Abstract
Objectives
Brucellosis is caused by bacteria from the genus Brucella which infect human and domestic animals as well as wildlife. The Maasai Mara National Reserve has vast populations of wild ruminants such as buffaloes and wildebeest which could contribute to the risk of brucellosis in livestock, and the surrounding pastoralist communities grazing cattle in and around the reserve may be exposed to a higher risk of zoonotic diseases like brucellosis due to the close contact with livestock. In this study, cattle from three villages at varying distance from the reserve, were screened for antibodies against Brucella abortus.
Results
In total, 12.44% of 225 sampled animals were seropositive, with more females (15%) infected than males (5%). Seroprevalence was higher in livestock closer to Maasai Mara with the cattle in the village Mara Rianta having an odds ratio of 7.03 compared to Endoinyo Narasha further away (95% CI 1.4–11.1, p = 0.003), suggesting that a closer contact with wildlife may increase the circulation of infectious diseases between livestock and wildlife. Symptoms consistent with brucellosis were reported to occur in both humans and animals, and we thus conclude that brucellosis may be an important problem, both for the health and the economy.
Electronic supplementary material
The online version of this article (10.1186/s13104-017-2941-x) contains supplementary material, which is available to authorized users.
Keywords: Zoonosis, Brucella abortus, Livestock-wildlife interface, Pastoralism, Africa
Introduction
In sub-Saharan Africa, livestock are essential for the livelihood of many families, and the health of livestock, humans and their economic welfare are closely linked [1]. Zoonotic diseases create a double burden on the households with both human and animal morbidity [2]. Brucellosis is a severe disease for farmers since it does not only cause serious chronic disease in humans and suffering in their animals, but also a decreased production since the disease is associated with abortions and reproductive failures in the livestock [3].
In cattle the infection is predominantly caused by B. abortus, sometimes by B. melitensis (more common in small ruminants) and occasionally by B. suis [4–6]. Different wildlife species, especially ruminants, provide a potential reservoir of brucellosis, which has been suggested to increase the risk infections in livestock [7].
In Kenya, awareness of brucellosis is low among livestock-keepers and healthcare staff, and because of the general symptoms and the limited availability of laboratory facilities, diagnosis is not easy [8, 9]. Moreover, some of the areas with high cultural and economic dependence on livestock are close to wildlife protected areas, such as the Maasai Mara national reserve. The aim of this study was to determine the current seroprevalence of bovine brucellosis and the associated exposure factors for transmission, in three villages close to Maasai Mara.
Main text
Methods
Three villages (Lemek, Mara Rianta and Endoinyo Narasha) were selected purposively to represent areas with expected differences in livestock-wildlife interaction based on the distance to the national reserve. Both Lemek and Endoinyo Narasha represented areas with less livestock-wildlife overlap. In Lemek there was free grazing; in Endoinyo Narasha sedentary grazing systems in fenced lands were being adopted, while Mara Rianta had high wildlife-livestock interactions due to livestock grazing in the park and communal grazing lands.
The sample size was determined by logistic possibilities. Twenty-five households, all keeping livestock, were randomly selected in each village. Livestock owners were interviewed using a questionnaire translated to Swahili and Maa, where they were asked to answer questions about animal keeping, grazing strategies, herd sizes, experienced signs of illness and other significant details that could be of importance to the study (Additional file 1). The questionnaire was developed by experts at ILRI and pre-tested in the field. Three cattle over 1 year were randomly selected (excluding large bulls and aggressive animals for safety reasons) in each herd for blood sampling. The serum was analyzed in duplicates using an indirect Enzyme-Linked Immunosorbent assay (ELISA); PrioCHECK® Brucella Antibody 2.0 ELISA (Thermo Fisher Scientific) according to manufacturer’s instructions. Univariable analyses for risk factors for seropositivity was done using Stata (STATA 14, StataCorp LP, USA). A risk score was calculated adding all risk practices; whether cattle are let to graze inside the national reserve; whether cattle mix with other herds while grazing; whether cattle mix with other herds at watering points; whether cattle share trek route with other herds; whether herds share water point on trek; whether farmer has bought livestock from other farms; whether working personnel visit other livestock holdings; and whether vehicles have access to farm. Correction for multiple comparisons was not done. Data is provided as Additional file 2.
The study had ethical approval from International Livestock Research Institute (ILRI) animal care and use committee (IACUC Approval 2016–20).
Results
A total of 225 animals were sampled, and 28 of them [12.44%; 95% confidence interval (CI) 7.71–15.41] were seropositive (Table 1). None of the farmers indicated that they had ever vaccinated livestock against brucellosis. More animals, 22.7% (95% CI 14.7–33.3), were positive in Mara Rianta and the odds ratio (OR) was 7.03 (p = 0.003) higher than Endoinyo Narasha, where seroprevalence was 4.0% (95% CI 1.4–11.1), and OR was 2.45 (p = 0.053) higher for Mara Rianta than in Lemek where the prevalence was 10.7 (95% CI 5.5–19.7). Females had a higher risk (OR 4.0, p = 0.046) of being seropositive compared to males, with 25/166 females (15.1%, 95% CI 10.4–21.3) being positive compared to 3/59 males (5.1%, 95% CI 1.7–13.9). All three positive males were sampled in Mara Rianta.
