Virology, pathology, and clinical manifestations of West Nile Virus disease.West Nile virus West Nile virus, microorganism and the infection resulting from it, which typically produces no symptoms or a flulike condition. The virus is a flavivirus and is related to a number of viruses that cause encephalitis. (WNV) causes epidemics of febrile illness, meningitis, encephalitis, and flaccid paralysis. Since it was first detected in New York City New York City: see New York, city. New York City City (pop., 2000: 8,008,278), southeastern New York, at the mouth of the Hudson River. The largest city in the U.S. in 1999, and through 2004, >16,000 WNV disease cases have been reported in the United States. Over the past 5 years, research on WNV disease has expanded rapidly. This review highlights new information regarding the virology, clinical manifestations, and pathology of WNV disease, which will provide a new platform for further research into diagnosis, treatment, and possible prevention of WNV through vaccination. ********** The impressive spread of West Nile virus (WNV) in the Western Hemisphere after its detection in 1999 during an outbreak of encephalitis in New York City has caused >16,000 human disease cases and >660 deaths in North America. Research on the signs, symptoms, and pathogenesis of WNV disease has greatly intensified in the past 5 years. The number of recognized cases of flaccid paralysis due to WNV infection has increased substantially, and research into prognosis and possible therapy has expanded. Genetic variation of the virus has been further characterized and continues to be explored. The pathology and pathogenesis of WNV disease have been described more completely than ever before. Several strategies are being pursued to develop effective vaccines to prevent WNV disease. This article highlights new information about the virology, clinical manifestations, laboratory diagnosis, pathology, and prognosis of WNV illness in humans. The expanded knowledge about WNV disease provides a new platform for future development of diagnostic tests, therapy, and vaccine development. Characteristics of West Nile Virus WNV is an arbovirus arbovirus Any of a large group of viruses that develop in arthropods (chiefly mosquitoes and ticks). The name derives from “arthropod-borne virus.” The spheroidal virus particle is encased in a fatty membrane and contains RNA; it causes no apparent harm to the in the family Flaviridae. Its spherical, enveloped capsid capsid /cap·sid/ (kap´sid) the shell of protein that protects the nucleic acid of a virus; it is composed of structural units, or capsomers. cap·sid n. has a diameter of [approximately equal to] 50 nm and contains single-stranded RNA RNA: see nucleic acid. RNA in full ribonucleic acid One of the two main types of nucleic acid (the other being DNA), which functions in cellular protein synthesis in all living cells and replaces DNA as the carrier of genetic that encodes the capsid (C), envelope (E), and premembrane (prM) proteins, as well as 7 nonstructural proteins that likely contribute to viral replication. The virus has 2 genetic lineages: lineage 1 strains are found in North America, Europe, Africa, Asia, and Australia; lineage 2 strains have been isolated only in subSaharan Africa and Madagascar. Lineage 1 strains have been further divided into 4 clades: Kunjin, Indian, A, and B (which includes an Indian isolate) (1). The isolates in clade clade Cladus, subtype Genetics A branch of biological taxa or species that share features inherited from a common ancestor; a single phylogenetic group or line. See Inheritance, Species. B, which includes strains from the United States, are all virulent in mice; lineage 2 and other clades in lineage l comprise both virulent and attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. strains (l). Differences in pathogenicity may be related to nucleotides that code for specific regions in the prM, E, or nonstructural proteins of the virus (1,2). WNV strains from the United States are closely related to strains from Israel, with 99.7% homology in nucleotide sequences, indicating that the strains in the United States almost certainly originated from the Middle East (3). The strain isolated in New York in 1999 is more virulent in American crows (Corvus brachyrynchos) than strains from Kenya and Australia (Kunjin virus, a subtype of WNV), and both the New York strain and the Kenyan strain experimentally killed house sparrows whereas the Australian strain did not (4). Two genetic variants of the North American