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West Nile Virus Infection and its Neurological Manifestations

Department of Neurology, Marshfield Clinic, Marshfield, Wisconsin

REPRINT REQUESTS: Ken Madden, MD, PhD, Department of Neurosciences, Marshfield Clinic, 1000 North Oak Avenue (4F2), Marshfield, WI 54449, Telephone: 715-389-3225, Fax: 715-387-5727, Email: madden.kenneth{at}marshfieldclinic.org

Received: January 22, 2003.

Accepted: March 4, 2003.

	Abstract

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 
The West Nile virus caused an epidemic of meningoencephalitis in Midwest North America during 2002. The peak incidence coincided with the highest activity period of mosquito vectors in affected states. This epidemic followed recent established trends, not only of increased central nervous system involvement by the virus, but also increased incidence of dramatic neuromuscular impairment. Two cases are presented which illustrate the most concerning types of neuromuscular sequelae, diffuse weakness leading to respiratory insufficiency, and the development of focal weakness similar to poliomyelitis. The epidemiology and clinical characteristics of West Nile virus infection are also reviewed. Concern is expressed regarding the possibility of epidemics in other Midwestern states during future seasons of increased mosquito activity.

Key Words: West Nile virus • Encephalitis • Myelitis • Poliomyelitis

	INTRODUCTION

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 
The first documented human infection of the West Nile virus occurred in the West Nile district of Uganda in 1937, and this virus has subsequently been implicated in recent encephalitis epidemics within Russia, Israel and Romania.^1,2 It was the 1999 New York City outbreak within a large urban area, however, that stimulated concern over the virus among North Americans.³ Since that outbreak, the virus has spread coast to coast, with all but nine states within the continental United States reporting human infection. Surveillance immunoserological testing within endemic areas suggest that only 20% of individuals affected by the virus develop systemic symptoms, and less than 1% develop neurological manifestations.⁴ However, those that do develop nervous system involvement usually evolve a severe illness, with mortality rates of 12% to 14% and severe associated morbidity. The neurological manifestations are protean. Changes in mental status associated with meningitis or encephalitis are very common, but motor weakness is often the clinical indicator of West Nile virus as the causative agent.^5,6 Two cases of West Nile virus infection at a tertiary care center are presented as examples of the unusual neuromuscular manifestations of this virus.

	CASE REPORTS

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 
Case 1
A 79 year-old male resident of Illinois developed fever and malaise one week prior to and coincident with travel to upper Wisconsin. He initially sought medical attention in July at a regional urgent care facility, where he received ciprofloxin (500 mg twice daily) for possible urinary tract infection. He worsened on home antibiotic administration and returned for medical attention of persistent fever and the new development of mild confusion. While in the care facility, he had a generalized convulsion. Computed tomography revealed a 3 x 1 centimeter extra-axial frontal mass consistent with a meningioma, as well as mild generalized atrophy. He was intubated and treated with fosphenytoin, then transferred to a tertiary care center.

On arrival at the new center, his temperature was 101.6°F, with normal pulse and blood pressures on multiple assessments. He had a supple neck and unremarkable cardiopulmonary exam. There were no evident skin lesions. On neurological assessment, he was agitated and mildly combative. He did not follow commands or effectively communicate non-verbally. Cranial nerve examination was unremarkable. He was mildly tremulous but had good power in all limbs as assessed by resistive movements. He withdrew appropriately from a painful stimulus in all limbs. Tendon reflexes were normal in the upper extremities, but not elicitable in the lower extremities. Plantar responses were flexor bilaterally.

Initial laboratory results included a leukocyte count of 9,600 with 89% neutrophils. Hemoglobin was 11.3 g/dl. Electrolytes were normal. Glucose was 146 mg/dl. Transaminases were mildly elevated. Coagulation tests were normal. Initial chest x-ray and electrocardiogram were normal. Blood and urine cultures were negative. Lumbar puncture was performed on arrival to the new facility and revealed 3 RBCs and 958 WBCs per mm³, total protein of 218 mg/dl and glucose of 59 mg/dl. Aerobic and anaerobic cultures were negative. Cytology was negative. Lyme screen was negative. Polymerase chain reaction (PCR) for Herpes simplex virus was negative. Arbovirus IgM panel results included normal values for LaCrosse encephalitis and Eastern Equine encephalitis. Recent flavivirus infection was suggested, however, by IgM EIA optical density ratios (patient sera/normal human sera control) of 7.51 for St. Louis encephalitis, and >20 for West Nile virus encephalitis (tests are presumptive positive when ratio exceeds 2.0). Plaque reduction neutralization test confirmed West Nile virus infection.

