subsequent serial testing, the overall animal-level seroprevalences were 8·0% (95% CI 6·0–10·6), 1·8% (95% CI 1·1–2·8) and 1·6% (95% CI 1·0–2·5), respectively, for cattle, camels and goats. The herd-level prevalence was 51·7% (30/58) for cattle, 15·0% (16/107) for camels and 13·3% (13/98) for goats. The mean within-herd prevalence was 15·5% (range 4·8–50·0%) for cattle, 8·9% (4·4–33·3%) for camels and 10·5% (5·0–25%) for goats.

Table 1 illustrates village-level seropositivity to Brucella infection by animal species. Seropositive animals were found in 93·8% (15/16), 43·8% (7/16) and 18·8% (3/16) of the villages with at least one, two and all three positive animal species, respectively. Village-level seropositive reactors were more frequently detected in cattle (93·3%) than in camels (56·3%) and goats (37·5%). The average number of positive animals per positive herd was generally low and comparable in the three species, cattle (1·5), goats (1·5) and camels (1·2), suggesting a slow within-herd spread of the disease.

Table 1. Village-level seropositivity to Brucella infection by animal species in Borana, Ethiopia

* No. is number of animals or herds sampled per village; (%) is percent of positive samples.

Table 2 shows association of individual explanatory variables with respect to seropositivity in each species. More variables were found to be associated with seropositivity to Brucella antigens in cattle compared to camels and goats.

Table 2. Univariable analysis of explanatory variables associated with seropositivity to Brucella infections in cattle, camels and goats in Borana, Ethiopia

HH, Households.

Potential risk factors (P⩽0·25) were selected for inclusion in the multivariable model.

* Herd or flock size below median value is regarded as small and above median value as large.

Age: young <3 years (cattle), <4 years (camel) and <1 year (goat) while above is adult.

Species composition: number of livestock species kept by households.

§ Permanent water point for home-based herd: large for large ponds, and small for traditional wells or small ponds.

The results of multivariable logistic regression analysis are presented by Table 3. The results show that age (OR 2·8, 95% CI 1·3–6·0), livestock species composition (OR 4·1, 95% CI 1·9–8·9) and wet season (OR 3·3, 95% CI 1·6–6·9) were the major risk factors for cattle seropositivity to Brucella antigen. Seropositivity was found to significantly increase with age, with higher prevalences recorded in mature than young cattle. Cattle kept with multiple livestock species were fourfold more likely to be seropositive than those kept together with less (one) animal species. As the wet season occurs concurrently with parturition time of the animals, this variable is linked to increased parturition or abortion with likely excretion of Brucella organisms that could facilitate transmission and exposure to the pathogen. Unlike in cattle, only one factor for each was found to show association with seropositivity in camels and goats. Increase in household-level species composition (OR 4·1, 95% CI 1·2–14·2) was the risk factor in camels while wet season (OR 3·7, 95% CI 1·5–9·1) was found to be associated with seropositivity in goats.

Table 3. Multivariable logistic regression analysis of explanatory variables associated with seropositivity to Brucella infections in cattle, camels and goats (adjusted for clustering by village)

OR, Odds ratio; CI, confidence interval.

Hosmer–Lemeshow goodness-of-fit test data: cattle (χ2=14·8, P=0·071), camels (χ2=2·45, P=0·118), goats (χ2=1·01, P=0·315).

The Hosmer–Lemeshow goodness-of-fit test showed that the model fitted the data (cattle: χ2=14·8, P=0·071; camels: χ2=2·45, P=0·118; goats: χ2=1·01, P=0·315). The ability of the model to rationally predict occurrence of brucellosis cases, if applied to the reference population in the study area, exhibited an acceptable level of reliability (area under ROC curve ⩾0·74).

