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  1. Heisch RB
    Br Med J, 1956;2:669.
    DOI: 10.1136/bmj.2.4994.669
    The zoonoses, which are defined as infections of man naturally acquired from other vertebrates, are treated as a problem in ecology. This entails studying the interrelation between man, animals, a causative organism, the environment, and sometimes arthropods. Such an approach is holistic or synecological—wholes being regarded as more important than parts. Holism is a dynamic not a static conception. The evolution of the zoonoses is discussed, particularly in relation to plague, relapsing fever, and leishmaniasis. The most important reservoirs of zoonoses and other parasitic infections are usually resistant or relatively insusceptible animals rather than highly susceptible ones. Plague and Chagas's disease illustrate this. Resistant and unduly susceptible animals occupy different “niches“ in nature. By “niche“ is meant the place of an animal in its biotic environment. Zoonoses often have a “focal distribution“ in nature. Thus wild rodents infected with plague may occur in “ pockets,” and the vector mites of scrub typhus congregate in “typhus islands.” An unstable environment often favours the transference of zoonoses to man and animals. Examples are the plague-infected plain of Rongai, in Kenya, the typhus-infected forest clearings in Malaya, and the yellow-fever infected forest edges in Uganda. Ecologically unstable areas are termed “ ecotones.” Zoonoses can also be transmitted in or near relatively stable sites such as huts, rodent burrows, caves, and termite hills. These are known as “habitat niches.” Animals and arthropods in a community are linked by food, and the importance of what are known as “food chains“ and “food cycles“ is discussed in relation to the transference of zoonotic infections from one host to another. Reference is also made to the fluctuations in numbers of various animals in nature, and how this affects the incidence of zoonotic disease. Certain highly susceptible rodents are periodically decimated by plague; this breaks the link with man, and human infections cease for the time being. © 1956, British Medical Journal Publishing Group. All rights reserved.
    Matched MeSH terms: Chagas Disease
  2. Castellanos-Sánchez P, Falconi-Agapito F, Pariona N, Paredes-Esquivel C
    Trop Biomed, 2020 Dec 01;37(4):864-870.
    PMID: 33612739 DOI: 10.47665/tb.37.4.864
    Chagas disease is endemic to the Americas and is transmitted by blood-feeding kissing bugs. We evaluated the insecticidal potential of a fungus (Beauveria bassiana strain Pr-11) against Triatoma infestans, an important vector in South America. This fungal species was isolated from a locust (Schistocerca piceifrons) that inhabits the Central Andes region of Peru. Ten days post inoculation, this strain induced high insect mortality (97%) at low fungal concentrations (2 × 107 conidia/ml) at 70% relative humidity. The Pr-11 strain outperformed reference strain CCBLE-216 B. bassiana, provided by the Peruvian Ministry of Agriculture. Our results are consistent with previous reports on the virulence of this fungal strain against other insect pests. This is the first study to evaluate an orthopteran-isolated B. bassiana to control Chagas disease vectors. We conclude that strain Beauveria bassiana Pr-11 is effective against Triatoma infestans, resulting in a promising tool to control Chagas disease in Peru and may be used in integrated vector control programs.
    Matched MeSH terms: Chagas Disease/transmission
  3. Weibel Galluzzo C, Wagner N, Michel Y, Jackson Y, Chappuis F
    Rev Med Suisse, 2014 May 7;10(429):1008-13.
    PMID: 24908745
    Travels, migration and circulation of goods facilitate the emergence of new infectious diseases often unrecognized outside endemic areas. Most of emerging infections are of viral origin. Muscular Sarcocystis infection, an acute illness acquired during short trips to Malaysia, and Chagas disease, a chronic illness with long incubation period found among Latin American migrants, are two very different examples of emerging parasitic diseases. The former requires a preventive approach for travelers going to Malaysia and must be brought forth when they return with fever, myalgia and eosinophilia, while the latter requires a proactive attitude to screen Latin American migrant populations that may face difficulties in accessing care.
    Matched MeSH terms: Chagas Disease/diagnosis; Chagas Disease/parasitology
  4. Ibrahim F, Thio TH, Faisal T, Neuman M
    Sensors (Basel), 2015 Mar 23;15(3):6947-95.
    PMID: 25806872 DOI: 10.3390/s150306947
    This paper reviews a number of biomedical engineering approaches to help aid in the detection and treatment of tropical diseases such as dengue, malaria, cholera, schistosomiasis, lymphatic filariasis, ebola, leprosy, leishmaniasis, and American trypanosomiasis (Chagas). Many different forms of non-invasive approaches such as ultrasound, echocardiography and electrocardiography, bioelectrical impedance, optical detection, simplified and rapid serological tests such as lab-on-chip and micro-/nano-fluidic platforms and medical support systems such as artificial intelligence clinical support systems are discussed. The paper also reviewed the novel clinical diagnosis and management systems using artificial intelligence and bioelectrical impedance techniques for dengue clinical applications.
    Matched MeSH terms: Chagas Disease/diagnosis; Chagas Disease/pathology
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