The patient was extubated after arrival at the tertiary care center, and his arterial blood gas after extubation was notable for a pH of 7.38, a pCO² of 41 mmHg, and a pO² of 75 torr. Within 72 hours, however, he required reintubation after appreciable gradual diminishment of ventilatory effort and CO² retention (maximum 68 mmHg). A clear pulmonary cause of respiratory insufficiency could not be demonstrated. Serial chest x-rays were notable for a small left pleural effusion and intermittent demonstration of a right infrahilar opacity felt most likely relatable to intermittent endobronchial obstruction. Sputum cultures were persistently negative. Bronchoscopy was ultimately performed on hospital day twelve and revealed endobronchial plugging by thick secretions. Coincident with the development of pulmonary insufficiency, the patient developed mild systemic weakness as well. This was symmetrical and involved both proximal and distal musculature.

By two weeks, he had begun to improve. He was extubated on his fourteenth hospital day. His systemic weakness required extensive rehabilitative efforts, but he was making slow steady gains with ambulation and self-cares by the time of his discharge to a local rehabilitative facility on his twenty-sixth hospital day. Cerebrospinal fluid had begun to normalize (19 leukocytes, protein 79) by the ninth day.

Case 2
A 49 year-old, long-haul truck driver presented to her local hospital in August complaining of fever and chills. She was placed on antibiotics for presumed pneumonitis and discharged after a short hospitalization. Six days after her initial admission, she was readmitted to a second hospital with fever of 103.2°F, epigastric and lower abdominal pain, and four days of global headache. She had also just begun to notice weakness, numbness and pain of the right hand. Physical examination on that admission was notable for weakness of muscles of the right hand (no elaboration by admitting physician). Computed tomography of brain was unremarkable. Lumbar puncture revealed 225 leukocytes/mm³ (90% lymphocytes), glucose of 30 mg/dl, and protein of 60 mg/dl. Bacterial cultures were negative. Lyme screen was negative. The patient was transferred to a tertiary care center.

On arrival to the new center, physical examination was notable for substantial weakness of multiple muscles of the right upper extremity, including deltoid, biceps, triceps, wrist flexors, wrist extensors, finger flexors and finger extensors. Sensation was severely impaired in the right arm and deep tendon reflexes were absent. The sensorimotor exam of the remaining limbs was normal, as were deep tendon reflexes. Cognition, cranial nerves, coordination and gait were all normal. Serum creatine phosphokinase was normal. CSF analysis was repeated (7 days after initial lumbar puncture) and was notable for 106 leukocytes/mm³ (90% lymphocytes), glucose of 57 mg/dl, and protein of 88 mg/dl. Bacterial, fungal, and acid-fast bacilli stains and cultures were negative. Viral cultures were negative. Cytology was negative. PCR for Herpes simplex virus was negative. Antibody assays for rubeola, mumps and varicella antibodies were negative. Arbovirus IgM panel results included normal values for LaCrosse encephalitis and Eastern Equine encephalitis, but positive IgM EIA optical density ratios of 4.4 for St. Louis encephalitis, and >20 for West Nile virus encephalitis. Plaque reduction neutralization test confirmed West Nile virus infection.

Further evaluation of the patient’s right arm weakness included magnetic resonance imaging of brain and cervical spine. The cerebral study was unremarkable. The cervical imaging revealed degenerative changes causing central canal narrowing and foraminal compromise affecting the right fifth cervical root. These abnormalities did not appear significant enough to cause the sensorimotor impairment of the right arm. Electromyography and nerve conduction testing of the limb were therefore performed. Nerve conductions were generally remarkable only for decreased motor unit amplitudes and absent F-waves (median and ulnar). Electromyography of multiple distal and proximal muscles of the right arm revealed increased insertional activity and decreased recruitment in all muscles, but normal waveforms in paraspinal muscles. There were no fibrillations. The electromyographic impression was that the findings were most consistent with a preganglionic neuropathology involving cervical spinal cord segments C5 to T1. Clinically, she improved during her hospitalization, with normalization of her mental status and resolution of headache and fever. She remained with pronounced weakness of the right arm at the time of discharge.

