Serological evidence of exposure to some zoonotic microorganisms in cattle and humans with occupational exposure to livestock in Antioquia, Colombia

Eraso-Cadena, Marcela Patricia; Molina-Guzmán, Licet Paola; Cardona, Ximena; Cardona-Arias, Jaiberth Antonio; Ríos-Osorio, Leonardo Alberto; Gutierrez-Builes, Lina Andrea

doi:10.1590/0102-311x00193617

Abstracts

Bacteria belonging to Anaplasma, Ehrlichia, Rickettsia and Coxiella genera are considered emerging pathogens and livestock is one of the contexts where the transmission of these microorganisms can occur. The goal of this study was to determine serological evidence for the exposure to these bacteria in cattle and humans with occupational exposure to livestock in the subregions North and Magdalena Medio, Antioquia, Colombia, and to explore related factors. A cross-sectional study was conducted in 48 livestock farms distributed in six municipalities from both subregions: Belmira, Entrerríos and San Pedro de los Milagros (North), and Puerto Berrío, Puerto Nare and Puerto Triunfo (Magdalena Medio). Blood samples from 332 people and 384 bovines were evaluated by serology (IgM and IgG) screening for bacteria from the Anaplasma, Ehrlichia, Rickettsia, and Coxiella genera. Seropositivity in humans from both regions was 42.4% (95%CI: 31.2-55.1) for Anaplasma, 74.2% (95%CI: 66.0-84.4) for Ehrlichia, 72.5% (95%CI: 62.1-82.0) for Rickettsia, and 60.7% (95%CI: 59.7-69.1) for Coxiella burnetii. In cattle, seropositivity was 31.6% (95%CI: 19.9-44.2), 66.8% (95%CI: 55.2-78.1), 64.6% (95%CI: 53.8-74.5), and 61.6% (95%CI: 51.9-69.2), respectively. History of biting by ticks, milking, vaccination, having dogs and hens in the residence, as well as the consumption of raw milk derivatives were some factors associated with the infection by the bacteria studied. The results suggest a previous and recent exposure to these zoonotic bacteria genera in people with occupational exposure to livestock, as well as in cattle in the two studied subregions.

Keywords:
Zoonoses; Serology; Cattle; Occupational Health

Las bacterias pertenecientes a los géneros Anaplasma, Ehrlichia, Rickettsia y Coxiella son consideradas patógenos emergentes y la ganadería es uno de los contextos donde se puede producir la transmisión de este tipo de microorganismos. El objetivo de este estudio fue determinar la evidencia serológica, debida a la exposición a estas bacterias en bovinos y humanos con exposición ocupacional a ganadería en las subregiones Norte y Magdalena Medio, Antioquia, Colombia, además de estudiar los factores relacionados. Se realizó un estudio transversal en 48 fincas ganaderas, distribuidas en seis municipios de ambas subregiones: Belmira, Entrerríos y San Pedro de los Milagros (Norte), y Puerto Berrío, Puerto Nare y Puerto Triunfo (Magdalena Medio). Las muestras de sangre de 332 personas y 384 bovinos fueron evaluadas mediante tamización serológica (IgM e IgG) para la detección de bacterias de los géneros Anaplasma, Ehrlichia, Rickettsia, y Coxiella. La seropositividad en humanos de ambas regiones fue 42,4% (IC95%: 31,2-55,1) en el caso de Anaplasma, un 74,2% (IC95%: 66,0-84,4) en Ehrlichia, un 72,5% (IC95%: 62,1-82,0) en Rickettsia, y un 60,7% (IC95%: 59,7-69,1) en Coxiella burnetii. En los bovinos, la seropositividad fue 31,6% (IC95%: 19,9-44,2), 66,8% (IC95%: 55,2-78,1), 64,6% (IC95%: 53,8-74,5), y 61,6% (IC95%: 51,9-69,2), respectivamente. El antecedente de haber sido mordido por garrapatas, ordeñar, vacunación, tener perros y gallinas en la residencia, así como el consumo de derivados de leche cruda fueron algunos de los factores asociados con la infección por las bacterias estudiadas. Los resultados sugieren la exposición previa y reciente a estas bacterias en personas con una exposición ocupacional a la ganadería, así como a los bovinos en las dos subregiones estudiadas.

Palabras-clave:
Zoonosis; Serología; Bovinos; Salud Laboral

As bactérias dos gêneros Anaplasma, Ehrlichia, Rickettsia e Coxiella são considerados patógenos emergentes, e a transmissão desses microrganismos pode ocorrer no contexto da pecuária. O estudo teve como objetivos determinar as evidências sorológicas de exposição a essas bactérias em bovinos e em humanos com exposição ocupacional ao gado nas sub-regiões Norte e Magdalena Médio, Antióquia, Colômbia, e explorar fatores associados. Foi realizado um estudo transversal em 48 fazendas de gado bovino distribuídas em seis municípios nas duas sub-regiões: Belmira, Entrerríos e San Pedro de los Milagros (Norte) e Puerto Berrío, Puerto Nare e Puerto Triunfo (Magdalena Médio). Amostras de sangue de 332 humanos e 384 bovinos foram analisadas com sorologia (IgM e IgG) para bactérias dos gêneros Anaplasma, Ehrlichia, Rickettsia e Coxiella. Os níveis de sorologia positiva em humanos das duas regiões foram de 42,4% (IC95%: 31,2-55,1) para Anaplasma, 74,2% (IC95%: 66,0-84,4) para Ehrlichia, 72,5% (IC95%: 62,1-82,0) para Rickettsia e 60,7% (IC95%: 59,7-69,1) para Coxiella burnetii. Nos bovinos, os níveis foram 31,6% (IC95%: 19,9-44,2), 66,8% (IC95%: 55,2-78,1), 64,6% (IC95%: 53,8-74,5) e 61,6% (IC95%: 51,9-69,2), respectivamente. Os fatores associados às bactérias estudadas foram: história de picada de carrapato, ordenha, vacinação, presença de cães e galinhas no domicílio e consumo de laticínios feitos com leite cru, entre outros. Os resultados sugerem exposição prévia e recente a esses gêneros bacterianos zoonóticos em pessoas com contato ocupacional com gado, assim como nos próprios animais, nas duas sub-regiões estudadas.

Palavras-chave:
Zoonoses; Sorologia; Bovinos; Saúde do Trabalhador

Introduction

Tick-transmitted infectious diseases in humans are considered zoonotic diseases ¹1. Centers for Disease Control and Prevention. Emerging tickborne diseases 2017. https://www.cdc.gov/cdcgrandrounds/archives/2017/March2017.htm (accessed on 03/May/2017).
https://www.cdc.gov/cdcgrandrounds/archi... . The livestock industry is one of the settings where such microorganisms are often detected, and the World Health Organization (WHO) considers this agricultural activity as one of the seven professional groups that is especially exposed to various zoonotic agents, given their close relationship with animals or their by-products, and the ongoing bidirectional transmission of diverse microorganisms ²2. Organización Mundial de la Salud. Informe de un comité de expertos de la salud (OMS), con participación de la FAO. Geneva: Organización Mundial de la Salud; 1982. (Reporte, 682)..

In Colombia, livestock farming occurs over the national territory as a major economic activity. The department of Antioquia hosts the largest bovine population of the country, where the Urabá, North, and Magdalena Medio subregions stand out as the largest producers at department level ³3. Instituto Colombiano Agropecuario. Censo Pecuario Nacional, 2016. https://www.ica.gov.co/getdoc/8232c0e5-be97-42bd-b07b-9cdbfb07fcac/Censos-2012.aspx (accessed on 15/Jun/2016).
https://www.ica.gov.co/getdoc/8232c0e5-b... . Tick-borne diseases cause large economic losses, affecting cattle health and reducing the quality of by-products from the production system, such as meat, milk, and skins ⁴4. Manzano R, Díaz V, Perez R. Garrapatas: características anatómicas, epidemiológicas y ciclo vital. Detalles de la influencia de las garrapatas sobre la producción y sanidad animal. Revista Argentina de Producción Animal 2012; 8:1-8.. The World Organization for Animal Health (OIE) suggests that some of these infectious diseases should be compulsorily reported for timely diagnosis and control due to their impact on animal welfare ⁵5. Organización Mundial de Sanidad Animal. Enfermedades, infecciones e infestaciones de la lista de la OIE en vigor en 2017. http://www.oie.int/es/sanidad-animal-en-el-mundo/oie-listed-diseases-2017/ (accessed on 20/Nov/2017).
http://www.oie.int/es/sanidad-animal-en-... . However, Colombian surveillance programs often present underreporting regarding the etiological and clinical suspicion of tick-borne diseases, further, adequate diagnostic and therapeutic alternatives are currently unavailable.

