Prevalence and risk factors of gastrointestinal parasites in backyard pigs reared in the Bucaramanga Metropolitan Area, Colombia

Pinilla, Juan Carlos; Morales, Elsa; Delgado, Nelson Uribe; Florez, Angel Alberto

doi:10.1590/S1984-29612020094

Abstract

Backyard pigs have been associated with poor sanitary conditions and the development of parasitic diseases, often causing public health and food safety problems. Therefore, the aim of this study was to determine the prevalence and risk factors for gastrointestinal parasites in backyard pigs. 279 animals were sampled from thirty-two backyard pig farms located in the Bucaramanga, Floridablanca, Giron and Piedecuesta municipalities, from Bucaramanga Metropolitan Area, Colombia. Fecal samples were taken directly from the rectum and processed by four coprological techniques. The overall prevalence of gastrointestinal parasites was 91%, being the highest values for Balantidium coli and Eimeria sp. Regarding the prevalence by municipalities, there was no statistical association (p ≥ 0.05) indicating that the prevalence was similar in the region under study. Floridablanca municipality, free-ranging pigs, access to latrines, and consumption of spring water showed to be a risk factor for nematodes, while Giron municipality, pigs > 7 months of age and access to latrines, increased infection risk for coccidian. We concluded that there is a high prevalence of gastrointestinal parasites in backyard pigs from the Bucaramanga Metropolitan Area, and that it could be controlled by improving management practices and farm facilities.

Keywords:
Backyard pigs; gastrointestinal parasitism; nematodes; protozoan

Resumo

Suínos criados em fundo de quintal têm sido associados às más condições sanitárias e ao desenvolvimento de doenças parasitárias, frequentemente causando problemas de saúde pública e segurança alimentar. Assim, o objetivo deste estudo foi determinar a prevalência e os fatores de risco para parasitos gastrointestinais em suínos criados em fundo de quintal. Foram amostrados 279 animais de 32 fazendas de suínos localizadas nos municípios de Bucaramanga, Floridablanca, Giron e Piedecuesta, da Área Metropolitana de Bucaramanga, Colômbia. As amostras fecais foram coletadas diretamente do reto e processadas por quatro técnicas coprológicas. A prevalência geral de parasitos gastrintestinais foi de 91%, sendo os maiores valores para Balantidium coli e Eimeria sp. Em relação à prevalência por municípios, não houve associação estatística (p≥ 0,05), indicando que a prevalência foi semelhante na região estudada. O município de Floridablanca, porcos caipiras, acesso a latrinas e consumo de água da nascente mostraram ser um fator de risco para os nematoides enquanto no município de Giron, porcos com mais de 7 meses de idade e acesso a latrinas, aumentou o risco de infecção por coccídios. Concluiu-se que há uma alta prevalência de parasitos gastrointestinais em suínos criados em fundo de quintal da Área Metropolitana de Bucaramanga, e que isso poderia ser controlado melhorando as práticas de manejo e as instalações agrícolas.

Palavras-chave:
Porcos caipiras; parasitismo gastrointestinal; nematóides; protozoários

Introduction

Gastrointestinal (GI) parasitism is caused by different genera of parasites that inhabit the digestive tract of pigs, causing several digestive signs, loss of appetite, poor growth rate, poor feed conversion ratio, organ and carcass condemnation, high cost of treatment, economic losses in the farms, and even death in severe cases (Kagira et al., 2012Kagira JM, Kanyari PN, Githigia SM, Maingi N, Nganga JC, Gachohi JM. Risk factors associated with occurrence of nematodes in free range pigs in Busia District, Kenya. Trop Anim Health Prod 2012; 44(3): 657-664. http://dx.doi.org/10.1007/s11250-011-9951-9.
http://dx.doi.org/10.1007/s11250-011-995... ). Therefore, parasites represent an obstacle in swine production, and thus, greater knowledge about the epidemiology is necessary (Góes et al., 2009Góes G, Santos TB, de Melo CM, Jeraldo VLS. Ocorrência de enteroparasitas em amostras fecais de suínos do município de Simão Dias-SE. Cad Grad- Ciênc Biol Saúde 2009; 1(15): 11-18.). In general, GI parasitism in pigs is caused by nematodes and protozoan (Cordero & Rojas, 1999Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999.). Protozoan, Eimeria sp. and Cystoisospora suis, are enterococcidia which causes swine coccidiosis, an infection characterized by diarrhea in pigs under three months of age; also, parasitic infections by nematodes such as Ascaris suum, Trichuris suis, Strongyloides ransomi and parasites of the Strongylida order (Cordero & Rojas, 1999Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999.). Many GI parasites affect health and swine production, and can be transmitted to humans, such as Balantidium coli, Entamoeba coli and Cryptosporidium sp. (Solaymani-Mohammadi & Petri, 2006Solaymani-Mohammadi P, Petri WA Jr. Zoonotic implications of the swine-transmitted protozoal infections. Vet Parasitol 2006;140(3-4): 189-203. https://doi.org/10.1016/j.vetpar.2006.05.012
https://doi.org/10.1016/j.vetpar.2006.05... ). These protozoans are transmitted via the fecal-oral route in both humans and animals, usually through the ingestion of contaminated water or food (Zheng et al., 2019Zheng S, Li D, Zhou C, Zhang S, Wu Y, Chang Y, et al. Molecular identification and epidemiological comparison of Cryptosporidium spp. among different pig breeds in Tibet and Henan, China. BMC Vet Res 2019; 15(1): 101. http://dx.doi.org/10.1186/s12917-019-1847-3.
http://dx.doi.org/10.1186/s12917-019-184... ).

