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Sleeping Disorder (African Trypanomiasis) ADALYA JOURNAL ISSN NO: 1301-2746 SLEEPING DISORDER (AFRICAN TRYPANOMIASIS) T.MERLIN SHIBA [email protected], Assi. professor, Sree Balaji college of nursing BIHER, Chennai. ABSTRACT: Human African trypanosomiasis Sleeping sickness is endemic in 36 sub-Saharan Africa countries where there are tsetse flies that transmit the disease. The people most exposed to the tsetse fly and therefore the disease live in rural areas and depend on agriculture, fishing, animal husbandry or hunting. Human African trypanosomiasis takes 2 forms, depending on the parasite involved: Trypanosoma brucei gambiense accounts for more than 98% of reported cases. Sustained control efforts have reduced the number of new cases. In 2009 the number reported dropped below 10 000 for the first time in 50 years, and in 2018 there were 977 cases recorded. Diagnosis and treatment of the disease is complex and requires specifically skilled staff. KEY WORDS: African trypanosomiasis, Sleeping sickness, T. brucei rhodesiense Sleeping sickness, also called African trypanosomiasis, disease caused by infection with the flagellate protozoan Trypanosoma brucei gambiense or the closely related subspecies T. brucei rhodesiense, transmitted by the tsetse fly (genus Glossina). Sleeping sickness is characterized by two stages of illness. Volume 9, Issue 1, January 2020 1483 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 Sleeping sickness, also called African trypanosomiasis, disease caused by infection with the flagellate protozoan Trypanosoma brucei gambiense or the closely related subspecies T. brucei rhodesiense, transmitted by the tsetse fly (genus Glossina). Sleeping sickness is characterized by two stages of illness. In the first stage, infected persons typically experience fever, headache, muscle and joint pain, and inflammation of the lymph nodes. The second stage, which develops within several weeks (T. brucei rhodesiense) or within one to two years (T. brucei gambiense), is marked by involvement of the brain and spinal cord, Volume 9, Issue 1, January 2020 1484 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 accompanied by personality changes, sleep disturbances, and profound lethargy, frequently ending in death when left untreated. CAUSES Sleeping sickness is caused by two types of parasites Trypanosoma brucei rhodesiense and Trypanosoma brucei gambiense. T b rhodesiense causes the more severe form of the illness. Tsetse flies carry the infection. When an infected fly bites you, the infection spreads through your blood. RISK FACTORS Risk factors include living in parts of Africa where the disease is found and being bitten by tsetse flies. The disease does not occur in the United States, but travelers who have visited or lived in Africa can be infected. Infections with T. brucei gambiense occur in an area extending from the west coast of Africa eastward to the East African lakes and southward to the Congo River basin. Cases caused by T. brucei rhodesiense are limited to the highlands of central eastern and southern Africa. Several major epidemics of sleeping sickness occurred in the 20th century, but since then the number of new cases reported annually has declined significantly. In 2012 the World Health Organization published a plan targeting the elimination of sleeping sickness as a public health problem by 2020. Volume 9, Issue 1, January 2020 1485 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 Infection And Disease Course The vast majority of human cases result from the transfer of T. brucei trypanosomes by tsetse flies as they suck human blood. The flies become infected while feeding on the blood of infected people or other infected mammals. Usually 12 to 15 days elapse before flies that have picked up the parasites become infective toward humans. During this time the trypanosomes multiply by binary division in the midget of the fly, and then migrate to the salivary glands, and pass out of the fly’s proboscis in droplets of saliva during the fly’s bloodsucking. After an incubation period in humans lasting one to two weeks, the trypanosomes are found in significant numbers in the circulating blood. Next the lymph nodes and spleen are invaded, becoming swollen, soft, and tender. The marked enlargement of the lymph nodes at the back of the neck (known as Winter bottom’s sign) is a common sign of the disease. Irregular fever and delayed sensation to pain are also characteristic symptoms at this stage. In the more severe East African (or Volume 9, Issue 1, January 2020 1486 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 Rhodesian) form of sleeping sickness, T. brucei rhodesiense infection, toxemia becomes so profound that the patient dies within months. In