	DISCUSSION

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 
Viral epidemiology
The West Nile virus is a single-stranded RNA virus of the genus Flavivirus, which also includes the viruses responsible for St. Louis encephalitis, Japanese encephalitis and Murray Valley encephalitis. The mechanism by which the West Nile virus was introduced into the Western hemisphere remains unknown, but its transmission cycle is now well understood. Wild birds, particularly songbirds, serve as the primary amplification hosts in nature, though infections also occur in horses and other avian species. Geographical spread of the virus in North America has occurred along the migratory pathways of the usual bird hosts. Regional infections of birds within the Corvidae family (crows, jays and magpies) have particular importance because the severe illness that develops in these species leads to high avian mortality, therefore serving as a sentinel of the virus within the locality.⁷ The virus is transmitted from bird to human hosts through the bite of mosquitoes, usually those of the Culex genus. Mammals do not generate viremia of a magnitude that allows further transmission of the virus.⁸ (The interested reader is referred to excellent discussions of these topics in the preceding edition of this journal).^9,10

In 2002, the state harboring the most human cases of West Nile virus infection was Illinois, with 836 cases and 56 deaths. Infections began in late summer and peaked in September. Because of the rapid immunity to recurrent infection that develops in birds, the incidence may more likely increase in neighboring states than in Illinois during future seasonal outbreaks.

Clinical manifestations of West Nile virus infection
Typically, flavivirus infection in humans is manifested by three clinical syndromes: fever/arthralgia/rash, viral hemorrhagic fever, and neurological disease.¹¹ The West Nile virus has developed a particularly neurotropic invasion pattern, and this may have recently evolved. Prior to 1996, few patients afflicted with the virus suffered neurological manifestations, and the severe and often fatal encephalitides that have been associated with subsequent outbreaks have been surprising.² Inoculated virus is thought to seed the endoplasmic reticulum where the virus replicates, ultimately resulting in secondary viremia that penetrates the central nervous system.¹² Clinical symptoms develop approximately two days after the peak of viremia. The virulence and neuroinvasiveness of the virus likely relates to the level and duration of viremia within infected individuals, as well as, the relative preservation of the cerebrovascular endothelium.¹³ Some researches speculate that susceptibility may be genetically determined as well.¹⁴

Mechanisms of viral entry into, and diffusion through, components of the nervous system are not currently understood, but may involve the West Nile virus envelope E protein that mediates cell attachment.¹⁵ After the virus is established in the central nervous system, its pathophysiology is based on neuronal proliferation, cytotoxic immune responses, perivascular inflammation, and microglial nodule formation.^12,16,17 In fatal cases, the most common inflammatory focus is brainstem, but thalamus, cerebellum, and cerebral cortex are also involved.¹⁸ In contrast to other arboviral infections, the inflammatory infiltrate is minimal and there is no vasculitis.¹⁶ Until recently, autopsies of fatal cases have not included sectioning of spinal cord, and neuropathology of this portion of the central nervous system had been lacking.

Most West Nile virus infections do not result in clinical symptoms,⁴ though many cases of mild disease may go unreported. "West Nile fever" is one such milder expression of the disease causing fever, malaise, and arthralgias that usually resolve within a week (table 1). Half of such patients may develop a roseolar or macropapular rash or generalized lymphadenopathy, but these also commonly resolve without significant sequelae. The fatality rate for patients with these mild cases of West Nile virus infection is quite low (<1%).

Within the last few months, autopsy evidence has emerged that implicates spinal cord involvement as the underlying cause of the muscle weakness associated with West Nile virus infection in some patients. The first report of asymmetric flaccid paralysis in conjunction with West Nile virus infection was in 1979, but no pathological data from this patient was obtained.²³ This phenomenon was then largely unreported until instances began surfacing with the North American epidemics. The initial cases of severe weakness with depressed tendon reflexes were attributed to Guillain-Barré syndrome.^24,25 During the 2002 outbreaks in the southwestern United States, a series of patients were encountered that had areflexic flaccid paralysis with preserved sensation.^26,27 Electrophysiologic studies were notable for markedly decreased motor responses in the involved limbs, with asymmetric muscle denervation, but without evidence of demyelination, myopathy, or sensory conduction disturbances. The electrophysiological evidence was not consistent with Guillain-Barré, and the possibility of anterior myelitis complicating West Nile virus infection was reported to the U.S. Center for Disease Control and Prevention. Additional patients displayed similar clinical syndromes in the same region. Eventually three patients were autopsied after dying from pulmonary complications.