Tick-borne diseases in humans, such as anaplasmosis, ehrlichiosis, rickettsiosis, and coxiellosis, develop with nonspecific symptoms like fever, headache, myalgia, and arthralgia ⁶6. Bauerfeind R, von Graevenitz A, Kimmig P, Schiefer HG, Schwarz T, Slenczka W, et al. Zoonoses: infectious diseases transmissible between animals and humans. 4th Ed. Washington DC: ASM Press; 2016.. This clinical picture overlaps with other epidemiologically relevant pathologies recognized in the Colombian environment, such as malaria and dengue ⁷7. Cortés JA, Romero LF, Aguirre CA, Pinzón L, Cuervo SI. Enfoque clínico del síndrome febril agudo en Colombia. Infectio 2017; 21:39-50.. Consequently, this similarity in symptoms may lead to an underestimation of the diagnosis and inadequate treatment of cases, which are usually recorded as unspecified fevers.

Ticks are obligate hematophagous ectoparasites associated with the transmission of viruses, bacteria, and protozoa that affect both human and animal health ⁸8. Dantas F, Chomel BB, Otranto D. Ticks and tick-borne diseases: a one health perspective. Trends Parasitol 2012; 28:437-46.. Wild and domestic animals are part of their life cycle. The distribution of ticks at heights over 2,600 meters above the sea level (m.a.s.l.) ⁹9. Cortés JA, Betancourt JA, Argüelles J, Pulido LA. Distribución de garrapatas Rhipicephalus (Boophilus) microplus en bovinos y fincas del Altiplano cundiboyacense (Colombia). Corpoica Ciencia y Tecnología Agropecuaria 2010; 11:73-84. and the microorganism-transmission capacity at the transovarial and transstadial stages inherent to its life cycle, created the conditions for the maintenance of a steady population size over time, therefore increasing the risk of pathogenic microorganism transmission to diverse hosts ¹⁰10. Estrada A. Ticks as vectors: taxonomy, biology and ecology. Rev Sci Tech 2015; 34:53-65.. In the Colombian livestock context, different tick species have been found to be naturally infected by Babesia¹¹11. Ríos S, Gutiérrez L, Ríos L. Assessing bovine babesiosis in Rhipicephalus (Boophilus) microplus ticks and 3 to 9-month-old cattle in the middle Magdalena region, Colombia. Pesqui Vet Bras 2014; 34:313-9., Rickettsia¹²12. Faccini AA, Ramírez A, Forero E, Cortés JA, Escandón P, Rodas JD, et al. Molecular evidence of different Rickettsia species in Villeta, Colombia. Vector Borne Zoonotic Dis (Larchmont, NY) 2016; 16:85-7., Anaplasma and Ehrlichia¹³13. Miranda J, Mattar S. Molecular detection of Anaplasma sp. and Ehrlichia sp. in ticks collected in domestical animals, Colombia. Trop Biomed 2015; 32:726-35. genera, making them potential biological vectors. In addition, there are reports of human clinical cases of babesiosis ¹⁴14. Montes J, De La Vega F, Bello A, Fortich AS. Coinfección de babesiosis y ehrlichiosis: un caso en Cartagena de Indias, Colombia. Revista Ciencias Biomédicas 2012; 3:339-45., anaplasmosis ¹⁵15. Gómez V, Arroyo BJ, Bello AA, Rodríguez Z, Polo ER. Diagnóstico microbiológico compatible con Anaplasma sp. en un paciente con síndrome febril. Rev Argent Microbiol 2015; 47:78-9., ehrlichiosis ¹⁴14. Montes J, De La Vega F, Bello A, Fortich AS. Coinfección de babesiosis y ehrlichiosis: un caso en Cartagena de Indias, Colombia. Revista Ciencias Biomédicas 2012; 3:339-45. and coxiellosis ¹⁶16. Máttar S, Contreras V, Gonzáles M, Camargo F, Álvarez J, Oteo JA. Infection by Coxiella burnetii in a patient from a rural area of Monteria, Colombia. Rev Salud Pública 2014; 16:958-61. associated with livestock activities.

Considering the representativeness of the North and Magdalena Medio subregions in livestock production in the department of Antioquia, Colombia, this study sought to determine, through serology screening, the level of exposure of cattle and people occupationally engaged in livestock activities to some tick-transmitted zoonotic agents, and to explore the associated factors with their detection in the studied subregions.

Methods

Design and place of study

A cross-sectional study was performed in 48 farms in the North and Magdalena Medio subregions of Antioquia. For the North subregion, the study was conducted from September to October 2014, in the municipalities of Belmira, Entrerríos and San Pedro de los Milagros, where the temperature range from 13 to 19ºC, 79% relative humidity, and the altitude range is 1,850 to 2,540 m.a.s.l. For the Magdalena Medio subregion, from October to November 2015, in the municipalities of Puerto Berrío, Puerto Nare and Puerto Triunfo, where the temperature ranges from 32 to 43ºC, 53% relative humidity, and the altitude ranges from 125 to 150 m.a.s.l. These environmental conditions were verified during field sampling using a portable meteorological station (Ambient WS-2080; Ambient Weather, Chandler, U.S.A.). The estimated sample size for cattle and humans was proportionally distributed among eight cattle herds from the six municipalities included in this study (48 total herds). Livestock herds were selected in each municipality using simple random sampling on databases provided by the main livestock associations in each area. Figure 1 illustrates the geographical distribution of the studied areas. Information on geographical coordinates was collected on the field using the Trimble Juno 3B GPS equipment (Westminster, U.S.A.), and represented using the ArcGIS 10.1 software (http://www.esri.com/software/arcgis/index.html).

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Figure 1
Geographic location of the municipalities included in this study.

Information collection and processing of blood samples

This study included males and females over 18 years of age, who had contact with the bovine reference population, and who voluntarily agreed to participate in this research. All participants signed an informed consent form. A structured survey was conducted to collect and describe some socio-demographic, hygiene-sanitary and clinical aspects about each participant. The information about cattle included age, sex, breed and medical and veterinary management history. The blood samples from people and cattle were collected without any preservatives. A multiple test was conducted for the serological screening of cattle and humans, using a single cut-off point (dilution ≥ 1:16) and a custom-made commercial kit prepared by Fuller Laboratories (Fullerton, U.S.A.). To detect IgM and IgG antibodies an indirect immunofluorescence assay (IFA - the analytical sensitivity and specificity were estimated by the manufacturer in 98-100%) was used. The plates contained fixed antigens of Anaplasma phagocytophilum, Ehrlichia chaffeensis, Rickettsia rickettsii, and phase I and phase II Coxiella burnetii, obtained from axenic cultures of these microorganisms. Samples were processed, and results were analyzed according to the manufacturer’s instructions. Results were read using an Eclipse 55i microscope (Nikon, Tokyo, Japan) with an Intensilight epifluorescence system (Nikon, Tokyo, Japan) using 40X objective lens. Each IFA was read by two independent observers, blind to the sample. In the case of ambiguous readings, a third reading was performed to reach a final consensus. When necessary, the sample was re-processed and read again by both analysts.