Some authors have reported parasitic prevalences in backyard pigs. Mendoza-Gómez et al. (2015)Mendoza-Gómez M, Pulido-Villamarín A, Barbosa-Buitrago A, Aranda-Silva M. Presence of gastrointestinal parasites in swine and human of four swine production farms in Cundinamarca- Colombia. Rev Mvz Cordoba 2015; 20(1): 5014-5027. http://dx.doi.org/10.21897/rmvz.15.
http://dx.doi.org/10.21897/rmvz.15... reported prevalence rates of 40% for E. coli and 5% for B. coli in semi-technified farms from Cundinamarca department, Colombia, whilst Herrera et al. (2015)Herrera BY, Almanza PM, Ensuncho HC, Goméz ML, Galeano EM. Determinación coprológica de la parasitofauna en cerdos criollos (Sus scrofa domestica) en el departamento de Córdoba, Colombia. Rev Colombiana Cienc Anim 2015; 7(2): 160-164. http://dx.doi.org/10.24188/recia.v7.n2.2015.257.
http://dx.doi.org/10.24188/recia.v7.n2.2... reported 97.5% of GI parasitism (GIP) prevalence in Colombian creole pigs reared outdoors in the department of Cordoba. In a Mexican study, Kú et al. (2013)Kú R, Trejo W, Aguilar A, Belmar R, Castillo J. Parasitismo gastrointestinal en el cerdo pelón mexicano en traspatio en el estado de Yucatán, México. Rev Colombiana Cienc Anim 2013; 6(1): 17-24. registered a general GIP prevalence of 71.9% in backyard pigs, whilst Cazorla Perfetti et al. (2013)Cazorla Perfetti DJ, Acosta Quintero ME, Tortolero Low JL, Moreno PM. Prevalencia de enteroparásitos porcinos en una comunidad rural de la península de Paraguaná, estado Falcón, Venezuela. Rev Cient FCV-LUZ 2013; 23(1): 19-25. found 66.4% of prevalence for protozoan and helminth parasites in pigs from a rural community in Venezuela, being B. coli (45.38%) the most prevalent endoparasite. In the semi-arid region of northeastern Brazil, de Araújo et al. (2019)de Araújo HG, da Silva JT, Álvares FBV, Ferreira LC, Azevedo SS, Vilela VL. Prevalence and risk factors associated with swine gastrointestinal nematodes and coccidia in the semi-arid region of northeastern Brazil. Trop Anim Health Prod 2019; 52(1): 379-385. http://dx.doi.org/10.1007/s11250-019-02032-8.
http://dx.doi.org/10.1007/s11250-019-020... reported 79.5% prevalence of gastrointestinal parasites, being coccidia (56.6%) the most prevalent parasite recovered, followed by parasites of the Strongylida order (8.1%). Roesel et al. (2017)Roesel K, Dohoo I, Baumann M, Dione M, Grace D, Clausen P-H. Prevalence and risk factors for gastrointestinal parasites in small-scale pig enterprises in Central and Eastern Uganda. Parasitol Res 2017; 116(1): 335-345. http://dx.doi.org/10.1007/s00436-016-5296-7.
http://dx.doi.org/10.1007/s00436-016-529... conducted a study in small pig farms from Central and Eastern Uganda, Africa and reported a GIP prevalence of 61.4%, being parasites of the Strongylida order and Eimeria sp. the most prevalent parasites.

In our country, pig farming is a technified industry that supplies the national market; however, backyard pig farming systems have been an alternative to generate economic income in many families in different regions of the country. The Santander department is located in the Colombian Northeast. This region is characterized by agricultural and cattle livestock production. According to the Colombian Agricultural Institute (ICA) the swine population census for the department was 93,000 pigs, being 85% in backyard and 30% located in the Bucaramanga Metropolitan Area (ICA, 2017Instituto Colombiano Agropecuario – ICA. Vigilancia Epidemiológica. Censo Pecuario Nacional [online]. Bogotá: ICA; 2017 [cited 2020 Feb 5]. Available from: https://www.ica.gov.co/areas/pecuaria/servicios/epidemiologia-veterinaria/censos-2016/censo-2017.aspx
https://www.ica.gov.co/areas/pecuaria/se... ). Generally, this system is associated with a low socio-cultural and human health status, poor facilities, absence of veterinarian, poor sanitary conditions of the pig farms, lack of wastewater treatment, and the development of parasitic diseases in these species, often causing public health and food safety problems. In Colombia, there is little epidemiological information about GIP in pigs, especially in the Northeast region of the country, and for this reason, the aim of the present research was to determine the prevalence of GIP and risk factors in backyard pigs reared in the Bucaramanga Metropolitan Area, Colombia.

Materials and Methods

Study area and sampling design

The research was conducted in backyard pig farms located in the Bucaramanga Metropolitan Area, department of Santander, Northeast of Colombia, which consists in four municipalities: Bucaramanga (7°07′07″N-73°06′58″W), Floridablanca (7°04′11″N-73°05′52″W), Giron (7°04′23″N-73°10′05″W), and Piedecuesta (6°59′19″N-73°03′01″W) (Santander, 2017Santander. Municipios del Departamento de Santander. [online] Santander, Colombia; 2017 [cited 2020 Jan 15]. Available from: http://www.santander.gov.co/index.php/atencion-al-ciudadano/directorios/directorio-municipios
http://www.santander.gov.co/index.php/at... ). This region comprises a geographical area of 1,479 km². Rainfall is regular throughout the year; however, the most of their rainfall from October to December. Bioclimatic characteristics of the region are similar and with a mean annual temperature of 25°C, with little weather variation throughout the year. Altitude is between 600 and 1700 masl and the mean annual rainfall is 1040 mm, with 78% relative humidity (Santander, 2017Santander. Municipios del Departamento de Santander. [online] Santander, Colombia; 2017 [cited 2020 Jan 15]. Available from: http://www.santander.gov.co/index.php/atencion-al-ciudadano/directorios/directorio-municipios
http://www.santander.gov.co/index.php/at... ). Within our study area, there is abundant evidence of backyard pig farms, as illustrated in Figure 1.

Figure 1
Backyard pigs group raised in open-air pens on farms located at the Bucaramanga Metropolitan Area, department of Santander, Colombia.