WNV strain were isolated in Texas in 2002; the major variant differed from the New York 1999 isolate by 0.18% of nucleotides, and the minor variant by 0.35% (1). The 2 variants differed from each other by 0.5% of nucleotides, and their neuroinvasiveness in mice was similar to that of the New York 1999 isolate. In 2003, attenuated WNV strains were found in birds in Texas and Mexico, providing the first evidence of phenotypic variation of WNV strains in the Western Hemisphere (2,5). The reduced neuroinvasiveness and smaller plaque size of the Texas strains may be due to mutations in nonstructural proteins that result in lower levels of viremia viremia /vi·re·mia/ (vi-re´me-ah) the presence of viruses in the blood. vi·re·mi·a n. The presence of viruses in the bloodstream. ; the attenuated strain from Mexico had a mutation in the E protein (2,5). Pathogenesis WNV is thought to replicate at the site of inoculation and then spread to lymph nodes and the bloodstream (6). Viral penetration of the central nervous system appears to follow stimulation of toll-like receptors and increased levels of tumor necrosis factor-[alpha], which increases permeability of the blood-brain barrier (7). WNV directly infects neurons, particularly in deep nuclei and gray matter of the brain, brainstem, and spinal cord (8-10). Collateral destruction of bystander nerve cells may contribute to paralysis (11). Immune-mediated tissue damage may also contribute to pathologic changes in some cases (12). Genetic susceptibility for severe disease in mice has been postulated to involve a deficiency in production of 2'-5'-oligoadenylate synthetase synthetase /syn·the·tase/ (-the-tas) a term used in the names of some of the ligases, no longer favored because of its similarity to synthase and its emphasis on reaction products. syn·the·tase n. , but this genetic susceptibility has not been elucidated in humans (10). Although most nonfatal WNV infections appear to be cleared by the host immune response, the virus may persist in some vertebrate hosts (10,13). Clinical Manifestations The clinical spectrum of symptomatic WNV infection in humans has been further defined during the North American epidemics. About 80% of human infections are apparently asymptomatic (14). Of those persons in whom symptoms develop, most have self-limited West Nile fever West Nile fever West Nile meningoencephalitis Infectious disease An acute, mosquito-borne flaviviral infection endemic–rarely, epidemic–in the Near East, Africa, former Soviet Union, India Clinical After a 3-6 day incubation, children present with a (WNF), characterized by the acute onset of fever, headache, fatigue, malaise, muscle pain, and weakness; gastrointestinal symptoms and a transient macular macular adjective Related to 1. A macule 2. The macula rash on the trunk and extremities are sometimes reported (15,16). A recent follow-up study of WNF patients who sought medical attention found that difficulty concentrating and neck pain or stiffness were also prominent symptoms, and that fatigue and muscle weakness frequently lasted for [approximately equal to] 1 month after onset (16). Of the 98 patients interviewed, 31% were hospitalized, 79% missed school or work because of their illness, and the median time before patients felt fully recovered was 60 days. These patients probably represent the most severe WNF, but even without neurologic manifestations, WNV infection clearly can cause a notable public health problem, Additional nonneurologic clinical manifestations that may rarely occur during WNV infection include hepatitis, pancreatitis, myocarditis Myocarditis Definition Myocarditis is an inflammatory disease of the heart muscle (myocardium) that can result from a variety of causes. While most cases are produced by a viral infection, an inflammation of the heart muscle may also be instigated by , rhabdomyolysis rhabdomyolysis /rhab·do·my·ol·y·sis/ (-mi-ol´i-sis) disintegration of striated muscle fibers with excretion of myoglobin in the urine. rhab·do·my·ol·y·sis n. , orchitis orchitis Inflammation and swelling of the testes, caused by infection (most often mumps) or chemical or physical injury. The testicles' rich blood and lymphatic supply block most infections in the absence of severe injury. , and ocular manifestations (17-24). Chorioretinitis may be more common than previously thought; a study in Tunisia found that 69% of 29 patients hospitalized with WNV disease had chorioretinitis (24). Cardiac dysrhythmias have been observed in some North American patients (Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. [CDC See Control Data, century date change and Back Orifice. CDC - Control Data Corporation ], unpub, data) (22). Neuroinvasive disease develops in <1% of WNV-infected persons, for example, in such forms as meningitis, encephalitis, or paralysis (the proportion of reported cases that are neuroinvasive disease is higher because neuroinvasive disease is more likely to be reported to be spoken of; to be mentioned, whether favorably or unfavorably. See also: Report than WNF or asymptomatic infections) (14). The risk for encephalitis increases with age and is higher among organ transplant recipients (25,26). Whether other immunocompromised immunocompromised /im·mu·no·com·pro·mised/ (-kom´pro-mizd) having the immune response attenuated by administration of immunosuppressive drugs, by irradiation, by malnutrition, or by certain disease processes (e.g., cancer). patients are at higher risk remains unclear, but severe WNV disease has been described in persons with malignancies (9). Whether diabetes, hypertension, and cerebrovascular disease are risk factors also remains uncertain (27). The clinical severity of WNV encephalitis ranges from mild disorientation to coma and death (28,29). Many patients with WNV encephalitis have movement disorders, including severe tremors and parkinsonism (28,29). In [approximately equal to] 13% of patients with neuroinvasive WNV disease, WNV infection of spinal motor neurons (anterior horn cells) causes acute, asymmetric flaccid paralysis similar to that seen with poliomyelitis poliomyelitis (pō'lēōmī'əlī`tĭs), polio, or infantile paralysis, acute viral infection, mainly of children but also affecting older persons. (CDC, unpub, data) (18,30,31). Infection of the brainstem and high cervical spinal cord may cause diaphragmatic and intercostal intercostal /in·ter·cos·tal/ (-kos´t'l) between two ribs. in·ter·cos·tal adj. Located or occurring between the ribs. n. A space, muscle, or part situated between the ribs. muscle paralysis with resulting respiratory failure and sometimes death. A separate syndrome consistent with acute inflammatory demyelinating polyradiculoneuropathy (Guillain-Barre syndrome) has been infrequently reported (32). Pathologic Changes Histologic findings of WNV encephalitis include perivascular perivascular /peri·vas·cu·lar/ (-vas´ku-lar) near or around a vessel. perivascular around a vessel. perivascular cellulitis inflammation, microglial nodules Nodules A small mass of tissue in the form of a protuberance or a knot that is solid and can be detected by touch. Mentioned in: Leprosy , variable necrosis, and loss of neurons (Figure panels A, B) (8,9). The deep gray nuclei, brainstem, and spinal cord appear to be most affected (8,9). Patients with flaccid paralysis have perivascular lymphocytic infiltration in the spinal cord, microglial nodules, and loss of anterior horn cells (9). Spinal cord inflammation was seen in 17 of 23 people who died with WNV neuroinvasive disease; inflammation was more prominent in the anterior horns than in the posterior horns of 9 patients (9). Endoneural mononuclear inflammation of cranial nerve roots and spinal nerves can be found in a small percentage of persons. Foci of demyelination demyelination /de·my·elin·a·tion/ (de-mi?e-li-na´shun) destruction, removal, or loss of the myelin sheath of a nerve or nerves. Called also myelinolysis. , gliosis, and occasional perivascular infiltrates may be found in persons with prolonged clinical courses. [FIGURE OMITTED] Before 2001, attempts to isolate WNV from postmortem tissues in the United States had been unsuccessful. Recently, the virus has been isolated postmortem from 2 immunosuppressed patients with apparently high viral loads (33). Immunohistochemical (IHC) staining is more sensitive than viral culture, showing WNV antigens in [approximately equal to] 50% of fatal WNV neuroinvasive disease cases; IHC staining is particularly useful in patients who died during the first week of illness when viral antigen concentrations in central nervous system (CNS See Continuous net settlement. CNS See continuous net settlement (CNS). ) tissues are high (9). Viral antigens are usually found within neurons and neuronal processes, predominantly in the brain stem and anterior horus (Figure, panel C). In general, antigens are focal and sparse, except in immunosuppressed patients in whom they can be seen extensively throughout the CNS (9). Visualization of WNV particles by electron microscopy is rare. When found, they are seen within endoplasmic endoplasmic pertaining to or arising from endoplasm. endoplasmic ribosomes small, cytoplasmic granules consisting of approximately 60% RNA and 40% protein. reticulum reticulum /re·tic·u·lum/ (re-tik´u-lum) pl. retic´ula [L.] 1. a small network, especially a protoplasmic network in cells. 