Table 1.
Total | Positive | % Positive | 95% CI | |
---|---|---|---|---|
Total | 225 | 28 | 12.44 | 7.71–15.41 |
Female | 166 | 25 | 15.06 | 10.41–21.29 |
Male | 59 | 3 | 5.08 | 1.74–13.92 |
Lemek | 75 | 8 | 10.67 | 5.50–19.66 |
Mara Rianta | 75 | 17 | 22.67 | 14.66–33.34 |
Endoinyo Narasha | 75 | 3 | 4.00 | 1.37–11.11 |
Twenty farms (26.7%) had one or more Brucella-infected cattle. During the last year, many farmers had experienced abortion (or loss of pregnancy, or stillbirth) in their cows (68, 48 and 36% in Mara Rianta, Lemek and Endoinyo Narasha respectively). In 13 of the infected farms (65%), the farmer reported abortions during the last 1 year. The odds ratio of having had abortion if Brucella was present in a farm was 2.2 higher than if Brucella was not present (CI 0.7–6.4), and in 34.2% of the farms that have experienced abortion in cattle the last 1 year, the farm was positive for Brucella, in even, antibodies against Brucella was present in serum from one or more of the three sampled animals (Table 2).
Table 2.
Farm with abortion | Farm without abortion | Total | |
---|---|---|---|
Positive farm | 13 | 7 | 20 |
Negative farm | 25 | 30 | 55 |
Total | 38 | 37 | 75 |
All farms had at least one bull for breeding and practiced natural mating. All the participants reported that animals had regular contact with wild ungulates and other cattle. Farms in Mara Rianta were generally larger compared to Lemek and Endoinyo Narasha (Table 3). Clinical pictures compatible with brucellosis were also reported in humans handling livestock. The most common was headache (48, 60 and 64% in Mara Rianta, Lemek and Endoinyo Narasha respectively), muscle, joint and back pain (52, 56 and 64% in Mara Rianta, Lemek and Endoinyo Narasha respectively) and fever (48, 44 and 40% in Mara Rianta, Lemek and Endoinyo Narasha respectively) (Table 3).
Table 3.
Overall (N = 75) | Lemek (N = 25) | Mara Rianta (N = 25) | Endoinyo Narasha (N = 25) | |
---|---|---|---|---|
Cattle herd size | 109 (5–400) | 97 (15–300) | 144 (14–400) | 85 (5–300) |
Years of operation | 34.6 (5–70) | 35.32 (15–60) | 37.08 (15–70) | 31.44 (5–70) |
Grazing in reserve | 60% | 32% | 100% | 48% |
Bought livestock during the last year | 79% | 88% | 64% | 84% |
Contact with wildlife reported by the farmer | ||||
Ungulates | 100% | 100% | 100% | 100% |
Predators | 76% | 52% | 100% | 76% |
Monkeys | 35% | 0% | 36% | 68% |
Contact with other livestock reported by the farmer | ||||
Cattle | 100% | 100% | 100% | 100% |
Goats | 80% | 92% | 48% | 100% |
Sheep | 80% | 92% | 48% | 100% |
Pigs | 0% | 0% | 0% | 0% |
Poultry | 0% | 0% | 0% | 0% |
Signs of illness noticed in cattle | ||||
Fever | 4% | 8% | 4% | 0% |
Fatigue | 0% | 0% | 0% | 0% |
Reduced fertility/abortion and/or stillbirth | 51% | 48% | 68% | 36% |
Decrease in milk production | 9% | 12% | 4% | 12% |
Mastitis/udder swelling and/or pain | 23% | 32% | 24% | 12% |
Self-reported signs of illness experienced by people handling the animals | ||||
Fever | 45% | 44% | 48% | 40% |
Sweats | 15% | 16% | 16% | 12% |
Malaise | 31% | 20% | 20% | 52% |
Headache | 57% | 60% | 48% | 64% |
Pain in muscles, joints and/or back | 57% | 56% | 52% | 64% |
All farms had at least five risk factors reported, with a higher average in Mara Rianta (7.6), than Lemek (7.0) and Endoinyo Narasha (6.8). Seropositive farms generally did have a higher risk score (average 7.4) than negative farms (average 7.1) but the difference was not significant (Table 3).
Discussion
More than a fifth of the farms and a tenth of the cattle had evidence of past Brucella infection in this study, with higher odds of animals being positive closer to the national reserve. To our knowledge, no similar study has been carried out on Brucella in this context. In addition, both livestock and humans had experienced symptoms that are consistent with the pathogen. Although this was not assessed in this study, it is possible that some clinical signs were caused by brucellosis. Indeed, human Brucella infections and disease have been previously reported in Kenya [9, 10].