A random study, descriptive and transversal, was designed. Based in the ICA's vaccination records (ICA, 2017Instituto Colombiano Agropecuario – ICA. Vigilancia Epidemiológica. Censo Pecuario Nacional [online]. Bogotá: ICA; 2017 [cited 2020 Feb 5]. Available from: https://www.ica.gov.co/areas/pecuaria/servicios/epidemiologia-veterinaria/censos-2016/censo-2017.aspx
https://www.ica.gov.co/areas/pecuaria/se... ), the farms were selected for the study using a random number table method based on the geographic location. Thirty-two backyard pig farms were visited between September and December 2019 (wet period). Figure 2 shows the Bucaramanga Metropolitan Area, department of Santander, and the location of the farms surveyed (black dots). Most of the pigs sampled were cross-breeds between the Yorkshire, Landrace and Pietrain breeds. Approximately 5 -10 g of feces were collected weekly from the rectum of each pig, using previously labeled sterile polyethylene bags. In suckling piglets, a swab was introduced rectally to collect a small fecal sample. Samples were placed into containers filled with ice packs and immediately transported to the laboratory for processing. Using the formula for known populations (Thrusfield, 2007Thrusfield M. Veterinary epidemiology. Oxford: Wiley Blackwell; 2007.), with an expected prevalence of 50% (Pulido-Villamarín et al., 2013Pulido-Villamarín A, Barbosa-Buitrago A, Hernández-Gallo N, Mendoza-Gómez M, Ortiz-Rincón I, García-Fonseca S. Potencial zoonotic parasites found in six swine farms of Cundinamarca, Colombia. Neotrop Helminthol 2013; 7(1): 51-63.), and a confidence level of 95% with 6% of associated maximum error, an estimated sample size of 266 fecal samples was required to estimate the gastrointestinal prevalence of parasites in backyard pigs in this region. Fecal samples were collected by proportional affixation of total sample according to the inventory from each examined farm. Therefore, the range was between 4 to 20 samples per farm, with an average of 8.7, providing samples from 279 pigs. The number of pigs to be sampled by sex was defined by a 2:1 ratio (female: male), whilst it was considered a 25% (±5%) frequency of the total sample for each age group.

Figure 2
Bucaramanga Metropolitan Area map showing the locations of the farms surveyed (black dots). Bottom left shows Santander department and Colombia.

Risk factors

Epidemiological data about potential risk factors were obtained using a questionnaire administered to the owner or manager of each herd at the time fecal samples were collected. This data in the questionnaire included: municipality where the farm is located, age group of the examined animals (≤2 months, 3-6 months, 7-12 months, and ≥13 months), sex, i.e. male and females, pigs free-ranging, location of the farm, the quantity of animals of the farm, pig access to latrines, de-wormed, type of feed supplied to the pigs and water source for the animals.

Laboratory analysis

Some of the fecal material was immediately processed for direct examination with lugol´s iodine solution (1:5 dilutions) to determine B. coli and E. coli cysts, as described by Rodríguez-Vivas (2015)Rodríguez-Vivas RI. Técnicas para el diagnóstico de parásitos con importancia en salud pública y veterinaria. México, DF: Ampave-Conasa; 2015. Then, all fecal samples were cultured at room temperature, as described by Pinilla & Da Silva (2019)Pinilla JC, Da Silva N. Infection dynamics of Cystoisospora suis (Isospora suis) on a pilot swine farm in Carabobo State, Venezuela. Rev Mex Cienc Pecu 2019; 10(1): 149-160. http://dx.doi.org/10.22319/rmcp.v10i1.4487.
http://dx.doi.org/10.22319/rmcp.v10i1.44... . A centrifugation-flotation technique and McMaster technique were then used according to Pinilla & Da Silva (2019)Pinilla JC, Da Silva N. Infection dynamics of Cystoisospora suis (Isospora suis) on a pilot swine farm in Carabobo State, Venezuela. Rev Mex Cienc Pecu 2019; 10(1): 149-160. http://dx.doi.org/10.22319/rmcp.v10i1.4487.
http://dx.doi.org/10.22319/rmcp.v10i1.44... and Sandoval et al. (2011)Sandoval E, Morales G, Ybarra N, Barrios M, Borges J. Comparación entre dos modelos diferentes de cámaras de McMaster empleadas para el conteo coproscópico en el diagnóstico de infecciones por nematodos gastroentéricos en rumiantes. Zootec Trop 2011; 29(4): 495-501., respectively. The numbers of opg (oocysts per gram of feces) and epg (eggs per gram of feces) on the McMaster slides were calculated with a detection level of 100 (one chamber) which is the standardized factor for this technique. The intensity of infection was determined as indicated by Sandoval et al. (2011)Sandoval E, Morales G, Ybarra N, Barrios M, Borges J. Comparación entre dos modelos diferentes de cámaras de McMaster empleadas para el conteo coproscópico en el diagnóstico de infecciones por nematodos gastroentéricos en rumiantes. Zootec Trop 2011; 29(4): 495-501.. Finally, the Kinyoun technique was employed to detect Cryptosporidium sp. oocysts, as described by Rodríguez-Vivas (2015)Rodríguez-Vivas RI. Técnicas para el diagnóstico de parásitos con importancia en salud pública y veterinaria. México, DF: Ampave-Conasa; 2015. The parasitic species observed were identified by the morphology of their eggs and oocysts using a light optical microscope with a magnification of 40 and 100x (Rodríguez-Vivas, 2015Rodríguez-Vivas RI. Técnicas para el diagnóstico de parásitos con importancia en salud pública y veterinaria. México, DF: Ampave-Conasa; 2015).

Data analysis

The information obtained through the coprological techniques and epidemiological questionnaires were stored in a database that was created using the Microsoft Excel software. The GIP prevalence was determined by dividing the number of positive animals between the total animal populations of the sampled population. The results obtained were analyzed by descriptive statistics and the Chi square test (X²). Predictor variables with p-value ≤ 0.05 in the Chi-square test (Hosmer & Lemeshow, 2000Hosmer DW, Lemeshow S. Applied logistic regression. New York: John Wiley e Sons; 2000. http://dx.doi.org/10.1002/0471722146.
http://dx.doi.org/10.1002/0471722146... ) were selected for multiple analysis using logistic regression with confidence intervals (95% confidence level). The level of significance for the analyzes was 5%. Calculations were made using the SPSS v.20.0 software (© 2011 IBM corporation, United States)

Ethical statement

The present study was approved by the Ethics Committee of the University of Santander, under initiation act no. CIF0311-19.

Results

The overall prevalence of GIP in the Bucaramanga Metropolitan Area was 91% (254/279). No statistical association was found (X² = 0.76; p ≥ 0.05) between prevalence values in the four municipalities: 89.2% (83/93) in Bucaramanga, 91.5% (43/47) in Floridablanca, 91.1% (72/79) in Giron and 93.3% (56/60) in Piedecuesta. With regard to the farms, at least one pig was positive for GIP on each examined farm, with 71.9% of farms positive to nematodes and 100% to protozoan.

