American Trypanosomiasis (Chagas Disease; Trypanosoma cruzi )

Etiology

American trypanosomiasis is caused by Trypanosoma cruzi , a parasitic, flagellated kinetoplastid protozoan. The main vectors for T. cruzi are insects of the family Reduviidae, subfamily Triatominae, which includes Triatoma infestans, Rhodnius prolixus, and Panstrongylus megistus.

Life Cycle

T. cruzi has 3 recognizable morphogenetic phases: amastigotes, trypomastigotes, and epimastigotes ( Figs. 313.1 and 313.2 ). Amastigotes are intracellular forms found in mammalian tissues that are spherical and have a short flagellum but form clusters of oval shapes (pseudocysts) within infected tissues. Trypomastigotes are spindle-shaped, extracellular, nondividing forms that are found in blood and are responsible for both transmission of infection to the insect vector and cell-to-cell spread of infection. Epimastigotes are found in the midgut of the vector insect and multiply in the midgut and rectum of arthropods, differentiating into metacyclic forms. Metacyclic trypomastigotes are the infectious form for humans and are released onto the skin of a human when the insect defecates close to the site of a bite, entering through the damaged skin or mucous membranes. Once in the host, these multiply intracellularly as amastigotes, which then differentiate into bloodstream trypomastigotes and are released into the circulation when the host cell ruptures. Bloodborne trypomastigotes circulate until they enter another host cell or are taken up by the bite of another insect, completing the life cycle.

Epidemiology

Natural transmission of Chagas disease occurs in North and South America, most frequently in continental Latin America. The disease may arise elsewhere because of migration and transmission through contaminated blood. World Health Organization (WHO) and Pan-American Health Organization–led efforts in large-scale vector control, blood donor screening to prevent transmission through transfusion, and case finding and treatment of chronically infected mothers and newborn infants have effectively halted transmission in a number of areas of South America. The number of cases has dropped from a peak of 24 million in 1984 to a current estimate of 6-7 million, with about 10,000 deaths annually. Overall vectorial transmission continues to drop, although challenges remain, including the emergence of disease in new areas thought to be Chagas free, along with reemergence in previously controlled areas.

Infection is divided into 2 main phases: acute and chronic ( Table 313.1 ). Acute infection is asymptomatic in up to 95% of infected individuals, but can manifest as fever, lymphadenopathy, organomegaly, myocarditis, and meningoencephalitis. Chronic infection in 60–70% of patients is indeterminate, meaning the patient is asymptomatic but has a positive antibody titer. Approximately 30% of infected persons proceed to chronic determinate or symptomatic T. cruzi infection. The T. cruzi genome has been fully sequenced and contains 12,000 genes, the most widely expanded among trypanosomatids, and may reflect its ability to invade a wide variety of host tissues. Significant variability has been also found, along with extensive epigenetic modification of surface proteins, which may contribute to immune evasion. Six discrete typing units (DTUs) are recognized, referred to as TcI to TcVI. A newly described 7th type called Tcbat has recently been identified. DTUs may differ in geographic distribution, predominant vector, and hosts and may also differ in disease manifestations and response to treatment.

T. cruzi infection is primarily a zoonosis, and humans are incidental hosts. T. cruzi has a large sylvan reservoir and has been isolated from numerous animal species. The presence of reservoirs and vectors of T. cruzi and the socioeconomic and educational levels of the population are the most important risk factors for vector-borne transmission to humans. Insect vectors are found in rural, wooded areas and acquire infection through ingestion of blood from humans or animals with circulating trypomastigotes.

Housing conditions are very important in the transmission chain. Incidence and prevalence of infection depend on the adaptation of the triatomines to human dwellings, as well as the vector capacity of the species. Animal reservoirs of reduviid bugs include dogs, cats, rats, opossum, guinea pigs, monkeys, bats, and raccoons. Humans often become infected when land in enzootic areas is developed for agricultural or commercial purposes. An estimated 238,000 immigrants from endemic countries living in the United States are likely infected with T. cruzi . Increasing cases of autochthonous transmission in the United States have also been reported and confirmed with molecular typing, particularly from California, Louisiana, Texas, and Georgia, although these numbers remain small. One study found that 5.2% of Latin America immigrants in Los Angeles with conduction abnormalities on electrocardiogram (ECG) were seropositive for T. cruzi .

Humans can be infected transplacentally, occurring in 10.5% of infected mothers and causing congenital Chagas disease. Transplacental infection is associated with premature birth, fetal wastage, and placentitis. Disease transmission can occur through blood transfusions in endemic areas from asymptomatic blood donors. Seropositivity rates in endemic areas are as high as 20%. The risk for transmission through a single blood transfusion from a chagasic donor is 13–23%. Blood screening for Chagas disease in the United States was started in 2006 and has detected >2,200 seropositive cases since February 2017 ( www.aabb.org ). Percutaneous injection as a result of laboratory accidents is also a documented mode of transmission. Oral transmission through contaminated food is an increasingly important method of transmission as vector transmission is successfully interrupted by control programs. Although breastfeeding is an uncommon mode of transmission, women with acute infections should not nurse until they have been treated.