There may be different explanations to the higher seroprevalence in Mara Rianta observed here. While all sites practices natural breeding, which has been associated with higher risk of brucellosis [11], all three positives males were in Mara Rianta, which may indicate a higher infection rate in the males in that population, further increasing the risks for the females. However, due to the small number of males sampled in this study, further research is needed to conclude on this. It is likely that a larger herd size entails a greater risk for Brucella infection. Previous studies suggest small, confined herds have lower risks [3], which is supported by the results from this study where Endoinyo Narasha was the village with the lowest prevalence, the smallest herds, and the only village where cattle farms were fenced.
There is a possibility that cattle in the infected farms have had abortions earlier since most cattle only abort once after infection [5], and we found a tendency among positive farms to report a higher degree of reproductive problems. There are many reasons why cattle may abort, and many of these are infectious [12]. Further studies are needed to investigate the relative importance of Brucella spp. as a cause of abortion in cattle of the examined area. Similarly the symptoms reported by farmers may be caused by many different diseases, and further studies would be required to provide more insight knowledge on the contribution of different pathogens to the total disease burden.
Wildlife can be a source of infectious diseases and thereby a risk to the health of the livestock as has been shown for some diseases [13]. A significant difference was found in prevalence of brucellosis between the villages, with cattle from Mara Rianta having the highest proportion of positive animals. These animals were grazing inside the national reserve Maasai Mara, and interacting with wildlife to a higher degree, than cattle that mostly graze behind fences within the own village, as in Endoinyo Narasha. Brucella exposure has been reported in both African buffaloes (Syncerus caffer), blue wildebeest (Connochaetes taurinus), oryx (Oryx beisa) and eland (Taurotragus oryx); common in and around Maasai Mara [14, 15].
Brucellosis remains an important problem in Kenya since there is currently no possibility of controlling or eradicating the disease the same way as in high-income countries, and vaccination is not common. None of the participating farmers reported that they had vaccinated their animals against the disease. In Kenya, a suitable method of controlling disease has to be introduced, with components of disease surveillance, mapping of transmission routes, vaccination campaigns, isolation of exposed animals and thorough examination before introducing new individuals to a healthy animal herd ought to be fundamental since all mentioned factors are important cornerstones in successful disease control. Since there are no vaccines available for humans, prevention of brucellosis in humans relies fully in controlling the animal reservoir.
Limitations
This study had several limitations, including the limited sample size of 75 herds, and few males sampled. Although selection of animals at herd level was intended to be unbiased and random, large bulls and aggressive individuals were excluded; however, the authors are not expecting this to influence the results significantly. There were many confounders in the study, and herd size was much depending on the area of sampling, meaning that it is difficult to draw definite conclusions on these factors. To fully evaluate the impact on human health, it would be necessary to collect data on incidence and morbidity.
Additional files
Authors’ contributions
SE conducted the field and laboratory work, data analyses, and did the first draft of the manuscript. DN supervised the field work and contributed to the study design and manuscript. BB and SA contributed to the study design and manuscript. AK contributed to the field work, the study design and manuscript. JL supervised all the work, analyses, and manuscript writing; and designed the study. All authors read and approved the final manuscript.
Acknowledgements
We thank livestock owners, local animal health worker William Kububuk and John Kisurkat who participated in the survey. We are also grateful to the Kenya Wildlife Service (KWS) for laboratory space at Sekenani that allowed us to prepare serum for serological analysis.
Competing interests
There were no competing interests, financial or others, in this study.
Availability of data and materials
The dataset supporting the conclusions of this article is included within the article as an Additional files.
Consent for publication
Not applicable.
Ethical approvals and consent to participate
The study had an ethical approval from ILRI animal care and use committee (IACUC Approval 2016–20). All participants were informed about the purpose of the study, and asked for their consent. Written informed consent was given by owners before interview or sampling.
Funding
This work was supported by SIDA, Swedish International Development Cooperation, through MFS, Minor Field Study, grants. Additional support was provided by Consultative Group for International Agricultural Research (CGIAR) Research Program on Agricultural for Nutrition and Health (A4NH) led by International Food Policy Research Institute (IFPRI) and the AfricanBioServices Project which received funding from the European Union’s Horizon 2020 research and innovation programme under Grant Agreement No 641918.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abbreviations
- CI
confidence interval
- ELISA
enzyme-linked immunosorbent assay
- IACUC
Institutional Animal Care and Use Committee
- ILRI
International Livestock Research Institute
- OR
odds ratio
Footnotes
Electronic supplementary material
The online version of this article (10.1186/s13104-017-2941-x) contains supplementary material, which is available to authorized users.
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Associated Data
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Supplementary Materials
Data Availability Statement
The dataset supporting the conclusions of this article is included within the article as an Additional files.