Table 1 shows the 9 parasite species found in the study, being B. coli, Eimeria sp., E. coli, and parasites of the order Strongylida being the most prevalent. With concerning to intensity of infection, S. ransomi showed the highest level, followed by A. suum, Eimeria sp. oocysts and T. suis. Cryptosporidium sp. oocysts were not counted. No clinical signs of parasitic infection were observed in examined pigs. In most (78.1%) of the fecal samples examined, two or more parasite genus were evidenced, whilst in 21.9% of the cases, just one parasite genera were found.

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Table 1
Prevalence and intensity of gastrointestinal parasites obtained from the fecal samples of backyard pigs in the Bucaramanga Metropolitan Area, department of Santander, Colombia.

Table 2 and Table 3 shows the analysis of the owner´s information (epidemiological data) associated with nematode and protozoan infections in backyard pigs, respectively. In the univariate analysis, most categories for nematodes parasitism showed p≤0.05, except for the number of pigs. Regarding coccidian infections, categories that showed p ≤ 0.05 were Giron municipality, pigs > 7 months, the altitude at <1000 masl, and de-worming of the animals, whilst for E. coli were Floridablanca municipality and altitude at >1000 masl. Cryptosporidium sp. showed a statistical association with pig access to latrines, while B. coli did not show a statistical association with any category.

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Table 2
Association between risk factors and nematode parasitism in backyard pigs reared in the Bucaramanga Metropolitan Area.

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Table 3
Association between risk factors and protozoan infection in backyard pigs reared in the Bucaramanga Metropolitan Area.

Regarding risk factors (Table 4) for the occurrence of nematodes parasitism, pigs from Floridablanca and Giron municipalities showed 41.5 (OR = 41.5, CI95% = 20.1-54.3) and 2.1 (OR = 2.1, CI95% = 1.01-4.3) times higher risk of infection, respectively. Free-ranging pigs and access to latrines showed 1.96 (OR = 1.96, CI95% = 0.8-2.34) and 1.91 (OR = 1.91, CI95% = 0.75-3.2) times higher probability for infection, respectively. Animals consuming spring water showed 15.8 (OR = 15.8, CI95% = 4.8-52.2) times higher probability for infection. For coccidian infections, pigs from Giron municipality showed 2.2 (OR = 2.2, CI95% = 1.2-4.1) times higher probability of infection, whilst animals from 7 to 12 months and ≥13 months showed 2.8 (OR = 2.8, CI95% = 1.4-5.2) and 2.3 times higher risk for coccidian infections, respectively. Those pigs with access to latrines had 4.5 times more likely to be exposed (OR= 4.5, CI95% = 1.3-15.5) for Cryptosporidium sp. infection

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Table 4
Multiple analysis regression of the risk factors associated with nematode and protozoan infection in backyard pigs reared in the Bucaramanga Metropolitan Area.

Discussion

The GIP in pigs is considered one of the most important problems in pig farming since they causing reduce weight, organ condemnation, high morbidity in young animals and even death in severe cases (Cordero & Rojas, 1999Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999.; Kagira et al., 2012Kagira JM, Kanyari PN, Githigia SM, Maingi N, Nganga JC, Gachohi JM. Risk factors associated with occurrence of nematodes in free range pigs in Busia District, Kenya. Trop Anim Health Prod 2012; 44(3): 657-664. http://dx.doi.org/10.1007/s11250-011-9951-9.
http://dx.doi.org/10.1007/s11250-011-995... ). In Colombia, there is little epidemiological information on GIP in pigs, at least in the consulted literature and for this reason, the data about the GIP in pigs are still unknown.

The prevalence of GIP found in the four municipalities were similar, since the temperature and humidity conditions in the zone, the management in most of the farms as well as the programs in the control of infectious agents are very much the same in the four municipalities (Cordero & Rojas, 1999Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999.). On the other hand, the high individual prevalence of GIP found in this study indicates the absence of hygienic and sanitary management in the examined farms, where some risk factors may have favored the dissemination and transmission of parasites among animals. The results obtained in this research agree with those reported by Kú et al. (2013)Kú R, Trejo W, Aguilar A, Belmar R, Castillo J. Parasitismo gastrointestinal en el cerdo pelón mexicano en traspatio en el estado de Yucatán, México. Rev Colombiana Cienc Anim 2013; 6(1): 17-24. who found a prevalence of 71.9% in backyard farms in the state of Yucatan, Mexico. Furthermore, the result obtained agree with those from Cazorla Perfetti et al. (2013)Cazorla Perfetti DJ, Acosta Quintero ME, Tortolero Low JL, Moreno PM. Prevalencia de enteroparásitos porcinos en una comunidad rural de la península de Paraguaná, estado Falcón, Venezuela. Rev Cient FCV-LUZ 2013; 23(1): 19-25., who reported similar values of prevalence for protozoan and helminths in pigs from a rural community in Venezuela. Similarly, the high prevalence of GIP found in the present study, agree with the findings of Herrera et al. (2015)Herrera BY, Almanza PM, Ensuncho HC, Goméz ML, Galeano EM. Determinación coprológica de la parasitofauna en cerdos criollos (Sus scrofa domestica) en el departamento de Córdoba, Colombia. Rev Colombiana Cienc Anim 2015; 7(2): 160-164. http://dx.doi.org/10.24188/recia.v7.n2.2015.257.
http://dx.doi.org/10.24188/recia.v7.n2.2... in Colombia, Roesel et al. (2017)Roesel K, Dohoo I, Baumann M, Dione M, Grace D, Clausen P-H. Prevalence and risk factors for gastrointestinal parasites in small-scale pig enterprises in Central and Eastern Uganda. Parasitol Res 2017; 116(1): 335-345. http://dx.doi.org/10.1007/s00436-016-5296-7.
http://dx.doi.org/10.1007/s00436-016-529... in Uganda, and de Araújo et al. (2019)de Araújo HG, da Silva JT, Álvares FBV, Ferreira LC, Azevedo SS, Vilela VL. Prevalence and risk factors associated with swine gastrointestinal nematodes and coccidia in the semi-arid region of northeastern Brazil. Trop Anim Health Prod 2019; 52(1): 379-385. http://dx.doi.org/10.1007/s11250-019-02032-8.
http://dx.doi.org/10.1007/s11250-019-020... in Brazil, who reported 97.5%, 61.4% and 79.5% prevalence of gastrointestinal parasites, respectively.