The socio-demographic, hygiene-sanitary and clinical characteristics reported by the participants and the registered characteristics of the studied bovine population, were described as means of absolute (n) and relative frequencies (%) for the qualitative variables, and summary measures for the quantitative variables. Associated factors with seropositivity were explored; crude odds ratio and adjusted odds ratio were estimated using binary logistic regression to control confounding factors. The bivariate (crude association measures) and multivariate analyses (regression-adjusted measures) considered a 0.05 statistical significance level and 95% confidence level. The standard entry method of simultaneous variables (the enter method) was used for the regression model; all independent variables were entered in the equation at the same time to determine confounding and highly correlated ones. Statistical analysis was performed using the software SPSS for Windows, version 22.0 (IBM SPSS, Armonk, U.S.A.). This study was endorsed by the Ethics Committee on Health Research of the Universidad Pontificia Bolivariana (Record n. 7, May 23, 2012).

Results

Socio-demographic, clinical, and health description of humans included in the study

Three hundred and thirty-two people were analyzed in total; 189 subjects from the North subregion and 143 from the Magdalena Medio subregion. In the Northern area, the study group consisted of 166 (87.8%) men and 23 (12.2%) women with a median age of 40 years. Most of the analyzed population resided in rural areas (82.5%) and milking was the most frequent activity on the farm (74.1%). The presence of ticks at the farm was reported by 18% of the population and 5.8% reported a history of tick bites. Preparation of foods derived from raw milk was reported by 51.3% of the individuals and usual consumption of foods derived from raw milk by 83.1%. Regarding the presence of domestic animals in the household, dogs were the most reported (71.4%), followed by cattle (66.7%) and horses (41.8%).

Most individuals from the Magdalena Medio subregion were men (82.5%) with a median age of 42 years. Regarding the place of residence, 83.2% of the participants lived in rural areas. The main work activities performed at the farm included cattle corralling (44.8%), milking (44.1%), and direct routine contact with bovine biological fluids while performing farm-related tasks (66.2%). The participants reported high values for the presence of ticks in the farms (85.3%), as well as a history of tick biting (62.9%) and involvement of immature ticks in biting (53.1%). Regarding the possession of domestic animals in the household, dogs (70.6%) and cattle (70.6%) were the most frequent. Preparation of foods derived from raw milk was reported by 50.3% of the individuals, and 59.4% reported their consumption on a regular basis (Table 1).

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Table 1
Socio-demographic, clinical and sanitary characteristics of the participants.

Description of some characteristics and history of clinical and veterinary management of cattle

Three hundred and eighty-four bovines were evaluated in total. In the North subregion, the studied bovine population were 192 females, most of them born at the farm, with a median age of 60 months. Regarding the breeds tested in this region, 79.2% were Bos taurus and 20.8% were crossbreeds (Table 2). The proportions of male and female bovines studied in Magdalena Medio (192 cattle) were similar. The median age was 20 months. Studied breeds under mainly included Bos indicus animals (43.2%), different crossbreeds (34.4%), B. taurus (18.2%) and Colombian creole breeds (4.2%) (Table 2).

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Table 2
Characterization of the studied cattle population.

Results of the serological screening in humans and cattle from both subregions

Seropositivity was obtained for Anaplasma, Ehrlichia, Rickettsia, and Coxiella genera in individuals and cattle from the six municipalities analyzed. When analyzing the frequency of positive samples for both types of antibodies at the same time, 11.7% (45/384) was found for Anaplasma, 46.4% (178/384) for Ehrlichia, 41.1% (158/384) for Rickettsia, and 27.1% (104/384) for Coxiella; on the other hand, the human population showed a 29.2% (97/332) frequency for Anaplasma; 59.9% (199/332) for Ehrlichia, 52.1% (173/332) for Rickettsia, and 31.9% (106/332) for Coxiella (Table 3).

The highest frequency of anti-Anaplasma spp. IgM antibodies in people was detected in San Pedro de los Milagros, where 84.1% (53/63) of the samples were positive. Anti-Ehrlichia spp. IgM antibodies were mostly found in Entrerríos in 98.4% (62/63), and anti-Rickettsia spp. IgM antibodies were found in equal proportions in Belmira and San Pedro de los Milagros with 100% (63/63) positivity. For anti-C. burnetii IgM antibodies, the highest frequency was found in Belmira, with 98.4% (62/63). Regarding the detection of IgG-type antibodies in every studied bacterial genus, the highest frequency of anti-Anaplasma spp. IgG was found in the municipality of Belmira, with 60.3% (38/63). Anti-Ehrlichia spp. IgG was equally frequent in Entrerríos and San Pedro de los Milagros (84.1%, 53/63). Analyzed samples from San Pedro de los Milagros showed the highest seropositivity for anti-Rickettsia spp. and anti-C. burnetii IgG, with 81% (51/63) and 60.3% (38/63) frequencies, respectively.

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Table 3
Frequencies of IgM/IgG antibodies detected simultaneously for the genera Anaplasma, Ehrlichia, Rickettsia and Coxiella in people and cattle from the North and Magdalena Medio subregions of the department of Antioquia, Colombia.

In cattle, the highest frequency of anti-Anaplasma spp. IgM antibodies was found in Puerto Berrío, with 64.1% (41/64), whereas detection percentages of anti-Ehrlichia spp. IgM were observed in three municipalities alike: Entrerríos, Belmira and Puerto Berrío, with 87.5% (56/64). The highest frequency of anti-Rickettsia spp. IgM antibodies was detected at equal values in Belmira and San Pedro de los Milagros (96.9%, 62/64). For anti-C. burnetii IgM, the highest frequency was found in Belmira, where 100% (64/64) of samples tested positive. Regarding the detection of IgG antibodies in cattle, the highest frequency of anti-Anaplasma spp. IgG was 45.3% (29/64), and 82.8% (53/64) for anti-Ehrlichia spp. IgG, both proportions were detected in Puerto Berrío. The highest frequencies of anti-Rickettsia spp. IgG antibodies were 54.7% (35/64), equally detected in San Pedro de los Milagros and Puerto Berrío. For anti-C. burnetii IgG, the highest frequency (42.2%, 27/64) was found in Entrerríos.

Exploratory analysis of variables related to serological evidence of exposure in the studied human and animal populations

No IgM antibody associated factors were observed in the four microorganisms analyzed in both subregions after a multivariate adjustment. However, after analyzing data on the detection of IgG antibodies in individuals from the North subregion, a significant increase in exposure to Anaplasma spp. infection was observed, which is directly related to the length of time (in years) of work with cattle and to the direct contact with cattle in work activities performed in farms. However, in the Magdalena Medio subregion such relation involved the participation in livestock corralling. The exposure to Rickettsia spp. in the North subregion showed greater likelihood in individuals who performed milking and vaccination, as well as in participants who reported having dogs in their residence. In the Magdalena Medio subregion, no associated factors with Rickettsia spp. infection were observed. Regarding exposure to Ehrlichia spp., no associated factors in the North subregion were found; however, in Magdalena Medio, individuals who had direct occupational contact with cattle presented a higher probability of exposure to infection by this microorganism. Participants from the North subregion who reported tick bite history, participation in livestock slaughter and cohabitation with hens in their residence showed a higher probability of presenting serological evidence of exposure to C. burnetii. Data analysis from Magdalena Medio showed a greater probability of exposure to infection by this zoonotic agent in people consuming raw milk products.

In the Magdalena Medio subregion, it was observed that serological evidence (IgG antibodies) for exposure to Anaplasma spp. and anti-Rickettsia spp. in cattle significantly increased with age. Exposure to C. burnetii increased significantly and was related to the period cattle had been in the farms (regardless of their origin), thus resulting in the detection of IgG antibodies in bovines from the North subregion (Table 4).

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Table 4
Exploratory analysis of variables related with seropositive (IgG antibodies) to Anaplasma, Ehrlichia, Rickettsia and Coxiella in the analyzed people and cattle from the North and Magdalena Medio subregions of the department of Antioquia, Colombia.