DISCUSSION

Diagnosis of Brucella infection is almost exclusively based on serological methods since bacteriological examination is not practicable for routine application [1, 20]. A remarkable limitation of brucellosis serology is that the tests used worldwide detect antibodies directed against epitopes associated to s-LPS, which is shared by the different Brucella spp. and other cross-reacting organisms such as Yersinia enterocolitica O:9 [Reference Corbel15]. Thus, as no single serological test is appropriate in all epidemiological situations, the application of two tests in series is usually recommended for maximal specificity [Reference Corbel15, 20, Reference Godfroid, Nielsen and Saegerman21]. When test specificities are conditionally independent of each other, the resulting expected specificity of serial testing is said be higher than the corresponding individual specificities of each test [Reference Dohoo, Martin and Stryhn19]. Application of series testing in diseased populations maximizes specificity and positive predictive values, but may have the risk of missing true positive cases. Given the serial nature of the testing, it is not possible to exclude that some RBT-negative animals may be positive by CFT and/or c-ELISA. Conversely, serial testing using pairs of specificity-correlated serological tests (RBT, CFT, c-ELISA) has been argued to have lower specificity than expected when applied to disease-free populations [Reference Mainar-Jaime22]. When such a test is applied to a low disease prevalence (<1%) or disease-free population, the positive predictive value of the test falls closer to zero and the increased proportion of non-infected animals are classified as seropositive [Reference Dohoo, Martin and Stryhn19, Reference Mainar-Jaime22]. Test cut-offs have different diagnostic goals depending on their context, e.g. a screening situation vs. a confirmatory diagnostic situation; where a diagnostic cut-off is selected is always a trade-off between false negatives and false positives, due to the overlap between normal and diseased populations [Reference Dohoo, Martin and Stryhn19]. In this study, the cut-off point used may increase the specificity of the test thereby ensuring that seropositive cases are resulting from Brucella infection, but may have the shortcoming of missing positive cases.

The present study documents serological evidence of Brucella infections in the animals kept for milk production under a pastoral system in Borana. The recorded higher prevalence in cattle (8·0%) compared to camels (1·8%) and goats (1·6%), is consistent with the serosurvey findings of brucellosis in different livestock species sharing the same ecosystem. Similar patterns of brucellosis seroprevalence were reported from pastoral camps in Chad, as being higher in cattle (7·0%), lower in camels (0·4%) with the absence of seroreactors in small ruminants [Reference Schelling16]. Cadmus et al. [Reference Cadmus23] reported a relatively higher seroprevalence in Nigerian cattle (5·8%) than goats (0·9%). In a study performed in Sudan [Reference Mokhtar24], seroprevalence was higher in cattle and camels than sheep and goats. Comparable seroprevalence reports were also obtained from different ruminant species in Eritrea [Reference Omer25] and Egypt [Reference Samaha26]. Conversely, records of higher seroprevalence were documented in camels and goats from Middle East areas [Reference Al-Majali27Reference Dawood29]. These results suggest that prevalence in different species of animals sharing a common ecosystem could vary from region to region depending on the presence of B. abortus and B. melitensis, and their respective preferential hosts, i.e. cattle and small ruminants, respectively.

In one village (Aradaya`a) only a seropositive goat was found, while no positive case was detected in 24 cattle and 59 camel samples (Table 1). This could be explained by either a false-positive result linked to the imperfect specificity of the test or absence of seropositive cases in cattle and camels due to the small sample size of tested animals. Since a serial testing method was applied to enhance specificity, the latter justification seems to be more plausible. Furthermore, the mobile nature of pastoral herds or animals may also lead to the assumption that an infected animal or flock might have been introduced to the village recently, so that only one seroreactor animal was detected.

In pastoral and agropastoral systems, seroprevalence of bovine brucellosis is often greater than 5% [Reference McDermott and Arimi2, Reference Berhe, Belihu and Asfaw4, Reference Matope30], while prevalence is generally low in pastoral camels [Reference Abbas and Agab31]. B. abortus has been isolated from cattle in different African countries [Reference Godfroid, Cetzer and Tustin32]. On the contrary, only sparse information exists on the isolation of B. melitensis from small ruminants in sub-Saharan Africa for the last decades [Reference Godfroid, Cetzer and Tustin32]. Indeed, B. melitensis biovar 3 was isolated from a testicular hygroma in a ram from a nomadic flock of sheep, and in goats serologically positive for brucellosis and with a history of occasional abortions in Western Sudan [Reference Musa and Jahans33], whereas three outbreaks (in 1965, 1989, 1994–1996) of B. melitensis have been recorded in goats and sheep in South Africa [Reference Emslie and Nel34]. In camels, the occurrence of B. melitensis or B. abortus was found to be linked to their contacts with the preferential hosts of the pathogens, i.e. small ruminants and cattle, respectively [Reference Mekonnen, Kalayou and Kyule7, Reference Al-Majali28, Reference Dawood29, Reference Abbas and Agab31, Reference Musa35].