The present study found 9 parasitic species, being protozoan infections the most prevalent. In addition, some of these protozoan (B. coli and E. coli) are zoonotic in nature and can infect humans. The results obtained in this study agree with those of Pinto et al. (2007)Pinto JM, Costa JO, Souza JC. Ocorrência de endoparasitos em suínos criados em Itabuna, Bahia, Brasil. Ciênc Vet Tróp 2007; 10(2-3): 79-85., who reported the same number of parasitic species (9). Also, these results agree with those of Herrera et al. (2015)Herrera BY, Almanza PM, Ensuncho HC, Goméz ML, Galeano EM. Determinación coprológica de la parasitofauna en cerdos criollos (Sus scrofa domestica) en el departamento de Córdoba, Colombia. Rev Colombiana Cienc Anim 2015; 7(2): 160-164. http://dx.doi.org/10.24188/recia.v7.n2.2015.257.
http://dx.doi.org/10.24188/recia.v7.n2.2... , who reported more than 12 parasite genera in their studies. According to Cordero & Rojas (1999)Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999., mixed parasitic infections in pigs are very common in backyard pig farming, and it seems to be an indication of high environmental pollution of the pig population (Herrera et al., 2015Herrera BY, Almanza PM, Ensuncho HC, Goméz ML, Galeano EM. Determinación coprológica de la parasitofauna en cerdos criollos (Sus scrofa domestica) en el departamento de Córdoba, Colombia. Rev Colombiana Cienc Anim 2015; 7(2): 160-164. http://dx.doi.org/10.24188/recia.v7.n2.2015.257.
http://dx.doi.org/10.24188/recia.v7.n2.2... ), whilst monospecies infections are less frequent, and are registered for the effect of climate change in a given region, as well as, in hosts under intensive parasite control. In the present study, 78.1% of the pigs examined were parasitized by two or more parasite genus, whilst 21.9% had one parasite genera. This result agrees with those recorded by Cazorla Perfetti et al. (2013)Cazorla Perfetti DJ, Acosta Quintero ME, Tortolero Low JL, Moreno PM. Prevalencia de enteroparásitos porcinos en una comunidad rural de la península de Paraguaná, estado Falcón, Venezuela. Rev Cient FCV-LUZ 2013; 23(1): 19-25. and Herrera et al. (2015)Herrera BY, Almanza PM, Ensuncho HC, Goméz ML, Galeano EM. Determinación coprológica de la parasitofauna en cerdos criollos (Sus scrofa domestica) en el departamento de Córdoba, Colombia. Rev Colombiana Cienc Anim 2015; 7(2): 160-164. http://dx.doi.org/10.24188/recia.v7.n2.2015.257.
http://dx.doi.org/10.24188/recia.v7.n2.2... , who found a high degree of polyparasitism in their studies. This could be due to the fact that backyard pig rearing system allows that all age groups of animals are raised together, increasing the dissemination odds of mixed infections in all animals. Although the mean intensity of infection for B. coli and E. coli found in this study, are considered mild, a more severe infection was observed for Eimeria sp., S. ransomi and A. suum, however, no clinical signs were observed in the examined pigs. According to Aguiar (2009)Aguiar CI. Aspectos epidemiológicos das parasitoses gastrintestinais de suínos naturalizados de criações familiares do Distrito Federal [dissertação]. Brasília: Universidade de Brasília; 2009. and de Araújo et al. (2019)de Araújo HG, da Silva JT, Álvares FBV, Ferreira LC, Azevedo SS, Vilela VL. Prevalence and risk factors associated with swine gastrointestinal nematodes and coccidia in the semi-arid region of northeastern Brazil. Trop Anim Health Prod 2019; 52(1): 379-385. http://dx.doi.org/10.1007/s11250-019-02032-8.
http://dx.doi.org/10.1007/s11250-019-020... , subclinical infections are important and can be frequent, affecting animals by causing loss of appetite, low weight gain, and reduced feed conversion.

The present study found that B. coli was most prevalent (52.7%), followed by Eimeria sp. (50.2%) and E. coli (33.7%). These results obtained agree with those recorded by Pinto et al. (2007)Pinto JM, Costa JO, Souza JC. Ocorrência de endoparasitos em suínos criados em Itabuna, Bahia, Brasil. Ciênc Vet Tróp 2007; 10(2-3): 79-85., who revealed similar values of prevalence in these parasites. Similarly, the results obtained in this study agree with those reported of Cazorla Perfetti et al. (2013)Cazorla Perfetti DJ, Acosta Quintero ME, Tortolero Low JL, Moreno PM. Prevalencia de enteroparásitos porcinos en una comunidad rural de la península de Paraguaná, estado Falcón, Venezuela. Rev Cient FCV-LUZ 2013; 23(1): 19-25. and Gúzman et al. (2013)Guzmán RC, Nessi PA, González OH, Hernández MO, Galindo M, Dorta A, et al. Balantidium spp in pigs and their keepers: Prevalence in communities of two States of Venezuela. VITAE Acád Biom Dig 2013; 54., who found similar prevalence values for B. coli in outdoor pigs from Venezuela. However, the results obtained differ from those reported of Mendoza-Gómez et al. (2015)Mendoza-Gómez M, Pulido-Villamarín A, Barbosa-Buitrago A, Aranda-Silva M. Presence of gastrointestinal parasites in swine and human of four swine production farms in Cundinamarca- Colombia. Rev Mvz Cordoba 2015; 20(1): 5014-5027. http://dx.doi.org/10.21897/rmvz.15.
http://dx.doi.org/10.21897/rmvz.15... , who found 5% of prevalence for B. coli in farms from Cundinamarca state, Colombia. The prevalence of E. coli in the present study was 33.7%, and this result agrees with those reported by Mendoza-Gómez et al. (2015)Mendoza-Gómez M, Pulido-Villamarín A, Barbosa-Buitrago A, Aranda-Silva M. Presence of gastrointestinal parasites in swine and human of four swine production farms in Cundinamarca- Colombia. Rev Mvz Cordoba 2015; 20(1): 5014-5027. http://dx.doi.org/10.21897/rmvz.15.
http://dx.doi.org/10.21897/rmvz.15... , who found 40% of prevalence in pigs from Cundinamarca state. Although E. coli do not cause infection, their presence indicates the fecal-oral transmission in the host, which is an indicator for the general assessment of the hygiene status of the animals. The high prevalence mentioned, could be caused for the ingestion of contaminated water or food, or by immunosuppression in the animals due to factors like stress associated with overcrowding.