the West African (or Gambian) type, T. brucei gambiense infection, there is a delay of one or more years before the trypanosomes proceed to invade the brain and spinal cord. The resulting neurological symptoms include severe headache, mental dullness and apathy, a weary shuffling gait, tremors, spastic or flaccid paralysis, chorea, and a profound sleepiness that develops during a meal or when the patient is standing or walking. These symptoms are followed by increasing emaciation, coma, and death. The West African form of sleeping sickness usually causes death in two or three years; in some cases, the patient develops a tolerance to the infection and may continue to live for many years as a carrier of the parasites. Diagnosis And Treatment The earlier that sleeping sickness is diagnosed and treated, the greater the chances for recovery. Diagnosis is made by microscopic examination of blood and lymph for the presence of trypanosomes and of cerebrospinal fluid for increased levels of white blood cells. Information obtained from these tests is then used to determine the stage of disease and course of treatment. Suramin is effective for early stages of East African sleeping sickness. Eflornithine is used for the early stages of the West African type, with pentamidine used as an alternative. For later stages involving the central nervous system, the West African form is treated with eflornithine. The highly toxic organoarsenic agent melarsoprol may used as a second-line agent against the East African form. All treatment of T. brucei rhodesiense infection is useless once the fulminating toxemic stage has developed. Researchers have been investigating eflornithine-based combination therapies for West African sleeping sickness. The most effective combination has been eflornithine used in conjunction with nifurtimox, an agent used to treat Chagas disease. Volume 9, Issue 1, January 2020 1487 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 Prevention In the early 21st century the majority of sleeping sickness cases occurred in the Democratic Republic of the Congo (DRC), which reported about 1,000 new cases each year. By 2015, with the exception of the DRC, most other African countries had reported fewer than 100 cases annually, and many others had not reported a case in more than a decade. The dramatic decline in sleeping sickness Volume 9, Issue 1, January 2020 1488 http://adalyajournal.com/ ADALYA JOURNAL ISSN NO: 1301-2746 cases was attributed to intensive control efforts, which included the isolation and proper treatment of all infected persons (including large numbers of asymptomatic chronic carriers) and the protection of humans from bites of tsetse flies by using insecticides and by maintaining extensive clearings around villages and residence compounds. Regular screening of communities in areas where tsetse flies are endemic and the culling of wild animal reservoirs, as well as personal approaches such as the use of insect repellent and the wearing of long-sleeved shirts and pants, have also helped reduce the number of cases of sleeping sickness. Historically, epidemics of West African sleeping sickness were controlled in part through the administration of prophylactic doses of pentamidine to village populations. The destruction of wild animals that served as host reservoirs for the parasites was also carried out, particularly in East Africa; the approach helped reduce tsetse fly populations, though neither the flies nor the disease were successfully exterminated. REFERENCES 1. WHO (1998) Control and Surveillance of African Trypanosomiasis. WHO Technical rapport. 2. Blum J, Schmid C, Burri C (2006) Clinical aspects of 2541 patients with second stage human African trypanosomiasis. Acta Trop 97: 55–64. 3. MacLean LM, Odiit M, Chisi JE, Kennedy PG, Sternberg JM (2010) Focus- specific clinical profiles in human African Trypanosomiasis caused by Trypanosoma brucei rhodesiense. PLoS Negl Trop Dis 4: e906. 4. Heppner C, Petzke F, Arlt W, Mbulamberi D, Siekmann L, et al. (1995) Adrenocortical insufficiency in Rhodesian sleeping sickness is not attributable to suramin. Trans R Soc Trop Med Hyg 89: 65–68. 5. Mbulamberi DB (1987) A clinical analysis of 3151 cases of Rhodesian sleeping sickness treated in the South Eastern Uganda, during the year 1985188–195. 6. Duggan AJ, Hutchinson MP (1966) Sleeping sickness in Europeans: a review of 109 cases. J Trop Med Hyg 69: 124–131. 7. Ezzedine K, Darie H, Le Bras M, Malvy D (2007) Skin features accompanying imported human African trypanosomiasis: hemolymphatic Trypanosoma gambiense infection among two French expatriates with dermatologic manifestations. J Travel Med 14: 192–196. Volume 9, Issue 1, January 2020 1489 http://adalyajournal.com/.
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