Although, this study made no attempt to isolate Brucella spp., it is of note, based on serological records, that higher prevalence in cattle than in goats or camels is most likely due to the fact that B. abortus is present in cattle and might have spilled over to goats and camels. In classical brucellosis (i.e. B. abortus in cattle, B. melitensis in sheep and goats, B. suis in pigs) where control measures are not in place, a state of endemicity is reached at the herd or flock level which is characterized by a high seroprevalence [Reference Godfroid3]. However, in cases of spillover from the preferential host to the accidental host such a state of endemicity is not likely to be reached in the accidental host and, thus, a low seroprevalence record is anticipated. This presumption can be augmented by the findings of B. abortus infection in sheep in Nigeria [Reference Ocholi36], B. melitensis infection in cattle in France [Reference Verger37] and B. suis infection in cattle in Denmark [Reference Andersen and Pedersen38], which have been linked to the presence of infections in their preferential host reservoirs: cattle, small ruminants, and hares (Lepus europeanus), respectively.

Our seroprevalence finding of 8·0% in cattle (Table 2) closely agrees with the findings of 11·0% in Ethiopia [Reference Kebede, Ejeta and Ameni5], 5·8% in Nigeria [Reference Cadmus23], 5·0% in Egypt [Reference Samaha26] and 7·0% in Chad [Reference Schelling16]. However, it is higher than most of the previous reports from mixed farming systems in Ethiopia [Reference Berhe, Belihu and Asfaw4, Reference Jergefa6Reference Ibrahim8]. The higher seroprevalence of the present study could be attributed to the nature of pastoral herds; large herd size, high herd mobility and diverse species composition.

Our finding of low seroprevalence (1·8%) of camel brucellosis is also in line with the findings of different authors from pastoral camels in Ethiopia [Reference Teshome, Molla and Tibbo9, Reference Megersa, Molla and Yigezu10], Eritrea [Reference Omer25], Chad [Reference Schelling16] and Somalia [Reference Ghanem39]. In contrast, higher seroprevalences than the present finding were reported in slaughter camels from Egypt [Reference Moghney40], Nigeria [Reference Junaidu41] and Sudan [Reference Mokhtar24] which could be due to increased age of slaughter animals. Relatively higher seroprevalences (12·1% and 15·8%) were also recorded from camels in Jordan [Reference Al-Majali28, Reference Dawood29]. Prevalence was also found to be high in camels kept with cattle, sheep and goat in Sudan [Reference Musa35] and in camels in contact with small ruminants in Jordan [Reference Al-Majali28]. This was further substantiated by isolation of B. melitensis biotype 3 [Reference Dawood29, Reference Musa35] and B. abortus biotype 6 [Reference Musa35] from camel samples. The prevalence status of brucellosis in camels, therefore, appears to depend much on husbandry practices and the transmission of infection from maintenance hosts for B. melitensis and B. abortus sharing the same habitat [Reference Abbas and Agab31, Reference Wernery and Kaaden42].

In the present study, seroprevalence of caprine brucellosis was generally low (1·6%) and comparable with the findings of other authors from Ethiopia [Reference Teshale11], Nigeria [Reference Cadmus23] and Eritrea [Reference Omer25]. However, some authors, reported a relatively higher prevalence of 5·8% from Ethiopia [Reference Ashenafi12] and even much higher prevalence of 27·7% from Jordan [Reference Al-Majali27] compared to our finding. Such contrasting results are mainly related to differences in husbandry practices as well as the Brucella spp. involved. Indeed, seroprevalence is higher in areas like the Middle East where goats infected with B. melitensis are kept in large flocks, a condition that favours the spread of infection [Reference Al-Majali27]. Infection due to B. abortus occurs less frequently in goats and may result in low prevalence [1] although abortion due to B. abortus has been documented under an experimental condition [Reference Meador, Hagemoser and Deyoe43].

The observed significant association between increased livestock species composition at household level and seropositivity in cattle and camels substantiates the existence of cross-species transmission of Brucella infection (Table 3). Keeping small ruminants with cattle or camels was reported by different authors to be a risk factor for brucellosis transmission between different animal species [Reference Al-Majali28, Reference Musa35, Reference Al-Majali44, Reference Kaoud45]. Thus, animal-to-animal contact, owing to increase livestock composition at pastoral villages or households, play a considerable role in the spread of Brucella infections within and between animal species sharing a common environment.

A significant association of season with seropositivity to Brucella antigen results from concurrent occurrence of parturition along with increased excretion of Brucella organisms into the environment. The breeding cycle (parturition or abortions) in pastoral areas is often naturally synchronized with wet season feed availability, a condition which facilitates contamination and maintenance of the organisms in the environment. Gul & Khan [Reference Gul and Khan46] described peak occurrence of a brucellosis epidemic from February to July and related the event to the months that coincide with parturition and abortion in animals.