In relation to Cryptosporidium sp. the prevalence rate found was 5.7% (16/279). This result agrees with those of Mendoza-Gómez et al. (2015)Mendoza-Gómez M, Pulido-Villamarín A, Barbosa-Buitrago A, Aranda-Silva M. Presence of gastrointestinal parasites in swine and human of four swine production farms in Cundinamarca- Colombia. Rev Mvz Cordoba 2015; 20(1): 5014-5027. http://dx.doi.org/10.21897/rmvz.15.
http://dx.doi.org/10.21897/rmvz.15... , who found similar prevalence values in semi-technified farms. Cryptosporidium sp. infections are common in pigs and have been found in all age groups worldwide. Although the age distribution of Cryptosporidium infection rates in pigs has not been clearly concluded, it can be assumed that the prevalence in pigs aged 1–2 months is greater than that of other age groups by the weaning effect (Zheng et al., 2019Zheng S, Li D, Zhou C, Zhang S, Wu Y, Chang Y, et al. Molecular identification and epidemiological comparison of Cryptosporidium spp. among different pig breeds in Tibet and Henan, China. BMC Vet Res 2019; 15(1): 101. http://dx.doi.org/10.1186/s12917-019-1847-3.
http://dx.doi.org/10.1186/s12917-019-184... ). Cryptosporidiosis is a disease of high zoonotic importance, known as a public health problem, that affects mainly people that interact with farm animals daily. Therefore, it is important to demonstrate the presence of this pathogen with zoonotic potential, to take measures such as strengthening the breeding management of pigs and improving the sanitary control to avoid the spread of pathogens (Zheng et al., 2019Zheng S, Li D, Zhou C, Zhang S, Wu Y, Chang Y, et al. Molecular identification and epidemiological comparison of Cryptosporidium spp. among different pig breeds in Tibet and Henan, China. BMC Vet Res 2019; 15(1): 101. http://dx.doi.org/10.1186/s12917-019-1847-3.
http://dx.doi.org/10.1186/s12917-019-184... ).

As for the nematode groups, parasite genera grouped under the Strongylida order showed the highest prevalence values in this group (12.9%), whilst S. ransomi showed low prevalence (4.3%) and the frequency was moderate (18.7%). This could be since during the life cycle of Strongyloides sp., cutaneous and colostral transmission is possible and, poor hygiene conditions in the farms favor a greater risk of infection of the pigs. The prevalence of A. suum (3.9%) and T. suis (1.8%) were low. These results could be due to the fact that the pig can develop an immune response to these parasites, however, residual loads may remain in the infected animals (Murrell, 1986Murrell KD. Epidemiology, pathogenesis and control of major swine helminth parasites. Vet Clin North Am Food Anim Pract 1986; 2(2): 439-454. http://dx.doi.org/10.1016/S0749-0720(15)31255-X.
http://dx.doi.org/10.1016/S0749-0720(15)... ; Kringel & Roepstorff, 2006Kringel H, Roepstorff A. Trichuris suis population dynamics following a primary experimental infection. Vet Parasitol 2006; 139(1-3): 132-139. http://dx.doi.org/10.1016/j.vetpar.2006.03.002.
http://dx.doi.org/10.1016/j.vetpar.2006.... ; Nejsum et al., 2009Nejsum P, Roepstorff A, Jørgensen CB, Fredholm M, Göring HHH, Anderson TJC, et al. High heritability for Ascaris and Trichuris infection levels in pigs. Heredity 2009; 102(4): 357-364. http://dx.doi.org/10.1038/hdy.2008.131.
http://dx.doi.org/10.1038/hdy.2008.131... ; Nwafor et al., 2019Nwafor IC, Roberts H, Fourie P. Prevalence of gastrointestinal helminths and parasites in smallholder pigs reared in the central Free State Province. Onderstepoort J Vet Res 2019; 86(1): a1687. http://dx.doi.org/10.4102/ojvr.v86i1.1687.
http://dx.doi.org/10.4102/ojvr.v86i1.168... ).

Regarding risk factors associated with gastrointestinal nematodes, backyard pigs from Floridablanca municipality had a 41.5 (OR = 41.5; p ≤ 0.05) times higher risk of infection than other locations. This municipality is located at medium altitudes (1000 to 1700 masl), with mean annual temperature (25 to 30 °C) long the year, with prolonged periods of rain and average precipitation rates between 1100 and 1400 mm, which are favorable climatological conditions for the presence of GIP and increased risk of infection for the animals. Free-ranging pigs and access to latrines showed to be a risk factor for nematode infection. These results agree with those reported by Thomas et al. (2013)Thomas LF, de Glanville WA, Cook EA, Fèvre EM. The spatial ecology of free-ranging domestic pigs (Sus scrofa) in western Kenya. BMC Vet Res 2013;9:46. https://doi.org/10.1186/1746-6148-9-46.
https://doi.org/10.1186/1746-6148-9-46... , who found a positive correlation between the Ascaris sp. infection and the interacting with latrines, and a moderate positive correlation between coccidia infection and home range area. Probably, pigs free-ranging when have access to latrines could have higher contact with paratenic hosts as earthworms or scarabaeus, and therefore, increase the parasitic disease transmission risk to the pig itself and, to other wild and domestic animals, even humans (Thomas et al., 2013Thomas LF, de Glanville WA, Cook EA, Fèvre EM. The spatial ecology of free-ranging domestic pigs (Sus scrofa) in western Kenya. BMC Vet Res 2013;9:46. https://doi.org/10.1186/1746-6148-9-46.
https://doi.org/10.1186/1746-6148-9-46... ).

