Yellow fever is a mosquito-borne viral illness found in tropical and subtropical areas in South America and Africa. Transmission is primarily via Aedes and Haemagogus species of mosquito. It can present with varying clinical features ranging from a self-limited, mild febrile illness to severe hemorrhage and liver disease. The “yellow” comes from jaundice that affects some patients with severe disease. The disease is diagnosed by history travel to an endemic area, exposure to infected mosquitoes, vaccination history, symptoms, and laboratory findings. Most cases are self-limited and resemble many other common viral infections. Of those who develop severe disease mortality can approach 50%. Unlike many other mosquito-transmitted viruses, infected humans are not dead-end hosts and may infect mosquitoes during periods of viremia and spread the virus. There is no specific antiviral therapy, but there is an effective vaccine recommended for travelers to endemic areas. Other than vaccination, prevention of mosquito bites is the best way to avoid contracting the virus.
The virus is an RNA virus of the genus Flavivirus, closely related to the viruses that cause West Nile, St. Louis, and Japanese encephalitis. Tree-hole breeding mosquitoes, such as Aedes aegypti and Haemagogous species, transmit yellow fever during the rainy season. The yellow fever virus has three distinct transmission cycles: jungle, intermediate, and urban. The jungle cycle involves transmission between non-human primates (monkeys) and mosquitoes. Humans are infected through infected mosquito bites while visiting or working in the jungle. The intermediate cycle occurs in the African savannah and involves humans who live or work in jungle border areas. Transmission may be between monkey and human or humans via mosquito vectors. The urban cycle involves a viremic human who contracted the virus in either the jungle or intermediate cycle who then returns to an urban area. Humans develop significant viremia to infect mosquitoes, which can then transmit the virus to other humans in urban areas. Person to person or primate to human transmission has not been reported without the involvement of a mosquito vector. 
Vaccination has decreased worldwide epidemics of yellow fever, but the infection has reemerged in many parts of Africa and South America. No one is immune from yellow fever, and it occurs in people of all ages and races. The highest mortality rates are reported in infants and elderly, who often have depressed immune systems. yellow fever is very rare in the United States. Most cases are diagnosed in unvaccinated travelers to sub-Saharan Africa or South America. While most people develop a self-limited infection, those who develop severe disease.
The incubation period is 3 to 6 days. Once acquired, the virus quickly spreads to multiple organs in the body. The liver is the most important organ affected by yellow fever. It produces profound jaundice due to liver damage. The kidneys also undergo similar pathological alterations and can lead to acute renal failure. When the upper gastrointestinal (GI) tract is involved, the gastric acid mixed with blood produces what is known as black vomit. Central nervous system (CNS) features include cerebral edema and hemorrhage. Encephalopathy is also a common feature of yellow fever.
The diagnosis requires a thorough travel history and record of immunization. Patients may present with headache, malaise, jaundice, and myalgias with severe back pain commonly reported. A physical exam may reveal the Faget sign or pulse fever dissociation, facial flushing, and conjunctival injection. During the most toxic phase, patients develop jaundice, dark urine, and vomiting. Bleeding may occur from mucous membranes and in the gastrointestinal tract. Symptoms may mimic those of malaria, leptospirosis, viral hepatitis, other hemorrhagic fevers, dengue, and other flavivirus infections.
Rapid detection methods include detection of yellow fever antigen using monoclonal enzyme immunoassay in serum specimens and detection of viral genome sequences using polymerase chain reaction (PCR) assay. Yellow fever can be diagnosed using ELISA and serology titers of antibodies. Other investigations depend on what organ is involved. If there is evidence of altered mentation, a lumbar puncture and a CT scan are performed. Blood work may reveal leukopenia with elevated transaminase levels. If the liver is involved, the coagulation profile may be abnormal. Most yellow fever specific testing can be done at the CDC, but reports will be sent to the state health department. When sending blood samples directly to the CDC, the health department should be informed.