Association of higher seropositivity with increasing age in cattle is in agreement with earlier findings [Reference Berhe, Belihu and Asfaw4, Reference Kebede, Ejeta and Ameni5, Reference Al-Majali44, Reference Faye47], and is linked to increasing susceptibility to Brucella infection with sexual maturity [Reference Radostits48]. Seroprevalence may also increase with age as a result of prolonged duration of antibody responses in infected animals and prolonged exposure to infection. In traditional husbandry practice, female animals are maintained in herds over a long period of time and have ample opportunity to acquire infections. Hence, the practice of culling breeding animals with reduced reproductive performance and old age could reduce the risk of within-herd spread of brucellosis and its zoonotic hazard to humans.

Although brucellosis has been controlled or eradicated in most developed countries, many developing countries such as Ethiopia have not been able to initiate intervention measures, and the disease continues to be a major public and animal health problem. Adherence to traditional farming practices and a preference for fresh dairy products [Reference Regassa14, Reference Zinsstag49, Reference Meky50], and occupational risks [Reference Kassahun13] have been reported to be risk factors for human exposure. In our study area, close intimacy with livestock; nursing infected livestock closely, assisting during parturition without protective equipment and the tradition of raw milk consumption may facilitate zoonotic transmission of the disease.

In conclusion, the study shows that antibodies to Brucella organisms are prevalent in cattle, camels and goats, and different explanatory variables were found to be associated with seropositivity. The presence of brucellosis in animals kept for milk production, certainly poses a threat to the public health of pastoral communities. Hence, the need for investigating feasible control measures in animals and raising public awareness of prevention methods of human exposure to Brucella infection is becoming more evident.

ACKNOWLEDGEMENTS

This research work was supported partly by the Drylands Coordination Group (DCG) Norway, as part of a camel disease research project, and by the Research and Extension Office of Hawassa University. Both institutions are gratefully acknowledged.

DECLARATION OF INTEREST

None.