2. reticular tissue. of neurons (Figure, panel D). Diagnostic Tests Routine clinical laboratory studies do not distinguish WNV infection from many other viral infections. Patients with neuroinvasive disease generally have lymphocytic pleocytosis pleocytosis /pleo·cy·to·sis/ (ple?o-si-to´sis) presence of a greater than normal number of cells in cerebrospinal fluid. ple·o·cy·to·sis n. in the cerebrospinal fluid (CSF Cerebrospinal Fluid (CSF) Analysis Definition Cerebrospinal fluid (CSF) analysis is a laboratory test to examine a sample of the fluid surrounding the brain and spinal cord. ), but neutrophils may predominate early in the course of illness (28,31). Results of brain magnetic resonance imaging magnetic resonance imaging (MRI), noninvasive diagnostic technique that uses nuclear magnetic resonance to produce cross-sectional images of organs and other internal body structures. are frequently normal, but signal abnormalities may be seen in the basal ganglia, thalamus thalamus (thăl`əməs), mass of nerve cells centrally located in the brain just below the cerebrum and resembling a large egg in size and shape. , and brain stem of patients with encephalitis, and in the anterior spinal cord in patients with poliomyelitislike syndrome (18,29,31). Clinical features and electrodiagnostic tests can help differentiate poliomyelitislike syndrome from Guillain-Barre syndrome by localizing damage primarily to motor axons, anterior horn cells, or both, with relative sparing of sensory nerves in the former, as opposed to localizing the damage to peripheral myelin myelin /my·elin/ (mi´e-lin) the lipid-rich substance of the cell membrane of Schwann cells that coils to form the myelin sheath surrounding the axon of myelinated nerve fibers. or muscle in the latter (18,31,32,34). Detection of WNV-specific immunoglobulin (Ig) M in serum or CSF provides strong evidence of recent WNV infection. In some patients, IgM antibody against WNV is usually detectable by 8 days after illness onset; however, in patients with WNV neuroinvasive disease, specific IgM is almost always detectable in serum and CSF by the time CNS symptoms begin (35). Among asymptomatic WNV-viremic blood donors who were seronegative seronegative /se·ro·neg·a·tive/ (-neg´ah-tiv) showing negative results on serological examination; showing a lack of antibody. se·ro·neg·a·tive adj. at the time of donation, IgM appeared [approximately equal to] 9 days postdonation, and IgG appeared [approximately equal to] 4 days later (M. Busch, pers. comm.). IgM is detectable in serum of [approximately equal to] 36% of patients who have survived WNV encephalitis at 12 months postonset and [approximately equal to] 20% at 16 months postonset; IgM is also detectable in CSF of other patients up to 199 days postonset (36,37). Consequently, detectable IgM may occasionally refect re·fect tr.v. re·fect·ed, re·fect·ing, re·fects Archaic To refresh with food and drink. [Latin reficere, refect-, to refresh : re-, re- past rather than recent infection. Recently developed microsphere immunoassays for WNV antibody appear to be more accurate and efficient than current enzyme immunoassays (EIAs) (J. Johnson, pers. comm.) (38). As with standard EIA (Electronic Industries Alliance, Arlington, VA, www.eia.org) A membership organization founded in 1924 as the Radio Manufacturing Association. It sets standards for consumer products and electronic components. , related flaviviral infection may elicit cross-reactive test results. A microsphere assay with nonstructural viral antigens appears to discriminate between primary flaviviral infections that elicit cross-reactive antibody to the E glycoprotein (38). A [greater than or equal to] 4-fold change in virus-specific neutralizing antibody titer (detected by plaque-reduction neutralization test [PRNT]) between 2 serum specimens collected 2-3 weeks apart usually confirms acute WNV infection. Samples with WNV-specific antibody will usually have neutralizing antibody titers to WNV that are >4-fold higher than titers to other epidemiologically relevant flaviviruses included in the assay. However, PRNT may not discriminate between WNV infection and other flaviviral infections in patients with previous flavivirus exposure, because the neutralizing antibody in such