The consumption of spring water showed 15.8 times increased risk of infection for gastrointestinal nematodes. A study conducted by Morales et al. (2015)Morales R, Rebatta M, Lucas J, Mateo J, Ramos D. Caracterización de la crianza no tecnificada de cerdos en el parque porcino del distrito de Villa el Salvador, Lima-Perú. Salud Tecnol Vet 2015; 2(1): 39-48. http://dx.doi.org/10.20453/stv.v2i1.2206.
http://dx.doi.org/10.20453/stv.v2i1.2206... revealed that most of the backyard pig farming had no solid effluents treatment, since they keep them inside or outside the farm, causing serious problems of spring water contamination, flies and pathogens, and a health problem for people and animals. Therefore, polluted spring water can transmit lots of pathogens with various behaviors and resistance to various environmental factors. Probably, the lack of wastewater treatment in backyard pig farming represents a serious environmental and social problems due to the contamination of the spring water and soil that are around it, which are also accompanied by swine waste odor (Morales et al., 2015)Morales R, Rebatta M, Lucas J, Mateo J, Ramos D. Caracterización de la crianza no tecnificada de cerdos en el parque porcino del distrito de Villa el Salvador, Lima-Perú. Salud Tecnol Vet 2015; 2(1): 39-48. http://dx.doi.org/10.20453/stv.v2i1.2206.
http://dx.doi.org/10.20453/stv.v2i1.2206... .

In relation to coccidian infections, the animals raised in farms from Giron municipality had 2.2 times the risk of becoming infected than pigs from other locations. According to Cordero & Rojas (1999)Cordero CM, Rojas F. Parasitología Veterinaria. España: Mc Graw Hill; 1999., Eimeria sp. and C. suis oocysts are favored by rainfall and temperature of the zone, poor facilities and poor hygiene of the farm, as well as, the high biotic potential of the coccidia. Probably, the high prevalence (64.6%) of these protozoans found in this study is associated with the wet period of the year when fecal samples were collected, since in this municipality was observed the most rainfall during the sampling period. Moreover, most of the examined farms in this municipality showed poor facilities and poor hygienic and sanitary conditions. The animals > 7 months of age showed to be a risk factor for coccidian infections and could behave as asymptomatic carriers and act as a potential source of infection for piglets, causing eimeriosis, since they become infected by ingesting sporulated oocysts with feed or water, or by any parasitic dissemination mechanism such as people, overall, boots and intermediate host (Quiroz et al., 2011Quiroz H, Figueroa J, Ibarra F, López M. Epidemiología de enfermedades parasitarias en animales domésticos. México, DF: Revista Facultad Medicina Veterinaria y Zootecnia UNAM; 2011.).

In our study, the access to latrines showed to be a risk factor (OR= 4.5; p ≤ 0.05) for Cryptosporidium sp. in pigs, since this pathogen is transmitted via the fecal-oral route in humans and animals, usually through the ingestion of contaminated water or food with feces (Chacín-Bonilla et al., 2008Chacín-Bonilla L, Barrios F, Sanchez Y. Environmental risk factors for Cryptosporidium infection in an island from Western Venezuela. Mem Inst Oswaldo Cruz 2008; 103(1): 45-49. http://dx.doi.org/10.1590/S0074-02762008005000007.
http://dx.doi.org/10.1590/S0074-02762008... ). Probably, the contact with infective human fecal material by pigs is an important requisite for the successful maintenance of the parasite lifecycle, therefore, it would be to think stands to reason that keeping free-ranging pigs in contact with latrines, it would increase the risk of the pigs in acquiring this infection, as in other parasitic infections (Thomas et al., 2013Thomas LF, de Glanville WA, Cook EA, Fèvre EM. The spatial ecology of free-ranging domestic pigs (Sus scrofa) in western Kenya. BMC Vet Res 2013;9:46. https://doi.org/10.1186/1746-6148-9-46.
https://doi.org/10.1186/1746-6148-9-46... ). In developing countries, the environmental risk factors and routes of transmission for Cryptosporidium sp. infection are not well defined. Despite the numerous surveillance studies reported, few investigations have been conducted about the source of infection. However, contamination of water supplies and infection of domestic animals, lacking adequate municipal water and sewage services, and using a field or latrine for defecation in human communities were correlated with a higher risk of cryptosporidiosis (Chacín-Bonilla et al., 2008Chacín-Bonilla L, Barrios F, Sanchez Y. Environmental risk factors for Cryptosporidium infection in an island from Western Venezuela. Mem Inst Oswaldo Cruz 2008; 103(1): 45-49. http://dx.doi.org/10.1590/S0074-02762008005000007.
http://dx.doi.org/10.1590/S0074-02762008... ).

Conclusion

It was concluded that the high overall prevalence of GI parasitism reported in this study could be due to poor facilities, and lack of hygiene in the facilities. To our knowledge, the present research recorded B. coli, E. coli, and Cryptosporidium sp. for the first time in the region under study, and suggests the possible transmission of these parasite populations between pigs and humans thus increasing the transmission of parasites zoonotic potential. The relevant risk factors for nematodes included free-ranging pigs and consumption of spring water, while for Cryptosporidium sp., access to latrines was a relevant risk factor

Acknowledgements

The authors thank the University of Santander, Colombia for financial support for this project. The authors thank the staff of Veterinary Clinic Research Laboratory of the University of Santander, Colombia for their help in the conduction of this project.

How to cite: Pinilla JC, Morales E, Delgado NU, Florez AA. Prevalence and risk factors of gastrointestinal parasites in backyard pigs reared in the Bucaramanga Metropolitan Area, Colombia. Braz J Vet Parasitol 2020; 29(4): e015320. https://doi.org/10.1590/S1984-29612020094

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Publication Dates

Publication in this collection
20 Nov 2020
Date of issue
2020

History

Received
30 June 2020
Accepted
22 Sept 2020

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] How to cite: Pinilla JC, Morales E, Delgado NU, Florez AA. Prevalence and risk factors of gastrointestinal parasites in backyard pigs reared in the Bucaramanga Metropolitan Area, Colombia. Braz J Vet Parasitol 2020; 29(4): e015320. https://doi.org/10.1590/S1984-29612020094