References

REFERENCES

1.World Health Organization (WHO).Brucellosis in Humans and Animals. Geneva, Switzerland: WHO Press, 2006.Google Scholar
2.McDermott, JJ, Arimi, SM. Brucellosis in Sub-Saharan Africa: epidemiology, control and impact. Veterinary Microbiology 2002; 20: 111134.CrossRefGoogle Scholar
3.Godfroid, J, et al. From the discovery of the Malta fever's agent to the discovery of a marine mammal reservoir, brucellosis has continuously been a re-emerging zoonosis. Veterinary Research 2005; 36: 313326.CrossRefGoogle Scholar
4.Berhe, G, Belihu, K, Asfaw, Y. Seroepidemiological investigation of bovine brucellosis in extensive cattle production system of Tigray region of Ethiopia. International Journal of Applied Research in Veterinary Medicine 2007; 5: 6571.Google Scholar
5.Kebede, T, Ejeta, G, Ameni, G. Seroprevalence of bovine brucellosis in smallholder dairy farms in central Ethiopia (Wuchale-Jida district). Revue d'Elevage et Medicine Veterinaire des Pays Tropicaux 2008; 159: 39.Google Scholar
6.Jergefa, T, et al. Epidemiological study of bovine brucellosis in three agro-ecological areas of central Oromia, Ethiopia. Revue Scientifique et Technique de l'Office International des Epizooties 2009; 28: 933943.Google Scholar
7.Mekonnen, H, Kalayou, S, Kyule, M. Serological survey of bovine brucellosis in barka and arado breeds (Bos indicus) of western Tigray, Ethiopia. Preventive Veterinary Medicine 2010; 94: 2835.CrossRefGoogle Scholar
8.Ibrahim, N, et al. Seroprevalence of bovine brucellosis and its risk factors in Jimma zone of Oromia region, South-western Ethiopia. Tropical Animal Health and Production 2010; 42: 3540.CrossRefGoogle ScholarPubMed
9.Teshome, H, Molla, B, Tibbo, M. A seroprevalence study of camel brucellosis in three camels rearing regions of Ethiopia. Tropical Animal Health and Production 2003; 35: 381390.CrossRefGoogle ScholarPubMed
10.Megersa, B, Molla, B, Yigezu, L. Seroprevalence of brucellosis in camels (Camelus dromedarius) in Borana lowland, Southern Ethiopia. Bulletin Animal Health and Production in Africa 2005; 53: 252257.Google Scholar
11.Teshale, S, et al. Seroprevalence of small ruminant brucellosis in selected districts of Afar and Somali pastoral areas of Eastern Ethiopia: the impact of husbandry practice. Revue d'Elevage et Medicine Veterinaire des Pays Tropicaux 2006; 157: 557563.Google Scholar
12.Ashenafi, F, et al. Distribution of brucellosis among small ruminants in Afar region of Eastern Ethiopia. Revue Scientifique et Technique de l'Office International des Epizooties 2007; 26: 731739.CrossRefGoogle ScholarPubMed
13.Kassahun, J, et al. Seroprevalence of brucellosis in occupationally exposed people in Addis Ababa, Ethiopia. Ethiopian Medical Journal 2006; 44: 245252.Google ScholarPubMed
14.Regassa, G, et al. Human brucellosis in traditional pastoral communities in Ethiopia. International Journal of Tropical Medicine 2009; 4: 5964.Google Scholar
15.Corbel, MJ. Recent advances in the study of Brucella antigens and their serological cross reactions. Veterinary Bulletin 1985; 55: 927942.Google Scholar
16.Schelling, E, et al. Brucellosis and Q-fever seroprevalences of nomadic pastoralists and livestock in Chad. Preventive Veterinary Medicine 2003; 61: 279293.CrossRefGoogle ScholarPubMed
17.Coppock, DL.The Borana Plateau of Southern Ethiopia: synthesis of the pastoral research, development and change 1980–1991. ILRI, Addis Ababa, Ethiopia, 1994.Google Scholar
18.Solomon, TB, Snyman, HA, Smit, GN. Cattle-rangeland management practices and perceptions of pastoralists towards rangeland degradation in the Borana zone of Southern Ethiopia. Journal of Environmental Management 2006; 84: 481494.Google Scholar
19.Dohoo, I, Martin, SW, Stryhn, H. Veterinary Epidemiologic Research. AVC Inc.. Charlottetown, Price Edward's Island, 2003, pp. 3456.Google Scholar
20.Office International des Epizooties (OIE).Caprine and Ovine brucellosis (excluding Brucella ovis). In: Manual of Diagnostic Tests and Vaccines for Terrestrial Animals. OIE, Paris, 2009, chapter 2.7.2.Google Scholar
21.Godfroid, J, Nielsen, K, Saegerman, C. Diagnosis of brucellosis in livestock and wildlife. Croatian Medical Journal 2010; 51: 296305.CrossRefGoogle ScholarPubMed
22.Mainar-Jaime, RC, et al. Specificity dependence between serological tests for diagnosing bovine brucellosis in Brucella-free farms showing false positive serological reactions due to Yersinia enterocolitica O:9. Canadian Veterinary Journal 2005; 46: 913916.Google ScholarPubMed
23.Cadmus, SIB, et al. Serological survey of brucellosis in livestock animals and workers in Ibadan Nigeria. African Journal of Biomedical Research 2006; 9: 163168.Google Scholar
24.Mokhtar, M, et al. Survey of brucellosis among sheep, goats, cattle and camel in Kassala area, Eastern Sudan. Journal of Animal and Veterinary Advances 2007; 6: 635637.Google Scholar