Yellow fever is a reportable infection. Once the virus is contracted, symptoms develop after 3 to 6 days. There is no specific treatment, but severe cases require aggressive supportive care and hydration. Patients should be managed in the intensive care unit (ICU) and closely monitored for disseminated intravascular coagulation (DIC), hemorrhage, kidney, and liver dysfunction. Coagulopathy is managed with fresh frozen plasma, and renal failure may require dialysis. Even though yellow fever is not transmitted from person to person, isolation of the individual should be undertaken until the diagnosis is confirmed. Universal precautions are required when looking after patients with yellow fever although person-person transmission of the virus is unlikely. Infected patients should avoid mosquitoes, as they may transmit the virus to mosquitoes, which can serve as vectors for infection other patients.
Since there is no effective treatment or vaccine, prevention is critical. This is best accomplished by avoiding mosquito bites entirely. Even very short periods outdoors can lead to exposure to mosquito bites, so people should wear proper protective clothing. This protection includes long sleeves, long pants, socks, and closed-toe shoes. Pant legs can be tucked into socks to prevent bites to exposed ankles. Transmission is common during the warmer months, and mosquitoes may bite through very thin clothing, so treating clothing with repellents containing permethrin, DEET, oil of lemon eucalyptus, or other EPA-registered insect repellants will reduce this risk. Permethrin should not be applied directly to the skin, but when applied to clothing, it provides protection even after the clothing is washed. Transmission is most frequent when mosquitoes feed, between dawn and dusk, so outdoor activities during this period should be avoided. However, one of the mosquitos responsible for transmitting the virus, Aedes Aegypty, feeds during the daytime; so there is no safe time during the day for a traveler without repellent and wearing protective clothing. Travelers should sleep in air-conditioned spaces or use mosquito nets or screens to prevent bites during sleep. Standing water is a breeding ground for mosquitoes, so flower pots, buckets, and other containers should be drained. Children’s wading pools should be emptied and stored on their sides, and tire swings should have holes drilled into the bottom to allow trapped water to drain.
There is a safe and highly effective live-attenuated vaccine available to prevent yellow fever. A single dose confers lifelong immunity and is effective within 30 days for 99% of patients. Patients with relative contraindications to live attenuated vaccine who plan to travel to endemic areas should review the recommendations for vaccination prior to travel.
The differential diagnosis of yellow fever is broad and makes a careful travel history important. It includes:
Most cases are subclinical or mildly symptomatic with an excellent prognosis. About 15% of symptomatic patients will develop a severe disease. Most will recover, but after a bout of yellow fever, full recovery may take weeks or months. In most cases, there is a reversal of the liver and renal dysfunction. Death occurs in 30% to 50% of patients with severe disease. All travelers to endemic areas should be vaccinated if they are candidates for the live attenuated vaccine.
Continuous medical education can be obtained through the CDC website regarding yellow fever and yellow fever vaccine.
Yellow fever is endemic in many parts of the world. The key to this infection is prevention. While the acute infection is managed by a multidisciplinary group of healthcare professionals, prevention is best done by the nurse and pharmacist. All travelers to endemic regions should be educated about the vaccine, which confers lifelong immunity. Rarely some individuals may require a booster dose after ten years before traveling to an endemic area. Further, all laboratory workers who regularly handle yellow fever containing blood samples should have their neutralizing antibody titers measured every ten years to determine if they need a booster shot. The pharmacist should also educate the traveler on wearing long-sleeved garments, sleeping under a net and using DEET containing repellant spray. It is very unlikely that yellow fever will be eradicated anytime soon. The mosquitoes also transmit the sylvatic form via nonhuman primates. Additionally, deforestation and urbanization have reintroduced the virus into the cities. Plus, there is a limited amount of resources available. (Level V)
Yellow fever can be self-limited or in some cases be life-threatening. Data indicate that about 10-25% of patient will develop severe symptoms that include jaundice, fever, renal and liver failure. The case fatality rates are slightly lower in West Africa compared to South America. However, the ultimate mortality depends on the virulence of the infecting strain and patient susceptibility. Overall, about 3-70% of patients die after contracting yellow fever; the higher mortality is usually in patients with liver and renal damage. Deaths tend to occur within the first 10 days of the toxic phase. Both infants and the elderly are more likely to die than other individuals. Individuals who are unvaccinated usually develop more severe disease than natives. Finally, there are rare cases of post-vaccination neurological deficits and viscerotropic disease leading to death. (Level V)
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