Discussion

In this study, serological signs of exposure to Anaplasma, Ehrlichia, Rickettsia and Coxiella genera were detected in bovines and in people working in cattle raising in the North and Magdalena Medio subregions. This finding denotes the circulation of these zoonotic agents in the livestock context in the studied subregions, suggesting that their role as potential etiological agents of associated infectious diseases must be considered to establish some type of differential diagnosis for both cattle and humans.

IFA is the most used technique for screening the studied type of infections; however, this test is hindered by the interference of cross-reactions between different microorganisms. For example, species from the genus Anaplasma exhibit seroreactivity between them, as well as with other Rickettsia and Ehrlichia, given the existing phylogenetical relation that was demonstrated through the analysis of the 16S rRNA gene ¹⁷17. Battilani M, De Arcangeli S, Balboni A, Dondi F. Genetic diversity and molecular epidemiology of Anaplasma. Infect Genet Evol 2017; 49:195-211.. Likewise, there are reports of the occurrence of coinfections of C. burnetii and species from the Rickettsia genus ¹⁸18. Santos A, de Sousa R, Alves F, Proença P, Núncio M, Dumler J, et al. Isolation of Coxiella burnetii from the blood of a patient with positive Anaplasma phagocytophilum serological results. Clin Microbiol Infect 2009; 15 Suppl 2:192-3.. Therefore, for cases that require more specific species differentiation, future studies should explore serological screening methods with molecular techniques like polymerase chain reactions and in vitro culture ¹⁹19. Máttar S. Utilidad de la biología molecular en el estudio de las zoonosis. MVZ Córdoba 2000; 5:46-50.. In addition, it is important to consider that the cut-off point used in this study was employed for screening and research in apparently healthy people working at farms; higher cut-off points values, measured in paired serum (seroconversion), should be employed in clinical diagnosis and treatment, according to the dynamics of antibodies production of each zoonosis ²⁰20. Ismail N, McBride JW. Tick-borne emerging infections erhlichosis and anaplasmosis. Clin Lab Med 2017; 37:1-24.. Accordingly, if higher cut-off points were used, the frequencies reported in this study are expected to be lower since they would indicate active diseases, not exposure in the livestock context.

A. phagocytophilum is considered the etiologic agent of human granulocytic anaplasmosis. In Colombia, there are reports of cases in people working at livestock farms in the departments of Bolívar ¹⁵15. Gómez V, Arroyo BJ, Bello AA, Rodríguez Z, Polo ER. Diagnóstico microbiológico compatible con Anaplasma sp. en un paciente con síndrome febril. Rev Argent Microbiol 2015; 47:78-9., Córdoba and Sucre, where exposure to this zoonotic agent has been suggested ²¹21. Máttar S, Parra M. Detection of antibodies to Anaplasma, Bartonella and Coxiella in rural inhabitans of the Caribbean area of Colombia. MVZ Córdoba 2006; 11:781-9.. Regarding cattle, reports claim the possibility of these animals being asymptomatically infected by Anaplasma spp. ²²22. Woldehiwet Z. The natural history of Anaplasma phagocytophilum. Vet Parasitol 2010; 167:108-22., in some instances, this species has been considered the cause of conditions such as fever, anemia, and of decrease in milk production depending on the animal’s age or immune status ²³23. Organización Mundial de Sanidad Animal. Manual terrestre de la OIE - anaplasmosis bovina. http://www.oie.int/fileadmin/Home/esp/Health_standards/tahm/2.04.01_Anaplasmosis_bovina.pdf (accessed on 17/Jun/2017).
http://www.oie.int/fileadmin/Home/esp/He... . In species like Anaplasma marginale, a recognized etiological agent of bovine anaplasmosis, an extensive genetic strain diversity has been described ²⁴24. Mtshali M, De La Fuente J, Ruybal P, Kocan K, Vicente J, Mbati PA, et al. Prevalence and genetic diversity of Anaplasma marginale strains in cattle in South Africa. Zoonoses Public Health 2007; 54:23-30., which may be related to various courses of clinical evolution in this type of infection. Considering IgG seropositivity associated factors for Anaplasma in bovines from the Magdalena Medio subregion, the findings of this study suggest that exposure increased significantly with age, similarly to Wesonga et al. ²⁵25. Wesonga FD, Gachohi JM, Kitala PM, Gathuma JM, Njenga MJ. Seroprevalence of Anaplasma marginale and Babesia bigemina infections and associated risk factors in Machakos County, Kenya. Trop Anim Health Prod 2017; 49:265-72..

Anaplasma has been detected in Rhipicephalus microplus cattle ticks, in Dermacentor nitens collected from horses ¹³13. Miranda J, Mattar S. Molecular detection of Anaplasma sp. and Ehrlichia sp. in ticks collected in domestical animals, Colombia. Trop Biomed 2015; 32:726-35., and in R. microplus, Amblyomma cajennense and Amblyomma maculatum ticks collected in buffaloes ²⁶26. Barbosa J, da Fonseca AH, Barbosa JD. Molecular characterization of Anaplasma marginale in ticks naturally feeding on buffaloes. Infect Genet Evol 2015; 35:38-41., demonstrating a wide circulation in diverse hosts and potential vector species. Clinical reports show that Anaplasma transmission does not occur exclusively by tick bites, documents in the literature link this microorganism to transmission through blood transfusions ²⁷27. Fine AB, Sweeney JD, Nixon CP, Knoll BM. Transfusion-transmitted anaplasmosis from a leukoreduced platelet pool. Transfusion 2016; 56:699-704., such transmission route for this microorganism is still poorly understood. Transplacental transmission has also been reported as the infection of calves has been observed since birth, thus becoming a potential infection source for other hosts ²⁸28. Aubry P, Geale D. A review of bovine anaplasmosis. Transbound Emerg Dis 2011; 58:1-30.. In addition, mechanical transmission has been reported through fomites contaminated with infected blood ²⁹29. Kocan KM, de la Fuente J, Blouin EF, Coetzee JF, Ewing SA. The natural history of Anaplasma marginale. Vet Parasitol 2010; 167:95-107. or through diptera of the Tabanus and Stomoxys genera ³⁰30. Scoles GA, Broce AB, Lysyk TJ, Palmer GH. Relative efficiency of biological transmission of Anaplasma marginale (Rickettsiales: Anaplasmataceae) by Dermacentor andersoni (Acari: Ixodidae) compared with mechanical transmission by Stomoxys calcitrans (Diptera: Muscidae). J Med Entomol 2005; 42:668-75.. Several animals, such as cattle, horses, goats, buffaloes, and canids are involved in the life cycle of Anaplasma. Infections have been reported in tropical countries like Colombia, Costa Rica and Brazil.