25.Omer, MK, et al. Prevalence of antibodies to Brucella species in cattle, sheep, horses and camels in the state of Eritrea: influence of husbandry system. Epidemiology and Infection 2000; 125: 447453.CrossRefGoogle Scholar
26.Samaha, H, et al. Multicenter study of brucellosis in Egypt. Emerging Infectious Diseases 2008; 14: 19161918.CrossRefGoogle ScholarPubMed
27.Al-Majali, AM. Seroepidemiology of caprine brucellosis in Jordan. Small Ruminant Research 2005; 58: 1318.CrossRefGoogle Scholar
28.Al-Majali, AM, et al. Risk factors associated with camel brucellosis in Jordan. Tropical Animal Health and Production 2008; 40: 193200.CrossRefGoogle ScholarPubMed
29.Dawood, HA. Brucellosis in camels (Camelus dromedorius) in the south province of Jordan. American Journal of Agricultural and Biological Sciences 2008; 3: 623626.Google Scholar
30.Matope, G, et al. Characterization of some Brucella species from Zimbabwe by biochemical profiling and AMOS-PCR. BMC Research Notes 2009; 2: 16.CrossRefGoogle ScholarPubMed
31.Abbas, B, Agab, H. A review of camel brucellosis. Preventive Veterinary Medicine 2002; 55: 4756.CrossRefGoogle ScholarPubMed
32.Godfroid, J, et al. Bovine brucellosis. In: Cetzer, JAW, Tustin, RC, eds. Infectious Diseases of Livestock. Cape Town: Oxford University Press, 2004, pp. 15101527.Google Scholar
33.Musa, MT, Jahans, KL. The isolation of Brucella melitensis biovar 3 from a testicular hygroma of a ram in a nomadic flock of sheep and goats in Western Sudan. Journal of Comparative Pathology 1990; 103: 467–70.CrossRefGoogle Scholar
34.Emslie, FR, Nel, JR. An overview of the eradication of Brucella melitensis from KwaZulu-Natal. Onderstepoort Journal of Veterinary Research 2002; 69: 123127.Google ScholarPubMed
35.Musa, MT, et al. Brucellosis in camels (Camelus dromedarius) in Darfur, Western Sudan. Journal of Comparative Pathology 2008; 138: 151155.CrossRefGoogle ScholarPubMed
36.Ocholi, RA, et al. Phenotypic characterization of Brucella strains isolated from livestock in Nigeria. Veterinary Microbiology 2004; 103: 4753.CrossRefGoogle ScholarPubMed
37.Verger, JM, et al. Bovine brucellosis caused by Brucella melitensis in France [in French]. Annales de Recherches Veterinaires 1989; 20: 93–102.Google ScholarPubMed
38.Andersen, FM, Pedersen, KB. Brucellosis: a case of natural infection of a cow with Brucella suis biotype 2 [in Danish]. Dansk Veterinaertidsskrift 1995; 78, 408.Google Scholar
39.Ghanem, YM, et al. Seroprevalence of camel brucellosis (Camelus dromedarius) in Somaliland. Tropical Animal Health and Production 2009; 41: 17791786.CrossRefGoogle ScholarPubMed
40.Moghney, ARFA. A preliminary study on brucellosis on camels at Behira province, Egypt. Assiut University Bulletin of Environmental Research 2004; 7: 3943.Google Scholar
41.Junaidu, AU, et al. Brucellosis in camels (Camelus dromedarius) in Sokoto, Northwestern Nigeria. Animal production Research Advances 2006; 2: 158160.Google Scholar
42.Wernery, U, Kaaden, OR. Infectious Diseases of Camelids. London: Blackwell Science Inc., 2002, pp. 99–116.CrossRefGoogle Scholar
43.Meador, VP, Hagemoser, WA, Deyoe, BL. Histopathologic findings in Brucella abortus-infected pregnant goats. American Journal of Veterinary Research 1988; 49: 274280.Google ScholarPubMed
44.Al-Majali, AM, et al. Seroprevalence and risk factors for bovine brucellosis in Jordan. Journal of Veterinary Science 2009; 10: 6165.CrossRefGoogle ScholarPubMed
45.Kaoud, HA, et al. Epidemiology of brucellosis among farm animals. Nature and Science 2010; 8: 190197.Google Scholar
46.Gul, ST, Khan, A. Epidemiology and epizootology of brucellosis: a review. Pakistan Veterinary Journal 2007; 27: 145151.Google Scholar
47.Faye, B, et al. Tuberculosis and brucellosis prevalence survey on dairy cattle in Mbarara milk basin (Uganda). Preventive Veterinary Medicine 2005; 67: 267281.Google Scholar
48.Radostits, OM, et al. Veterinary Medicine, Text Book of Cattle, Horses, Sheep, Pig and Goats, 11th edn. London: WB Saunders Company Ltd, 2007.Google Scholar
49.Zinsstag, J, et al. Human benefits of animal interventions for zoonosis control. Emerging Infectious Diseases 2007; 13: 527532.CrossRefGoogle ScholarPubMed
50.Meky, EA, et al. Epidemiology and risk factors of brucellosis in Alexandria Governorate. Eastern Mediterranean Health Journal 2007; 13: 677685.Google ScholarPubMed
Figure 0

Table 1. Village-level seropositivity to Brucella infection by animal species in Borana, Ethiopia

Figure 1

Table 2. Univariable analysis of explanatory variables associated with seropositivity to Brucella infections in cattle, camels and goats in Borana, Ethiopia

Figure 2

Table 3. Multivariable logistic regression analysis of explanatory variables associated with seropositivity to Brucella infections in cattle, camels and goats (adjusted for clustering by village)