cases may broadly cross-react to several related flaviviruses. WNV infection can also be diagnosed by detecting virus in CSF, serum, or tissues by isolation or nucleic acid amplification tests (NATs). WNV is best isolated in cell culture or suckling mice and identified by indirect immunofuorescence assay with specific monoclonal antibodies or by reverse transcriptase-polymerase chain reaction (RT-PCR RT-PCR reverse transcriptase-polymerase chain reaction. See PCR1. ). However, WNV is rarely isolated from the blood of patients with neuroinvasive WNV disease because viremia levels are typically low or absent by the time neurologic symptoms develop. Real-time RT-PCR and nucleic acid sequence-based amplification are the most sensitive NATs, able to detect [greater than or equal to] 50 viral RNA copies per mE ([approximately equal to] 0.1 PFU/mL), which is [approximately equal to] l,000-fold more sensitive than culture (39). WNV can be detected in serum by NAT if the specimen is obtained early in infection and is readily detected by NAT, isolation, or IHC staining in brain tissue from persons with fatal cases. The sensitivity of RTPCR RTPCR Reverse Transcriptase Polymerase Chain Reaction among 28 patients with serologically confirmed neuroinvasive WNV disease was 57% in CSF and 14% in serum (40). The diagnosis of WNV encephalitis can be supported histopathologically, and there is no pathognomonic pathognomonic /pa·thog·no·mon·ic/ (path?ug-no-mon´ik) specifically distinctive or characteristic of a disease or pathologic condition; denoting a sign or symptom on which a diagnosis can be made. lesion. Differential diagnoses include arboviral and other viral encephalitides, rickettsial infections, and various noninfectious diseases. When serum samples and frozen tissues are not available, IHC testing of formalin-fixed tissues with specific monoclonal and polyclonal antibodies is particularly useful. Prognosis The clinical course of WNF ranges from a mild febrile illness of several days' duration to debilitating de·bil·i·tat·ing adj. Causing a loss of strength or energy. Debilitating Weakening, or reducing the strength of. Mentioned in: Stress Reduction fatigue, aching, and weakness that may last for weeks or months (16,29,41). Although cases of meningitis without alteration of the patient's mental status or other focal neurologic features have a favorable prognosis, persistent headaches and fatigue may be reported (29). Patients with WNV encephalitis or focal neurologic manifestations often have persistent neurologic deficits for months or years (28,29). Of 35 patients hospitalized with WNV disease in New York, only 13 (37%) reported full recovery in physical, cognitive, and functional abilities 12 months after illness onset (41). Many patients with WNV-associated poliomyelitislike syndrome do not recover, but some improvement in limb strength may occur over time (42,43). The overall case-fatality rate for neuroinvasive WNV disease is [approximately equal to] 9% (26). Clinical Management Management of severe WNV illness remains supportive. Patients with severe meningeal me·nin·ge·al adj. Of, relating to, or affecting the meninges. meningeal pertaining to the meninges. meningeal hemorrhage symptoms often require pain control for headaches and antiemetic therapy and rehydration rehydration /re·hy·dra·tion/ (-hi-dra´shun) the restoration of water or fluid content to a patient or to a substance that has become dehydrated. re·hy·dra·tion n. 1. for associated nausea and vomiting Nausea and Vomiting Definition Nausea is the sensation of being about to vomit. Vomiting, or emesis, is the expelling of undigested food through the mouth. . Patients with severe encephalitis should be observed for development of elevated intracranial pressure and seizures, and patients with encephalitis or paralysis must be monitored for inability to protect the airway. Acute neuromuscular respiratory failure may develop rapidly, particularly in patients with prominent bulbar bulbar /bul·bar/ (bul´ber) 1. pertaining to a bulb. 2. pertaining to or involving the medulla oblongata. bul·bar adj. 1. Resembling or relating to a bulb. signs; prolonged ventilatory support may be required (22,30,34). Ribavirin ribavirin /ri·ba·vi·rin/ (ri?bah-vi´rin) a broad-spectrum antiviral used in the treatment of severe viral pneumonia caused by respiratory syncytial virus, particularly in high-risk infants; also used in conjunction with interferon , interferon-[alpha], WNV-specific immunoglobulin, and antisense gene-targeted compounds have all been