Risk factors	Categories	N°	Positive (%)	p-value
Municipality	B/manga	93	64 (68.8)
	Floridablanca	47	47 (100)
	Piedecuesta	60	7 (11.7)
	Giron	79	65 (82.3)	0.000^* * Variables that presented a value of p≤0.05 by the Chi-square test.
Age group	≤2 months	71	54 (76.1)
	3-6 months	49	23 (46.9)
	7-12 months	88	67 (76.1)
	≥13 months	71	39 (54.9)	0.000*
Sex	Male	107	79 (73.8)
	Female	172	104 (60.5)	0.02*
Altitude	<1000	139	122 (87.8)
	>1000	140	61 (43.6)	0.00*
Free-ranging pigs	No	213	117 (54.9)
	Yes	66	66 (100)	0.00*
Access to latrines	No	257	161 (62.6)
	Yes	22	22 (100)	0.00*
Number of pigs	<10	82	60 (73.2)
	>10	197	123 (62.4)	0.09
De-worming	No	17	17 (100)
	Yes	262	166 (63.4)	0.002*
Type of food	Restaurant residues	60	41 (68.3)
	Concentrate	56	19 (33.9)
	Mixed	163	123 (75.5)	0.000*
Water source	Deep well water	214	121 (56.5)
	Spring water	65	62 (95.4)	0.000*

			Coccidia ^ As Coccidia (Eimeria sp. and Cystoisospora suis)		Cryptosporidium sp.		*Balantidium coli*		*Entamoeba coli*
Risk factors	Categories	N°	Positive (%)	p-value	Positive (%)	p-value	Positive (%)	p-value	Positive (%)	p-value
Municipality	B/manga	93	42 (45.2)		6 (6.5)		44 (47.3)		18 (19.4)
	Floridablanca	47	19 (40.4)		4 (8.5)		27 (57.4)		23 (48.9)
	Piedecuesta	60	30 (50)		2 (3.3)		31 (51.7)		22 (36.7)
	Giron	79	51 (64.6)	0.03^* * Variables that presented a value of p≤0.05 by the Chi-square test.	4 (5.1)	0.69	45 (57)	0.55	31 (39.2)	0.002*
Age group	≤2 months	71	26 (36.6)		2 (2.8)		35 (49.3)		23 (32.4)
	3-6 months	49	22 (44.9)		1 (2)		22 (44.9)		14 (28.6)
	7-12 months	88	54 (61.4)		9 (10.2)		50 (56.8)		31 (35.2)
	≥13 months	71	40 (56.3)	0.01*	4 (5.6)	0.13	40 (56.3)	0.47	26 (36.6)	0.8
Sex	Male	107	51 (47.7)		7 (6.5)		60 (56.1)		36 (33.6)
	Female	172	91 (52.9)	0.39	9 (5.2)	0.65	87 (50.6)	0.37	58 (33.7)	0.9
Altitude	<1000	139	84 (60.4)		7 (5)		68 (48.9)		39 (28.1)
	>1000	140	58 (41.4)	0.02*	9 (6.4)	0.62	79 (56.4)	0.21	55 (39.3)	0.04*
Free-ranging pigs	No	213	113 (53.1)		12 (5.6)		112 (52.6)		69 (32.4)
	Yes	66	29 (43.9)	0.19	4 (6.1)	0.89	35 (53)	0.95	25 (37.9)	0.41
Access to latrines	No	257	134 (52.1)		12 (4.7)		133 (51.8)		88 (34.2)
	Yes	22	8 (36.4)	0.15	4 (18.2)	0.009*	14 (63.6)	0.28	6 (27.3)	0.5
Number of pigs	<10	82	38 (46.3)		8 (9.8)		40 (48.8)		24 (29.3)
	>10	197	104 (52.8)	0.32	8 (4.1)	0.06	107 (54.3)	0.4	70 (35.5)	0.31
De-worming	No	17	2 (11.8)		1 (5.9)		9 (52.9)		6 (35.3)
	Yes	262	140 (53.4)	0.01*	15 (5.7)	0.9	138 (52.7)	0.9	88 (33.6)	0.88
Type of food	Restaurant residues	60	26 (43.3)		2 (3.3)		34 (56.7)		24 (40)
	Concentrate	56	34 (60.7)		2 (3.6)		26 (46.4)		12 (21.4)
	Mixed	163	82 (50.3)	0.17	12 (7.4)	0.38	87 (53.4)	0.5	58 (35.6)	0.08
Water source	Spring water	65	28 (43.1)		2 (3.1)		30 (46.2)		22 (33.8)
	Deep well water	214	114 (53.3)	0.15	14 (6.5)	0.3	117 (54.7)	0.2	72 (33.6)	0.9

Risk factors	B	E. T	Exp(β)	CI (95%)	p-value
Nematodes
Floridadablanca municipality	20.4	58.6	41.5	20.1-54.3	0.000
Free-ranging pigs (yes)	0.65	0.1	1.96	0.8-2.34	0.000
Access to latrines (yes)	0.6	0.12	1.91	0.75-3.2	0.01
Spring water	2.7	0.67	15.8	4.8-52.2	0.02

Coccidia ^* * as Coccidia (Eimeria sp. and Cystoisospora suis).

Giron municipality	0.8	0.3	2.2	1.2-4.1	0.01
7-12 months of age	1.01	0.33	2.8	1.4-5.2	0.002
≥13 months of age	0.8	0.34	2.3	1.1-4.3	0.02

Cryptosporidium sp.
Access to latrines (yes)	1.5	0.63	4.5	1.3-15.5	0.01

Parasite	Positive (n=279)	Prevalence (%)	Intensity of infection (opg – epg)
Protozoan group
Balantidium coli	147	52.7	260.3
Eimeria sp.	140	50.2	1230
Entamoeba coli	94	33.7	100
Cryptosporidium sp.	16	5.7	^* * Cryptosporidium sp. was no counted
Cystoisospora suis	5	1.8	357.1

Nematodes group
Strongylida^ as Strongylida order	36	12.9	244.4
Strongyloides ransomi	12	4.3	3762.5
Ascaris suum	11	3.9	2150
Trichuris suis	5	1.8	400

Brasil

Brasil

Prevalence and risk factors of gastrointestinal parasites in backyard pigs reared in the Bucaramanga Metropolitan Area, Colombia

Prevalência e fatores de risco de parasitos gastrointestinais em suínos criados na Área Metropolitana de Bucaramanga, Colombia

Abstract

Resumo

Introduction

Materials and Methods

Study area and sampling design

Risk factors

Laboratory analysis

Data analysis

Ethical statement

Results

Discussion

Conclusion

Acknowledgements

References

Publication Dates

History