On the other hand, there is currently little evidence recording the circulation of the Ehrlichia species related to cattle or to the livestock context in Colombia, which contrasts with the exposure to Ehrlichia genus found in this study. However, literature reports exposure to Ehrlichia ruminantium in bovines from cattle systems in Tanzania ³¹31. Swai ES, Mtui PF, Changa AK, Machange GE. The prevalence of serum antibodies to Ehrlichia ruminantium infection in ranch cattle in Tanzania: a cross-sectional study. J S Afr Vet Assoc 2008; 79:71-5. and molecular detection of this microbial agent in cattle systems in Turkey ³²32. Aktas M, Altay K, Dumanli N. Molecular detection and identification of Anaplasma and Ehrlichia species in cattle from Turkey. Ticks Tick Borne Dis 2011; 2:62-5.. In Colombia, Ehrlichia species has been detected in hosts such as dogs, and Ehrlichia canis infection has been identified as the cause canine monocytic ehrlichiosis ³³33. Cartagena LM, Ríos LA, Cardona JA. Seroprevalencia de Ehrlichia canis en perros con sospecha de infección por patógenos transmitidos por garrapatas en Medellín, 2012-2014. Rev Med Vet (Bogota) 2015; 29:51-62.; also, its relation to infections in human cases has been suggested. In countries like Costa Rica, the circulation of this species has been detected in samples from blood donors ³⁴34. Bouza L, Dolz G, Solórzano A, Romero JJ, Salazar L, Labruna MB, et al. Novel genotype of Ehrlichia canis detected in samples of human blood bank donors in Costa Rica. Ticks Tick Borne Dis 2017; 8:36-40., while in Brazil, studies made in rural areas have shown exposure to E. canis in dogs and E. chaffensis in humans and horses ³⁵35. da Costa RF, Wischra ST, Gomes D, Martins TF, Krawczak FS, Labruna MB, et al. Serological survey of Ehrlichia species in dogs, horses an humans: zoonotic scenery in a rural settlement from southern brazil. Rev Inst Med Trop São Paulo 2013; 55:335-40.. Some studies have shown the circulation of Ehrlichia sp. in bovine ticks (R. microplus), and in dog ticks (Rhipicephalus sanguineus). E. canis, Anaplasma platys and A. phagocytophilum have been detected in dog ticks in tropical countries like Costa Rica ³⁶36. Campos L, Äbregon L, Solórzano A, Alberti A, Tore G, Zobba R, et al. Molecular detection and identification of Rickettsiales pathogens in dog ticks from Costa Rica. Ticks Tick Borne Dis 2016; 7:1198-202., where cases in humans have also been diagnosed. This microorganism has a high diversity of host species. E. chaffeensis has been described as the species responsible for human monocytic ehrlichiosis; further, it has also been identified as an etiological agent of infections in dogs and cattle, among other animals. Susceptibility to this zoonotic agent has been experimentally tested in bovine cattle, causing fever, lethargy and in some severe cases, the death of the animal ³⁷37. de los Santos JR, Boughan K, Bremer WG, Rizzo B, Schaefer JJ, Rikihisa Y, et al. Experimental infection of dairy calves with Ehrlichia chaffeensis. J Med Microbiol 2007; 56:1660-8..

Regarding the results obtained in this study about the exposure of people and cattle from the studied regions to the Rickettsia genus, several research in Colombia have consistently suggested the circulation of spotted fever group rickettsiosis detected in equines (horses, mules and donkeys) and cattle ³⁸38. Barreto C, Faccini A, Forero E, Ramirez A, Cortés J, Polo L, et al. Evidencia serológica de exposición a rickettsias del grupo de las fiebres manchadas en bovinos del municipio de Villeta, Cundinamarca. Acta Méd Costarric 2013; 55 Suppl 1:77-8.. R. rickettsii is considered the most virulent species in the group responsible for the Rocky Mountain spotted fever, whose vector-borne transmission can be transstadial and transovarial ⁶6. Bauerfeind R, von Graevenitz A, Kimmig P, Schiefer HG, Schwarz T, Slenczka W, et al. Zoonoses: infectious diseases transmissible between animals and humans. 4th Ed. Washington DC: ASM Press; 2016., with 10-60% of cases described as fatal if not treated rapidly. In countries like Costa Rica, the circulation of different Rickettsia species has been confirmed both in ticks associated to different hosts like horses, cattle, and dogs, and in humans ³⁹39. Hun L. Rickettsiosis en Costa Rica. Acta Med Costarric 2013; 55 Suppl 1:25-8.. In Panamá, spotted fever group rickettsiosis have been isolated in ticks from domestic animals in areas near the Colombian border ⁴⁰40. Bermúdez SE, Eremeeva ME, Karpathy SE, Samudio F, Zambrano ML, Zaldivar Y, et al. Detection and identification of rickettsial agents in ticks from domestic mammals in Eastern Panama. J Med Entomol 2009; 46:856-61., suggesting their potential circulation in other tropical countries. In addition, the circulation of A. cajennense ticks extracted from skin and clothing of people has also been detected, suggesting the affinity of these arthropods for humans ¹²12. Faccini AA, Ramírez A, Forero E, Cortés JA, Escandón P, Rodas JD, et al. Molecular evidence of different Rickettsia species in Villeta, Colombia. Vector Borne Zoonotic Dis (Larchmont, NY) 2016; 16:85-7.. IFA is the most used technique to diagnose rickettsial diseases; however, the presence of cross-reactions between the different species of Rickettsia and with other bacterial genera must be considered. Although in vitro culture screening is the reference test for Rickettsia, its application is not common given the need for a Biosafety Level 3 Laboratory. Therefore, in clinical instances with symptomatic patients, other aspects must be considered for the diagnosis, such as seroconversion and higher cut-off points for antibody titers ≥ 1:64 for IgG and ≥ 1:32 for IgM ⁴¹41. Oteo JA, Nava S, Sousa R, Mattar S, Venzal JM, Abarca K, et al. Guías latinoamericanas de la RIICER para el diagnóstico de las rickettsiosis transmitidas por garrapatas. Rev Chil Infectol 2014; 31:54-65..

Regarding the exploration of associated factors with the detection of anti-Rickettsia IgG antibodies, the results of this study suggest a higher probability of infection by this microorganism in people engaged with milking and vaccination activities in cattle farms, as well as in people who have dogs in their household. The presence of several animals at home, dogs and horses being the most frequent, was noted after the survey analysis. This information is important since these animals have been reported as hosts of several of the microorganisms tested in this study. This last observation coincides with a recent report performed in urban areas of Costa Rica, in which dogs were found to have a serological imprint of exposure to spotted fever group rickettsiosis, especially in places with known human infections. These findings hypothesize that dogs could be infection vectors in these scenarios ⁴²42. Moreira A, Carranza MV, Taylor L, Calderón O, Hun L, Troyo A. Exposure of dogs to spotted fever group rickettsiae in urban sites associated with human rickettsioses in Costa Rica. Ticks Tick Borne Dis 2016; 7:748-53., which highlights the importance of the associated factors identified in this study as variables to be considered by the human and animal health sectors in subsequent studies seeking to identify the transmission dynamics of this type of zoonotic agent in the Colombian environment.

The exploration of the associated factors with seropositivity for C. burnetii found in people evaluated in this study proved that there is a greater probability of exposure to this microorganism in people who reported tick biting history and the consumption of food derived from raw milk. These factors are biologically plausible because vector-borne transmission of C. burnetii is considered secondary, and the main transmission mechanisms such as inhalation, contact with biological fluids from infected animals, and ingestion of contaminated products have been described. C. burnetii has been detected in different biological fluids like urine, feces, milk, and placenta of infected animals; tropism of this microbial agent by cells of the reproductive system has been evidenced, thus affecting consumers of unpasteurized milk ⁴³43. Sins KA, Stobierski MG, Gandh TN. Q fever cluster among raw milk drinkers, Michigan, 2011. Clin Infect Dis 2012; 55:1387-9.. Corroborating these results, C. burnetii has been previously detected in bovine milk from Colombia ⁴⁴44. Contreras V, Máttar S, González M, Álvarez J, Oteo J. Coxiella burnetii in bulk tank milk and antibodies in farm workers at Montería, Colombia. Rev Colomb Cienc Pecu 2015; 28:181-7.. In addition, serological evidence of exposure to this zoonotic agent in people engaged in livestock activities has also been reported in the departments of Córdoba and Sucre, in towns like La Ceja, Envigado and Caracoli, also being found in other Antioquia regions ⁴⁵45. Betancur CA, Rubio M, Barrera J, Bedoya JC. Seroprevalence of Coxiella burnetii in cattle farm workers in the department of Antioquia. Acta Med Colomb 2015; 40:20-3.. In some cases, C. burnetii has been linked to chronic cardiac conditions, such as endocarditis ⁴⁶46. Betancur CA, Munera AG. Endocarditis por Coxiella burnetii: fiebre Q. Acta Med Colomb 2012; 37:31-3., in people with occupational exposure to livestock. IFA is the most used method to diagnose C. burnetii; cross-reactions have also been detected, in this case, with Bartonella species ⁴⁷47. Martín L, Vidal L, Campins A, Salvá F, Riera M, Carrillo A, et al. Bartonella as a cause of blood culture-negative endocarditis. Description of five cases. Rev Esp Cardiol 2009; 62:694-7.. All these aspects must be considered for its diagnosis, in addition to the patient’s clinical history and seroconversion during clinical evolution.