considered as specific treatments for WNV disease, but no rigorously conducted clinical trials have been completed. Nonspecific immunoglobulin and plasmapheresis plasmapheresis, see apheresis. should be considered for patients with Guillain-Barre syndrome but are not indicated for patients with paralysis due to damage of anterior horn cells (30). Vaccine Development Two vaccines are available for vaccinating equines: an inactivated inactivated rendered inactive; the activity is destroyed. inactivated viruses treated so that they are no longer able to produce evidence of growth or damaging effect on tissue. WNV vaccine and a recombinant vaccine that uses canarypox virus to express WNV antigens (44,45). An inactivated vaccine is also being studied for use in humans (46). A chimeric live virus vaccine incorporating the genetic sequences for E and prM antigens into a 17-D yellow fever virus yellow fever virus n. An arbovirus of the genus Flavivirus that causes yellow fever and is transmitted by mosquitoes. backbone has been shown to be efficacious in hamsters and is undergoing initial clinical trials in humans (46). Another chimeric vaccine incorporating WNV genetic sequences into a backbone of attenuated serotype-4 dengue virus induced protective immunity in monkeys (44). A DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. vaccine that elicits expression of WNV E and prM antigens has been used in mice, horses, and birds (44). Vaccination of crows with Kunjin virus, a subtype of WNV, protected against WNV, and a DNA vector, which elicited expression of attenuated Kunjin virus, provided protective immunity against WNV in mice (46). Future Directions Since the 1990s, WNV has gained notoriety as a cause of severe neuroinvasive disease in humans. As WNV isolates and genetic sequences accumulate over an increasing geographic and clinical range, the virus shows signs of genetic modifications that likely interact with host factors in causing different patterns of neuroinvasiveness and neurovirulence. Several areas warrant research focus over the next few years. More efficient diagnostic assays will help with both clinical diagnosis and disease surveillance. Improved knowledge about the pathogenesis and natural history of WNV disease is crucial to developing effective treatment, and promising therapies need to be carefully evaluated in controlled clinical trials. Given the focal distribution of WNV outbreaks, and the uncertain distribution of future cases of WNV disease, prospective clinical studies need to be designed with the flexibility to gather information from widely dispersed and changing locations. The development of a safe and effective vaccine for humans is a clear priority for prevention, and the public health strategies and recommendations for vaccination deserve careful thought. Given the relatively low incidence of WNV neuroinvasive disease and the focal occurrence of WNV epidemics thus far, vaccination will likely require targeting to higher risk groups to approach the cost-effectiveness of many recommended public health prevention strategies. References (1.) Beasley DW, Davis CT, Whiteman M, Granwehr B, Kinney RM, Barrett AD. Molecular determinants of virulence of West Nile virus in North America. Arch Virol Suppl. 2004;35-41. (2.) Davis CT, Beasley DW, Guzman H, Siirin M, Parsons RE, Tesh RB, et al. Emergence of attenuated West Nile virus variants in Texas, 2003. Virology. 2004;330.342-50. (3.) Lanciotti RS, Roehrig JT, Deubel V, Smith J, Parker M, Steele K, et al. Origin of the West Nile virus responsible for an outbreak of encephalitis in the northeastern United States. Science. 1999;286:2333-7. (4.) Langevin SA, Brault A, Panella NA, Bowen R, Komar N. Variation in West Nile virus strain virulence for house sparrows (Passer domesticus). Am J Trop Mcd Hyg. 2005;72:99-102. (5.) Beasley DW. Genome sequence and attenuating mutations in West Nile virus isolate from Mexico. Emerg Infect Dis. 2004;10:2221-4. (6.) Diamond MS, Shrestha B, Mehlhop E, Sitati E, Engle M. Innate and adaptive immune responses determine protection against disseminated infection by West Nile encephalitis virus. Viral Immunol. 2003;16:259-78. (7.) Wang T, Town T, Alexopoulou L, Anderson JF, Fikrig E, Flavell RA. Toll-like receptor 3 mediates West Nile virus entry into the brain causing lethal encephalitis. Nat Med. 2004;10:1366-73. (8.) Kleinschmidt-DeMasters BK, Marder BA, Levi ME, Laird SP, McNutt JT, Escott EJ, et al. Naturally acquired West Nile vials encephalomyelitis encephalomyelitis /en·ceph·a·lo·my·eli·tis/ (en-sef?ah-lo-mi?e-li´tis) inflammation of the brain and spinal cord. acute disseminated encephalomyelitis in transplant recipients: clinical, laboratory, diagnostic, and neuropathological features. Arch Neurol. 