Pathological inspection of the spinal cord in these patients revealed gliosis and neuronal loss in the ventral grey matter, with extensive perivascular cuffing by inflammatory cells. Inflammatory cells also surrounded dying anterior horn neurons. Notably, these findings were similar to necropsy findings of spinal cord in animals infected with the West Nile virus.^28,29 These data seem to suggest a predilection of this virus for the anterior horn cell and the production of a clinical state similar to that of acute poliomyelitis.

The clinical case presentations within this report include one patient whose primary neuromuscular manifestation of West Nile virus infection was respiratory failure. No pulmonary cause of his ventilator dependency was determined. His degree of mental status impairment did not appear profound enough to cause central respiratory failure. Other neurological causes of respiratory insufficiency such as critical care neuropathy or myopathy were not excluded by electrophysiological testing, but he did not display the other clinical manifestations of widespread neuropathy/myopathy that are usually associated with these conditions. The second patient in this report developed the clinical symptoms (asymmetrical, areflexic, flaccid paralysis) and electrophysiological findings typical for poliomyelitis involving the cervical spinal cord. Her clinical history and examination was not consistent with Guillain-Barré, nor did the electrophysiology suggest such. Brachial plexitis could be an alternative etiology for her clinical presentation, but the electrophysiology evidence also conflicted with this diagnosis. These cases therefore illustrate the type of severe neuromuscular involvement that can occur with West Nile virus infection. Both respiratory failure and the expression of a poliomyelitis-like syndrome are associated with higher incidence of fatal outcome of the infection,³⁰ though both patients reported here survived.

Diagnosis and treatment of West Nile virus infection
Unusual laboratory data in infected patients is typically non-specific. A modest leukocytosis is often present, but leukocyte counts have been normal in over 50% of patients. Computed tomography of brain has rarely revealed specific pathology. Magnetic resonance imaging has occasionally revealed leptomeningeal enhancement or periventricular inflammatory changes, but up to 70% of such images have been unremarkable.⁶ Cerebrospinal fluid analysis often discloses a mild lymphocyte predominant leukocytosis, but counts rarely exceed 100 cells/microliter. Spinal fluid glucose is normal and only modest elevation of protein occurs (rarely exceeding 100 mg/dl). Because of the low levels of viremia associated with human West Nile virus infection, neither virus culture nor PCR are sensitive for its detection.

Specific laboratory testing for West Nile virus infection can be accomplished with IgM antibody capture enzyme-linked immunosorbent assay (EIA) in both serum and spinal fluid. Over 95% of those suspected of West Nile virus infection during the New York epidemic had demonstrable antibody.³⁰ The EIA assay does cross-react with other flaviviruses, though quantitatively less so.³¹ Detection of antibody in the spinal fluid is diagnostic of central nervous system involvement, as the IgM antibody does not cross the blood-brain barrier. Specific testing is available through state health departments, and identified infection is reportable to infectious disease registries. The reporting of even a single case to state agencies may have substantial implications for regional public health policies.³⁰

Thus far, no treatment has been proven effective for West Nile virus infection. Patient care largely involves supportive measures, including the usual prophylactic measures for complications of immobility and depressed alertness. Acyclovir for treatment of Herpes simplex encephalitis could certainly be considered until this possibility is excluded by specific testing, or the West Nile virus is positively implicated. Specific treatment for West Nile virus infection has been attempted with intravenous immunoglobulin³² and oral ribavirin,³³ but neither treatment has established efficacy. The U.S. Food and Drug Administration has approved one clinical trial to explore the efficacy of inter-feron compared to placebo, and it is now accruing patients.

	SUMMARY

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 
The West Nile virus has caused epidemics of increasing magnitude in North American since its arrival in 1999. Coincident with increased infection rates, a greater incidence of severe meningoencephalitic illness and neuromuscular impairment related to the virus has evolved. The respiratory failure or poliomyelitis syndromes that occur lead to high morbidity and mortality rates. Following the large outbreak of illness in Illinois during 2002, similar epidemics may occur in neighboring states during future seasons of high mosquito activity. Usual preventive measures against mosquito bites, such as the use of repellants, and mosquito control measures, should be a high priority in these susceptible regions.^10,30 Health care workers need to be vigilant toward the possibility of West Nile virus infection in patients encountered with typical symptoms, both for patient care and public health concerns.

	REFERENCES

TOP Abstract INTRODUCTION CASE REPORTS DISCUSSION SUMMARY REFERENCES

 

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