In Latin America, C. burnetii infection has been reported in people living in rural areas dedicated to livestock activities in Minas Gerais, Brazil ⁴⁸48. Costa PSG, Brigatte ME, Greco DB. Antibodies to Rickettsia rickettsii, Rickettsia typhi, Coxiella burnetii, Bartonella henselae, Bartonella quintana and Ehrlichia chaffeensis among healthy population in Minas Gerais, Brazil. Mem Inst Oswaldo Cruz 2005; 100:853-9.. In Argentina, exposure to this zoonotic agent was reported in people living under poor sanitary conditions with domestic animals, such as cats and dogs ⁴⁹49. Cicuttin GL, Degiuseppe JI, Mamianetti A, Corin MV, Linares MC, De Salvo MN, et al. Serological evidence of Rickettsia and Coxiella burnetii in humans of Buenos Aires, Argentina. Comp Immunol Microbiol Infect Dis 2015; 43:57-60.. In countries like Spain, exposure to this microorganism has been detected in dairy cattle ⁵⁰50. Alvarez J, Perez A, Mardones FO, Pérez M, García T, Pagés E, et al. Epidemiological factors associated with the exposure of cattle to Coxiella burnetii in the Madrid region of Spain. Vet J 2012; 194:102-7. and in sheep. Regarding the detection of this agent in ticks, it has been described in the Amblyomma and Rhipicephalus genera of specimens collected in Brazil, Colombia, Kenya, and China ⁵¹51. Machado E, Vizzoni VF, Balsemao E, Moerbeck L, Gazeta GS, Piesman J, et al. Coxiella symbionts are widespread into hard ticks. Parasitol Res 2016; 115:4691-9.. McDaniel et al. ⁵²52. McDaniel CJ, Cardwell DM, Moeller RB, Gray GC. Humans and cattle: a review of bovine zoonoses. Vector Borne Zoonotic Dis (Larchmont, NY) 2014; 14:1-19. suggests that coxiellosis, or Q fever, should be one of the highly suspected zoonotic diseases in people with occupational exposure to cattle, and that early diagnoses must be made to achieve successful treatments, given the serious medical conditions, like endocarditis, observed in 65% of cases. Based on these data, we suggest that C. burnetii infections should also be considered in the Colombian environment for a differential and etiological diagnosis in people occupationally exposed to livestock, especially if they are used to consuming raw milk and raw milk-derived foods.

Anthropogenic activities related to the livestock production system are known to favor the contact with animals and hence, the development of zoonotic diseases. Although the North and Magdalena Medio subregions of Antioquia present contrasting ecological and productive conditions, the exposure of cattle and humans to the studied microorganisms was detected in both subregions. Milk production is considered the main economic and agricultural activity in Northern Antioquia, while breeding and dual-purpose activities are more frequent in livestock systems in the Magdalena Medio subregion ⁵³53. Gobernación de Antioquia. Plan de desarrollo "Antioquia piensa en grande" 2016-2019. http://www.antioquia.gov.co/images/pdf/ORDENANZA PLAN DE DESARROLLO DE ANTIOQUIA 2016-2019_FirmaEscaneada.pdf (accessed on 15/Apr/2018).
http://www.antioquia.gov.co/images/pdf/O... .

Climate change and global warming have been described as enhancers of the geographical expansion of vectors related to infectious diseases in the livestock context ⁵⁴54. Wu X, Lu Y, Zhou S, Chen L, Xu B. Impact of climate change on human infectious diseases: empirical evidence and human adaptation. Environ Int 2016; 86:14-23., benefiting the development of diseases that affect both animals and humans. Moreover, ungulates have been cited as the main vertebrate hosts of zoonotic pathogens when compared to animals like rodents, primates, and bats ⁵⁵55. Woolhouse MEJ, Gowtage S. Host range and emerging and reemerging pathogens. Emerg Infect Dis 2005; 11:1842-7.. The distribution of zoonotic agents related to cattle has also been claimed to be similar throughout the Americas, as well as in Oceania, Africa, Asia, and Europe ⁵²52. McDaniel CJ, Cardwell DM, Moeller RB, Gray GC. Humans and cattle: a review of bovine zoonoses. Vector Borne Zoonotic Dis (Larchmont, NY) 2014; 14:1-19.. Although the results obtained in this study are relevant, some of them remain as research questions to be answered with greater certainty in future longitudinal studies. For example, it could be important to determine how different cattle breeds, dairy farming vs breeding and dual-purpose activities, cattle management characteristics, weather, and tick infestation rates could be influencing the exposure dynamics to these zoonotic agents in the studied regions.

According to this study, time of work and direct contact with cattle (milking, vaccination, livestock slaughtering and corralling) were associated with the exposure to the studied zoonotic agents. Therefore, occupational health measures must be addressed in the livestock cattle context, taking biosecurity actions in the work field, such as the proper use of face masks, gloves, boots, preventive actions against tick bites, among others. Consumption of raw milk and foods derived from it must be considered when studying the transmission of this kind of zoonotic agents (as it has been demonstrated for C. burnetii) so control procedures are adequately followed. In addition, considering that people working in livestock activities in Colombia are exposed to the studied infections, the infectious agents involved should be included in differential and etiological diagnoses for clinical cases of acute febrile syndrome in people with this type of occupation. In general, the findings from this study indicate the exposure to these microorganisms in the livestock context. Consequently, promotion and prevention programs specifically aimed at this type of occupational exposure are required, thus addressing this problem in a comprehensive, cooperative and articulated manner in public and animal health sectors.

Acknowledgments

We thank UMATAs (Unidades Municipales de Asistencia Técnica Agropecuaria) and the livestock associations COREGAN (Comité Regional de Ganaderos de Puerto Berrío), COOLETRIUNFO (Cooperativa Multiactiva Lechera de Puerto Triunfo), and APAGRONAR (Asociación de Productores Agropecuarios de Puerto Nare) for the logistic support provided at sampling in the North and Magdalena Medio subregions. To COLCIENCIAS (grant number 121056934576-Contract 653-2013, CIDI UPB 211B-02/14-65) for the financial support.

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²⁵
Wesonga FD, Gachohi JM, Kitala PM, Gathuma JM, Njenga MJ. Seroprevalence of Anaplasma marginale and Babesia bigemina infections and associated risk factors in Machakos County, Kenya. Trop Anim Health Prod 2017; 49:265-72.
²⁶
Barbosa J, da Fonseca AH, Barbosa JD. Molecular characterization of Anaplasma marginale in ticks naturally feeding on buffaloes. Infect Genet Evol 2015; 35:38-41.
²⁷
Fine AB, Sweeney JD, Nixon CP, Knoll BM. Transfusion-transmitted anaplasmosis from a leukoreduced platelet pool. Transfusion 2016; 56:699-704.
²⁸
Aubry P, Geale D. A review of bovine anaplasmosis. Transbound Emerg Dis 2011; 58:1-30.
²⁹
Kocan KM, de la Fuente J, Blouin EF, Coetzee JF, Ewing SA. The natural history of Anaplasma marginale. Vet Parasitol 2010; 167:95-107.
³⁰
Scoles GA, Broce AB, Lysyk TJ, Palmer GH. Relative efficiency of biological transmission of Anaplasma marginale (Rickettsiales: Anaplasmataceae) by Dermacentor andersoni (Acari: Ixodidae) compared with mechanical transmission by Stomoxys calcitrans (Diptera: Muscidae). J Med Entomol 2005; 42:668-75.
³¹
Swai ES, Mtui PF, Changa AK, Machange GE. The prevalence of serum antibodies to Ehrlichia ruminantium infection in ranch cattle in Tanzania: a cross-sectional study. J S Afr Vet Assoc 2008; 79:71-5.
³²
Aktas M, Altay K, Dumanli N. Molecular detection and identification of Anaplasma and Ehrlichia species in cattle from Turkey. Ticks Tick Borne Dis 2011; 2:62-5.
³³
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³⁴
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³⁵
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³⁶
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³⁷
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³⁸
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³⁹
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⁴⁰
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⁴¹
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⁴²
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⁴³
Sins KA, Stobierski MG, Gandh TN. Q fever cluster among raw milk drinkers, Michigan, 2011. Clin Infect Dis 2012; 55:1387-9.
⁴⁴
Contreras V, Máttar S, González M, Álvarez J, Oteo J. Coxiella burnetii in bulk tank milk and antibodies in farm workers at Montería, Colombia. Rev Colomb Cienc Pecu 2015; 28:181-7.
⁴⁵
Betancur CA, Rubio M, Barrera J, Bedoya JC. Seroprevalence of Coxiella burnetii in cattle farm workers in the department of Antioquia. Acta Med Colomb 2015; 40:20-3.
⁴⁶
Betancur CA, Munera AG. Endocarditis por Coxiella burnetii: fiebre Q. Acta Med Colomb 2012; 37:31-3.
⁴⁷
Martín L, Vidal L, Campins A, Salvá F, Riera M, Carrillo A, et al. Bartonella as a cause of blood culture-negative endocarditis. Description of five cases. Rev Esp Cardiol 2009; 62:694-7.
⁴⁸
Costa PSG, Brigatte ME, Greco DB. Antibodies to Rickettsia rickettsii, Rickettsia typhi, Coxiella burnetii, Bartonella henselae, Bartonella quintana and Ehrlichia chaffeensis among healthy population in Minas Gerais, Brazil. Mem Inst Oswaldo Cruz 2005; 100:853-9.
⁴⁹
Cicuttin GL, Degiuseppe JI, Mamianetti A, Corin MV, Linares MC, De Salvo MN, et al. Serological evidence of Rickettsia and Coxiella burnetii in humans of Buenos Aires, Argentina. Comp Immunol Microbiol Infect Dis 2015; 43:57-60.
⁵⁰
Alvarez J, Perez A, Mardones FO, Pérez M, García T, Pagés E, et al. Epidemiological factors associated with the exposure of cattle to Coxiella burnetii in the Madrid region of Spain. Vet J 2012; 194:102-7.
⁵¹
Machado E, Vizzoni VF, Balsemao E, Moerbeck L, Gazeta GS, Piesman J, et al. Coxiella symbionts are widespread into hard ticks. Parasitol Res 2016; 115:4691-9.
⁵²
McDaniel CJ, Cardwell DM, Moeller RB, Gray GC. Humans and cattle: a review of bovine zoonoses. Vector Borne Zoonotic Dis (Larchmont, NY) 2014; 14:1-19.
⁵³
Gobernación de Antioquia. Plan de desarrollo "Antioquia piensa en grande" 2016-2019. http://www.antioquia.gov.co/images/pdf/ORDENANZA PLAN DE DESARROLLO DE ANTIOQUIA 2016-2019_FirmaEscaneada.pdf (accessed on 15/Apr/2018).
» http://www.antioquia.gov.co/images/pdf/ORDENANZA PLAN DE DESARROLLO DE ANTIOQUIA 2016-2019_FirmaEscaneada.pdf
⁵⁴
Wu X, Lu Y, Zhou S, Chen L, Xu B. Impact of climate change on human infectious diseases: empirical evidence and human adaptation. Environ Int 2016; 86:14-23.
⁵⁵
Woolhouse MEJ, Gowtage S. Host range and emerging and reemerging pathogens. Emerg Infect Dis 2005; 11:1842-7.

Publication Dates

Publication in this collection
11 Oct 2018

History

Received
09 Nov 2017
Reviewed
04 May 2018
Accepted
08 June 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[43] ⁴³
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[44] ⁴⁴
Contreras V, Máttar S, González M, Álvarez J, Oteo J. Coxiella burnetii in bulk tank milk and antibodies in farm workers at Montería, Colombia. Rev Colomb Cienc Pecu 2015; 28:181-7.

[45] ⁴⁵
Betancur CA, Rubio M, Barrera J, Bedoya JC. Seroprevalence of Coxiella burnetii in cattle farm workers in the department of Antioquia. Acta Med Colomb 2015; 40:20-3.

[46] ⁴⁶
Betancur CA, Munera AG. Endocarditis por Coxiella burnetii: fiebre Q. Acta Med Colomb 2012; 37:31-3.

[47] ⁴⁷
Martín L, Vidal L, Campins A, Salvá F, Riera M, Carrillo A, et al. Bartonella as a cause of blood culture-negative endocarditis. Description of five cases. Rev Esp Cardiol 2009; 62:694-7.

[48] ⁴⁸
Costa PSG, Brigatte ME, Greco DB. Antibodies to Rickettsia rickettsii, Rickettsia typhi, Coxiella burnetii, Bartonella henselae, Bartonella quintana and Ehrlichia chaffeensis among healthy population in Minas Gerais, Brazil. Mem Inst Oswaldo Cruz 2005; 100:853-9.

[49] ⁴⁹
Cicuttin GL, Degiuseppe JI, Mamianetti A, Corin MV, Linares MC, De Salvo MN, et al. Serological evidence of Rickettsia and Coxiella burnetii in humans of Buenos Aires, Argentina. Comp Immunol Microbiol Infect Dis 2015; 43:57-60.

[50] ⁵⁰
Alvarez J, Perez A, Mardones FO, Pérez M, García T, Pagés E, et al. Epidemiological factors associated with the exposure of cattle to Coxiella burnetii in the Madrid region of Spain. Vet J 2012; 194:102-7.

[51] ⁵¹
Machado E, Vizzoni VF, Balsemao E, Moerbeck L, Gazeta GS, Piesman J, et al. Coxiella symbionts are widespread into hard ticks. Parasitol Res 2016; 115:4691-9.

[52] ⁵²
McDaniel CJ, Cardwell DM, Moeller RB, Gray GC. Humans and cattle: a review of bovine zoonoses. Vector Borne Zoonotic Dis (Larchmont, NY) 2014; 14:1-19.

[53] ⁵³
Gobernación de Antioquia. Plan de desarrollo "Antioquia piensa en grande" 2016-2019. http://www.antioquia.gov.co/images/pdf/ORDENANZA PLAN DE DESARROLLO DE ANTIOQUIA 2016-2019_FirmaEscaneada.pdf (accessed on 15/Apr/2018).
» http://www.antioquia.gov.co/images/pdf/ORDENANZA PLAN DE DESARROLLO DE ANTIOQUIA 2016-2019_FirmaEscaneada.pdf

[54] ⁵⁴
Wu X, Lu Y, Zhou S, Chen L, Xu B. Impact of climate change on human infectious diseases: empirical evidence and human adaptation. Environ Int 2016; 86:14-23.

[55] ⁵⁵
Woolhouse MEJ, Gowtage S. Host range and emerging and reemerging pathogens. Emerg Infect Dis 2005; 11:1842-7.

Variables	North		Magdalena Medio
Variables	Median	IR	Median	IR
Age (years)	40	31-48	42	32-50
Time working with cattle (years)	19	10-30	20	10-28
Time working with cattle (hours/day)	8	4-9	8	1-8
	n	%	n	%
Sex
Male	166	87.8	118	82.5
Female	23	12.2	25	17.5
Site of residence
Urban	33	17.5	24	16.8
Rural	156	82.5	119	83.2
Education level (years)
≤ 5	117	61.9	95	66.4
6-11	59	31.2	40	28.0
≥ 12	13	6.9	8	5.6
Occupational history *
Contact with cattle	175	92.6	112	78.3
Contact with bovine biological fluids	156	82.5	94	66.2
Presence of ticks in the farm	34	18.0	122	85.3
History of tick bites	11	5.8	90	62.9
History of immature ticks found in their bodies	9	4.8	76	53.1
Farm occupations
Milking	140	74.1	63	44.1
Cattle corralling	111	58.7	64	44.8
Cattle bath	97	51.3	35	24.5
Vaccination	93	49.2	61	42.7
Fumigation	61	32.3	41	28.7
Cattle slaughtering	33	17.5	17	11.9
Farm barbed-wiring	31	16.4	36	25.2
Animals in the residence place
Dog	135	71.4	101	70.6
Cattle	126	66.7	101	70.6
Horse	79	41.8	84	58.7
Hen	76	40.2	93	65.0
Cat	73	38.6	93	65.0
Pig	57	30.2	47	32.9
Sheep	16	8.5	7	4.9
Goat	9	4.8	3	2.1
Hygiene-sanitary characteristics
Hand washing before eating and cooking	185	97.9	134	93.0
Preparation of food derived from raw milk	97	51.3	72	50.3
Consumption of food derived from raw milk	157	83.1	85	59.4
Consumption of raw milk	80	42.3	30	21.0
Self-report of medical history *
Headache	62	32.8	55	38.5
Fever	52	27.5	49	34.3
Chills	36	19.0	47	32.9
Fatigue	34	18.0	21	14.8
Stomachache	32	16.9	25	17.5
Myalgia	25	13.2	17	11.9
Nausea	24	12.7	21	14.7

Variables	North		Magdalena Medio
Variables	Median	IR	Median	IR
Age (months)	60	42-81	20	9-60
Time cattle has been in the farm (months)	60	41-72	14	8-48
	n	%	n	%
Sex
Male	-	-	96	50.0
Female	192	100.0	96	50.0
Breed *
Bos taurus **	152	79.2	35	18.2
Bos indicus **	-	-	83	43.2
Different crossbreeds	40	20.8	66	34.4
Colombian creole breeds **	-	-	8	4.2
Type of livestock production
Meat	-	-	98	51.0
Milk	192	100.0	59	30.7
Breeding	-	-	23	12.0
Dual purpose	-	-	12	6.3
Place of origin of the bovine
Born at the farm	168	87.5	148	77.1
Born in another farm	24	12.5	44	22.9
History of clinical and veterinary management
None/Non-diseased	187	97.4	192	100.0
Low milk production	2	1.0	-	-
Fever	1	0.5	-	-
Weight loss	1	0.5	-	-
Milk fever and hypocalcemia	1	0.5	-	-

Variable	OR *	95%CI
People
North subregion
Anaplasma spp.
Time working with cattle (in years)	1.04	1.00-1.08 **
Direct occupational contact with cattle	3.43	1.00-11.71 **
Rickettsia spp.
Participation in milking	2.64	1.08-6.43 **
Participation in vaccination	4.07	1.53-10.84 **
Having dogs in the place of residence	6.14	2.26-16.66 ***
Coxiella burnetii
Participation in livestock slaughtering	3.76	1.35-10.45 **
History of tick bites	6.18	1.12-34.07 **
Having hens in the place of residence	3.61	1.32-9.79 **
Magdalena Medio subregion
Anaplasma spp.
Participation in livestock corralling	3.43	1.22-9.63 **
Time working with cattle (in years)	1.90	1.21-3.26 **
Ehrlichia spp.
Direct occupational contact with cattle	2.59	1.02-6.57 **
Participation in fumigation	0.34	0.15-0.78 **
Coxiella burnetii
Consuming foods derived from raw milk	4.04	1.58-10.34 **
Time working with cattle (in years)	6.16	2.28-16.4 ***
Cattle
North subregion
Coxiella burnetii
Time cattle has been in the farm	2.45	1.02-6.08 **
Ticks control method	1.69	1.13-3.27 ***
Magdalena Medio subregion
Anaplasma spp.
Age	1.79	1.12-3.63 **
Ticks control method	1.21	1.31-8.26 **
Rickettsia spp.
Age	1.99	1.15-6.57 **
Type of livestock production	0.75	0.73-8.58 **

Saúde Pública

Saúde Pública

Serological evidence of exposure to some zoonotic microorganisms in cattle and humans with occupational exposure to livestock in Antioquia, Colombia

Evidencia serológica de exposición a algunos microorganismos zoonóticos en bovinos y humanos con exposición ocupacional a ganadería en Antioquia, Colombia

Evidências sorológicas de exposição a alguns microrganismos zoonóticos em bovinos e em humanos com exposição ocupacional ao gado na Antióquia, Colômbia

Abstracts

Introduction

Methods

Design and place of study

Information collection and processing of blood samples

Results

Socio-demographic, clinical, and health description of humans included in the study

Description of some characteristics and history of clinical and veterinary management of cattle

Results of the serological screening in humans and cattle from both subregions

Exploratory analysis of variables related to serological evidence of exposure in the studied human and animal populations

Discussion

Acknowledgments

References

Publication Dates

History

Subregion/Municipality	Analyzed samples	Anaplasma		Ehrlichia		Rickettsia		Coxiella
Subregion/Municipality	Analyzed samples	#	% (95%CI)	#	% (95%CI)	#	% (95%CI)	#	% (95%CI)
People
North
Entrerríos	63	27	42.9 (30.5-56.0)	52	82.5 (70.9-91.0)	47	74.6 (62.1-84.7)	27	42.9 (30.5-56.0)
Belmira	63	28	44.4 (31.9-57.5)	47	74.6 (62.1-84.7)	36	57.1 (44.1-69.5)	30	47.6 (34.9-60.6)
San Pedro de los Milagros	63	34	54.0 (40.9-66.6)	49	77.8 (65.5-87.9)	51	81.0 (69.1-89.8)	32	50.8 (37.9-63.6)
Total	189	89	47.1 (39.8-54.5)	148	78.3 (71.7-84.0)	134	70.9 (63.9-77.3)	89	47.1 (39.8-54.5)
Magdalena Medio
Puerto Berrío	50	2	4.0 (0.5-13.7)	27	54.0 (39.3-68.2)	17	34.0 (21.2-48.8)	9	18.0 (8.6-31.4)
Puerto Triunfo	37	6	16.2 (6.2-32.0)	21	56.8 (39.5-72.9)	13	35.1 (20.2-52.5)	6	16.2 (6.2-32.0)
Puerto Nare	56	- *	- *	3	5.4 (1.1-14.9)	9	16.1 (7.6-28.3)	2	3.6 (0.4-12.3)
Total	143	8	5.6 (2.4-10.7)	51	35.7 (27.8-44.1)	39	27.3 (20.2-35.4)	17	11.9 (7.1-18.4)
Total (people)	332	97	29.2 (24.4-34.4)	199	59.9 (54.5-65.3)	173	52.1(46.6-57.6)	106	31.9 (26.9-37.2)
Cattle
North
Entrerríos	64	4	6.3 (1.7-15.2)	29	45.3 (32.8-58.3)	26	40.6 (28.5-53.6)	23	35.9 (24.3-48.9)
Belmira	64	2	3.1 (0.4-10.8)	33	51.6 (38.7-64.3)	33	51.6 (38.7-64.3)	24	37.5 (25.7-50.5)
San Pedro de los Milagros	64	11	17.2 (8.9-28.7)	37	57.8 (44.8-70.1)	34	53.1 (40.2-65.7)	25	39.1 (27.1-52.1)
Total	192	17	8.9 (5.24-13.8)	99	51.6 (44.3-58.8)	93	48.4 (41.2-55.7)	72	37.5 (30.6-44.8)
Magdalena Medio
Puerto Berrío	64	20	31.3 (20.2-44.1)	47	73.4 (60.9-83.7)	33	51.6 (38.7-63.3)	11	22.0 (8.9-28.7)
Puerto Triunfo	64	7	10.9 (4.5-21.3)	25	39.1 (27.1-52.1)	22	34.4 (23.0-47.3)	14	21.9 (12.5-34.0)
Puerto Nare	64	1	1.6 (0.04-8.4)	7	10.9 (4.5-21.3)	10	15.6 (7.8-26.9)	7	10.9 (4.5-21.3)
Total	192	28	14.6 (9.9-20.4)	79	41.1 (34.1-48.5)	65	33.9 (27.2-41.0)	32	16.7 (11.7-22.7)
Total (cattle)	384	45	11.7 (8.7-15.4)	178	46.4 (41.3-51.5)	158	41.1 (36.2-46.3)	104	27.1 (22.7-31.8)