2004;61:1210 20. (9.) Guamer J, Shieh W J, Hunter S, Paddock CD, Morken T, Campbell GL, et al. Clinicopathologic study and laboratory diagnosis of 23 cases with West Nile virus encephalomyelitis. Hum Pathol. 2004;35:983-90. (10.) Ceccaldi PE, Lucas M, Despres R New insights on the neuropathology neuropathology /neu·ro·pa·thol·o·gy/ (-pah-thol´ah-je) pathology of diseases of the nervous system. neu·ro·pa·thol·o·gy n. The study of diseases of the nervous system. of West Nile virus. FEMS Microbiol Lett. 2004;233:1-6. (11.) Dannan J, Backovic S, Dike S, Maragakis NJ, Krishnan C, Rothstein JD, et al. Viral-induced spinal motor neuron death is non-cellautonomous and involves glutamate excitotoxicity. J Neurosci. 2004;24:7566-75. (12.) Leis AA, Stokic DS. Neuromuscular manifestations of human West Nile virus infection. Curr Treat Options Neurol. 2005;7:15-22. (13.) Kuno Ca Persistence of arboviruses arboviruses (ar´bōvī´r  sz),n. and antiviral antibodies in vertebrate hosts: its occurrence and impacts. Rev Med Virol. 2001;11:165-90. (14.) Mostashari F, Bunning ML, Kitsutani PT, Singer DA, Nash D, Cooper MJ, et al. Epidemic West Nile encephalitis, New York, 1999: results of a household-based seroepidemiological survey. Lancet. 2001;358:261-4. (15.) Hayes CCa West Nile fever. In: Monath TP, editor. The arboviruses: epidemiology and ecology, vol. V. Boca Raton (FL): CRC (Cyclical Redundancy Checking) An error checking technique used to ensure the accuracy of transmitting digital data. The transmitted messages are divided into predetermined lengths which, used as dividends, are divided by a fixed divisor. Press; 1989. p. 59 88. (16.) Watson JT, Pertel PE, Jones RC, Siston AM, Paul WS, Austin CC, et al. Clinical characteristics and functional outcomes of West Nile Fever. Ann Intern Med. 2004;141:360-5. (17.) Georges A J, Lesbordes JL, Georges-Courbot MC, Meunier DMY, Gonzalez JR Fatal hepatitis from West Nile virus. Ann Inst Pasteur Virol. 1987;138:237-44. (18.) Jeha LE, Sila CA, Lederman RJ, Prayson RA, Isada CM, Gordon SM. West Nile virus infection: a new acute paralytic paralytic /par·a·lyt·ic/ (par?ah-lit´ik) 1. affected with or pertaining to paralysis. 2. a person affected with paralysis. par·a·lyt·ic adj. 1. illness. Neurology. 2003;61:55-9. (19.) Smith RD, Konoplev S, DeCourten-Myers G, Brown T. West Nile virus encephalitis with myositis myositis Inflammation of muscle tissue, often from bacterial, viral, or parasitic infection but sometimes of unknown origin. Most types destroy muscle and surrounding tissue. Bacteria may directly infect muscle (usually after injury) or produce substances toxic to it. and orchitis. Hum Pathol. 2004;35:254-8. (20.) Sampson BA, Armbrustmacher V. West Nile encephalitis: the neuropathology of four fatalities. Ann NY Acad Sci. 2001;951:172-8. (21.) Perelman A, Stern J. Acute pancreatitis in West Nile fever. Am J Trop Med Hyg. 1974;23:1150-2. (22.) Kulstad EB, Wichter MD. West Nile encephalitis presenting as a stroke. Ann Emerg Med. 2003;41:283. (23.) Platonov AE, Sbipulin GA, Shipulina OY, Tyutyunnik EN, Frolochkina TI, Lanciotti RS, et al. Outbreak of West Nile virus infection, Volgograd Region, Russia, 1999. Emerg Infect Dis. 2001;7:128-32. (24). Khairallah M, Ben Yahia S, Ladjimi A, Zeghidi H, Ben Romdhane F, Besbes L, et al. Chorioretinal involvement in patients with West Nile virus infection. Ophthalmology. 2004;111:2065-70. (25.) Kumar D, Prasad GV, Zaltzman J, Levy GA, Humar A. Community-acquired West Nile virus infection in solid-organ transplant recipients. Transplantation. 2004;77:399402. (26.) O'Leary DR, Martin AA, Montgomery SP, Kipp AM, Lehman JA, Biggerstaff BJ, et al. The epidemic of West Nile virus in the United States, 2002. Vector Borne Zoonotic Zoonotic A disease which can be spread from animals to humans. Mentioned in: Zoonosis Dis. 2004; 4:61-70. (27.) Han LL, Popovici F, Alexander JP Jr, Laurentia V, Tengelsen LA, Cernescu C, et al. Risk factors for West Nile virus infection and meningoencephalitis meningoencephalitis /me·nin·go·en·ceph·a·li·tis/ (me-ning?go-en-sef?ah-li´tis) inflammation of the brain and meninges. toxoplasmic meningoencephalitis , Romania, 1996. J Infect Dis. 1999;179:230-3. (28.) Pepperell C, Rau N, Krajden S, Kern R, Humar A, Mederski B, et al. West Nile virus infection in 2002: morbidity and mortality Morbidity and Mortality can refer to:
(29.) Sejvar JJ, Haddad MB, Ticrney BC, Campbell GL, Martin AA, van Gerpen JA, et al. Neurologic manifestations and outcome of West Nile virus infection. JAMA JAMA abbr. Journal of the American Medical Association . 2003;290:511-5. (30.) Sejvar JJ, Leis AA, Stokic DS, van Gerpen JA, Martin AA, Webb R, et al. Acute flaccid paralysis and West Nile virus infection. Emerg Infect Dis. 2003;9:788-93. (31.) Li J, Loeb JA, Shy ME, Shah AK, Tselis AC, Kupski WJ, et al. Asymmetric flaccid paralysis: a neuromuscular presentation of West Nile virus infection. Ann Neurol. 2003;53:703-10. (32.) Ahmed S, Libman R, Wesson K, Ahmed F, Einberg K. Guillain-Barrd syndrome: An unusual presentation of West Nile virus infection. Neurology. 2000;55:144-6. (33.) Cushing MM, Brat DJ, Mosunjac MI, Hennigar RA, Jernigan DB, Lanciotti R, et al. Fatal West Nile virus encephalitis in a renal transplant recipient. Am J Clin Pathol. 2004;121:26-31. (34.) Leis AA, Stokic DS, Webb RM, Slavinski SA, Fratkin J. Clinical spectrum of muscle weakness in human West Nile virus infection. Muscle Nerve. 2003;28:302-8. (35.) Martin DA, Muth DA, Brown T, Johnson AJ, Karabatsos N, Roehrig JT. Standardization of immunoglobulin M capture enzyme-linked immunosorbent assays for routine diagnosis of arboviral infections. J Clin Microbiol. 2000;38:1823-6. (36.) Roehrig JT, Nash D, Maldin B, Labowitz A, Martin DA, Lanciotti RS, et al. Persistence of virus-reactive serum immunoglobulin M antibody in confirmed West Nile virus encephalitis cases. Emerg Infect Dis. 2003;9:376-9. (37.) Kapoor H, Signs K, Somsel P, Downes FP, Clark PA, Massey JP. Persistence of West Nile Virus (WNV) IgM antibodies in cerebrospinal fluid from patients with CNS disease. J Clin Virol. 2004;31:289-91. (38.) Wong SJ, Demarest VL, Boyle RH, Wang T, Ledizet M, Kar K, et al. Detection of human anti-flavivirus antibodies with a West Nile virus recombinant antigen microsphere immunoassay. J Clin Microbiol. 2004;42:65-72. (39.) Parida M, Posadas G, Inoue S, Hasebe F, Morita K. Real-time reverse transcription loop-mediated isothermal i·so·ther·mal adj. Of, relating to, or indicating equal or constant temperatures. isothermal, isothermic having the same temperature. amplification for rapid detection of West Nile virus. J Clin Microbiol. 2004;42:257-63. (40.) Lanciotti RS, Kerst AJ, Nasci RS, Godsey MS, Mitchell CJ, Savage HM, et al. Rapid detection of West Nile virus from human clinical specimens, field-collected mosquitoes, and avian samples by a TaqMan reverse transcriptase-PCR assay. J Clin Microbiol. 2000;38:4066-71. (41.) Klce AL, Maidin B, Edwin B, Poshni I, Mostashari F, Fine A, et al. Long-term prognosis for clinical West Nile virus infection. Emerg Infect Dis. 2004;10:1405-11. (42.) Leis AA, Stokic DS, Polk JL, Dostrow V, Winkelmann M. A poliomyelitis-like syndrome from West Nile virus infection. N Engl J Med. 2002;347:1279-80. (43.) Marciniak C, Sorosky S, Hynes C. Acute flaccid paralysis associated with West Nile virus: motor and functional improvement in 4 patients. Arch Phys Med Rehabil. 2004;85:1933-8. (44.) Chang GJ, Kuno G, Pnrdy DE, Davis BS. Recent advancement in flavivirus vaccine development. Expert Rev Vaccines. 2004;3:199-220. (45.) Minke JM, Siger L, Karaca K, Austgen L, Gordy P, Bowen R, et al. Recombinant canarypoxvirus vaccine carrying the prM/E genes of West Nile virus protects horses against a West Nile virus-mosquito challenge. Arch Virol Suppl. 2004;221-30. (46.) Hall RA, Khromykh AA. West Nile virus vaccines. Expert Opin Biol Then 2004;4:1295-305. Edward B. Hayes, * James J. Sejvar, ([dagger]) Sherif R. Zaki, ([dagger]) Robert S. Lanciotti, * Amy V. Bode, * and Grant L. Campbell * * Centers for Disease Control and Prevention, Fort Collins, Colorado The City of Fort Collins, a home rule municipality situated on the Cache la Poudre River along the Colorado Front Range, is the county seat and most populous city in Larimer County, Colorado. , USA; and ([dagger]) Centers for Disease Control and Prevention, Atlanta Georgia, USA Dr. Hayes is a medical epidemiologist and pediatrician with the CDC's Division of Vector-Borne Infectious Diseases. His current research is focused on the epidemiology of arboviral and other vectorborne infectious diseases. Address for correspondence: Edward B. Hayes, Division of Vector-Borne Infectious Diseases, Centers for Disease Control and Prevention, PO Box 2087, Fort Collins, CO 80526, USA; fax: 970-221-6476; email: ebh2@cdc.gov |
|
||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion