Infectious Causes of Abortion, Stillbirth and Neonatal Death in Bitches

Problems in gestational development in dogs can be determined by infectious and non‐infectious causes. Among the non‐infectious causes, trauma during pregnancy, genetic characteristics of the animal, deficit nutrition, thyroid dysfunction, maternal problems and hormonal disorders are found. The majority of the cases are in relation to infectious diseases, one should consider viral, bacterial, fungal and protozoal, which can interfere directly or indirectly in the foetal development. The progression of foetal development may be affected by the direct action of the microorganisms to overcome the placenta, but they are also able to affect pregnancy and release placental toxins by inflammatory processes and, may still cause maternal pathologies, which entail problems such as hyperthermia, hypoxia and endotoxemia, which can result in abortion. Several diseases can trigger pregnancy loss in dogs. This action can be direct by microorganisms, as well as indirectly triggering other problems that lead to abortion. This chapter discusses the infectious aetiologies of reproductive failures (abortion, stillbirth and neonatal death) in bitches

Occurrence of Apicomplexa protozoa in wild birds in the Northeast region of Brazil

Abstract Protozoa of the Apicomplexa phylum are worldwide distributed with capacity to infect endothermic animals. The study of these protozoa in wild birds in Brazil is scarce. This study aimed to evaluate the occurrence of apicomplexan protozoa in wild birds in the Northeast of Brazil. From October to December 2019, brain tissue samples were collected from 71 captive birds from the Wild Animal Screening Center of the Pernambuco State (CETRAS-Tangara) and 25 free-living birds from the Caatinga biome in Rio Grande do Norte, totaling 96 animals (41 species). Brain fragments were subjected to molecular diagnosis by nested PCR for the 18s rDNA gene of Apicomplexa parasites, followed by DNA sequencing. This gene was detected in 25% (24/96) of the samples, and it was possible to perform DNA sequencing of 14 samples, confirming three genera: Isospora, Sarcocystis and Toxoplasma from eight bird species (Amazona aestiva, Coereba flaveola, Egretta thula, Paroaria dominicana, Sporophila nigricollis, Cariama cristata, Columbina talpacoti, Crypturellus parvirostris). The occurrence these coccidia in wild birds provides important epidemiological information for the adoption of preventive measures for its conservation. Future studies are needed to better understand the consequence of Apicomplexa infection in birds in Caatinga and Atlantic Forest biomes

Risk factors for trypanosomiasis by Trypanosoma vivax in cattle raised in Rio Grande do Norte state

ABSTRACT: The objective of this study was to determine the prevalence of anti Trypanosoma vivax antibodies and the possible risk factors associated with the infection in cattle in Rio Grande do Norte, Northeastern Brazil, through a cross-sectional epidemiological study, with non-probabilistic convenience sampling. A total of 467 cattle’s serum samples were analyzed by indirect immunofluorescence. Forty-two samples tested positive for Trypanosoma vivax IgG antibodies, corresponding to the prevalence of 9%. Risk factors influencing the occurrence of trypanosomiasis were milk exploration, raising of European breeds, productivity category: lactation cow, purchase of new cattle, foraging habits near ponds and rivers, and the presence of mechanical vectors. So, high prevalence in beef animals (59.5%), females (95.2%), European breed (88.1%), lactating cows (85.7%), pasture at banks of dams and rivers (95.2%), in addition to the presence of mechanical vectors (81%) and acquisition of animals (88.1%), indicates the expansion of trypanosomiasis in Northeastern semi-arid region, and the information obtained may explain the epidemiological factors that determine the occurrence of trypanosomiasis by T. vivax in this region

Serological and molecular detection of infection with Mycobacterium leprae in Brazilian six banded armadillos (Euphractus sexcinctus)

Federal Rural University of Rio de Janeiro. Institute of Veterinary Medicine. Department of Animal Parasitology. Multiuser Molecular Biology Laboratory. Seropédica, RJ, Brazil.Fundação Oswaldo Cruz. Oswaldo Cruz Institute. Laboratory of Cellular Microbiology. Rio de Janeiro, RJ, Brazil.Fundação Oswaldo Cruz. Oswaldo Cruz Institute. Laboratory of Cellular Microbiology. Rio de Janeiro, RJ, Brazil.Federal Rural University of Semi-Árido. Hospital Veterinary. Rio Grande do Norte, RN, Brazil.Federal Rural University of Semi-Árido. Hospital Veterinary. Rio Grande do Norte, RN, Brazil.Federal Rural University of Semi-Árido. Hospital Veterinary. Rio Grande do Norte, RN, Brazil.National Hansen's Disease Program. Healthcare Systems Bureau. Health Resources and Services Administration. Department of Health and Humans Services. Baton Rouge, United States.National Hansen's Disease Program. Healthcare Systems Bureau. Health Resources and Services Administration. Department of Health and Humans Services. Baton Rouge, United States.National Hansen's Disease Program. Healthcare Systems Bureau. Health Resources and Services Administration. Department of Health and Humans Services. Baton Rouge, United States.Infectious Disease Research Institute. Seattle, United States.Ministério da Saúde. Secretaria de Vigilância em Saúde. Instituto Evandro Chagas. Laboratório de Geoprocessamento. Ananindeua, PA, Brasil.Fundação Oswaldo Cruz. Oswaldo Cruz Institute. Laboratory of Molecular Biology Applied to Mycobacteria. Rio de Janeiro, RJ, Brazil.Fundação Oswaldo Cruz. Oswaldo Cruz Institute. Laboratory of Molecular Biology Applied to Mycobacteria. Rio de Janeiro, RJ, Brazil.Federal Rural University of Rio de Janeiro. Institute of Veterinary Medicine. Department of Animal Parasitology. Multiuser Molecular Biology Laboratory. Seropédica, RJ, Brazil.Leprosy was recognized as a zoonotic disease, associated with nine-banded armadillos (Dasypus novemcinctus) in the Southern United States of America in 2011. In addition, there is growing evidence to support a role for armadillos in zoonotic leprosy in South America. The current study evaluated twenty specimens of the six-banded armadillo (Euphractus sexcinctus), collected from rural locations in the state of Rio Grande do Norte (RN), Brazil for evidence of infection with Mycobacterium leprae. Serum was examined using two "in-house" enzyme-linked immunosorbent assays (ELISAs) and via two commercially available (ML flow and NDO-LID®) immunochromatographic lateral flow (LF) tests, for detection of the PGL-I and/or LID-1 antigens of the bacterium. The presence of M. leprae DNA in liver tissue was examined using the multi-copy, M. leprae-specific repetitive element (RLEP), as target in conventional and nested PCR assays. Molecular and anti-PGL-I-ELISA data indicated that 20/20 (100 %) of the armadillos were infected with M. leprae. The corresponding detection levels recorded with the LF tests were 17/20 (85 %) and 16/20 (85 %), for the NDO-LID® and ML flow tests, respectively. Our results indicate that, in common with D. novemcinctus, six banded armadillos (a species hunted and reared as a food-source in some regions of Brazil, including RN), represent a potential reservoir of M. leprae and as such, their role in a possible zoonotic cycle of leprosy within Brazil warrants further investigation