Rabies (Encephalitic)

Encephalitic (furious) rabies is an almost invariably fatal acute viral encephalitis caused by rabies virus (RABV), accounting for ~80% of clinical rabies cases. [1] It is characterized by fluctuating consciousness, hydrophobia, aerophobia, inspiratory spasms, and autonomic dysfunction, progressing to coma and death typically within 5–7 days of symptom onset without intensive care. [2] Approximately 59,000 human rabies deaths occur annually worldwide, with 98% linked to canine exposures. [3-4]

The following figure illustrates the pathogenic journey of RABV from initial bite inoculation through neuromuscular junction entry, CNS invasion, and centrifugal spread to salivary glands:

1. History

• Exposure history is the single most critical element: animal bite (dog, bat, raccoon, skunk, fox), scratch, or mucous membrane contact with saliva — may have occurred weeks to months prior [6]
• Ask about geographic location, travel to rabies-endemic regions (Asia, Africa), occupation (veterinarian, animal handler, cave explorer), and outdoor/recreational activities [4][7]
• Prodromal symptoms (2–10 days): fever, malaise, headache, nausea, sore throat — nonspecific and easily missed [2][8]
• Pain, paresthesia, or pruritus at the bite site is often the earliest neurological symptom and is highly suggestive [2][8]
• Progression to agitation, anxiety, confusion, hallucinations, hypersalivation, difficulty swallowing
• Hydrophobia: pharyngeal spasms triggered by sight, sound, or perception of water [6][8]
• Aerophobia: spasms triggered by air drafts
• Periods of agitation alternating with lucidity — a key feature of furious rabies [8]
• In the US, rabies diagnosis is almost always missed at the first clinical encounter because exposure history may be remote or unrecognized, particularly with bat exposures [6][9]

2. Alarm Features

• Hydrophobia or aerophobia — virtually pathognomonic for rabies [2][10]
• Inspiratory muscle spasms (spontaneous or provoked)
• Rapidly progressive encephalitis with autonomic instability (tachycardia, hypersalivation, hyperpyrexia, piloerection)
• Fluctuating consciousness with episodes of extreme agitation
• Cardiac arrhythmias — supraventricular arrhythmias, heart block, myocarditis mimicking STEMI [11-13]
• Seizures, delirium, or coma
• Any acute encephalitis in a patient with a history of animal bite in an endemic area

3. Medications

• No effective antiviral therapy exists once clinical symptoms develop [1][14-15]
• Milwaukee Protocol (therapeutic coma + ketamine + ribavirin + amantadine): now considered ineffective with at least 64 documented failures; should be abandoned [14-16]
• Ribavirin and interferon-α have been disappointing [15]
• Minocycline and corticosteroids should NOT be used — may aggravate disease [15]
• Ketamine and midazolam are used for symptom palliation (sedation, dysautonomia control) rather than as curative therapy [2]
• Nimodipine has been added in some protocols for vasospasm but carries risk of severe hypotension; use with extreme caution [2]
• Post-exposure prophylaxis (PEP) is the only effective intervention and must be given before symptom onset:
  • Unvaccinated: wound cleansing + HRIG 20 IU/kg infiltrated into wound + rabies vaccine IM on days 0, 3, 7, 14 (4-dose ACIP schedule) [17-18]
  • Previously vaccinated: 2 doses on days 0 and 3, no HRIG [17]

4. Diet

• Dysphagia is a cardinal feature — patients cannot swallow due to pharyngeal spasms; oral intake is impossible once hydrophobia develops [8][10]
• IV hydration and nutritional support are required
• No specific dietary triggers or long-term dietary management apply

5. Review of Systems

• Neurological: altered mental status, agitation, hallucinations, seizures, focal deficits, cranial nerve palsies (especially in bat-acquired cases), myoclonus, tremor [2][19]
• Respiratory: inspiratory spasms, periodic/ataxic breathing, respiratory arrest [10][13]
• Cardiovascular: palpitations, chest pain (myocarditis), arrhythmias [11][13]
• GI: nausea, vomiting, hypersalivation, GI bleeding [10]
• Autonomic: diaphoresis, piloerection, priapism, lacrimation, pupillary abnormalities
• Endocrine: diabetes insipidus, SIADH, hypothalamic-pituitary dysfunction [20-21]
• Musculoskeletal: fasciculations, weakness at bitten extremity

6. Collateral History and Family History

• Collateral history is essential: witnesses to animal exposure, travel companions, family members who may recall a bite the patient has forgotten or dismissed
• Children may not report bat contact or minor bites [6]
• Bat exposure may be unrecognized (e.g., bat found in room of sleeping person) [17]
• No hereditary predisposition; family history is not contributory
• Organ/tissue transplant history — rare cases of transmission via transplanted corneas and organs [17]

7. Risk Factors

• Dog bite in Asia or Africa — accounts for ~98% of global human rabies [4][22]
• Bat exposure in the Americas — most common source in the US (70% of indigenously acquired cases) [9]
• Bites to highly innervated areas (face, hands) or deep muscle bites increase transmission efficiency [2][6]
• Proximity of bite to CNS (head, neck) may shorten incubation period [6]
• Children — higher risk due to inquisitive behavior, smaller stature (more head/face bites), and failure to report exposures [6]
• Failure to receive or complete PEP [3]
• Occupational exposure: veterinarians, animal control workers, laboratory workers, cave explorers [4]
• Travel to endemic regions without pre-exposure prophylaxis [22]

8. Differential Diagnosis

• Tetanus — trismus (lockjaw), opisthotonus, sustained muscle rigidity (vs. intermittent spasms in rabies); no altered consciousness until late [10]
• Herpes simplex encephalitis (HSV-1) — temporal lobe predilection on MRI, hemorrhagic changes; no hydrophobia [7][23]
• Other viral encephalitides (arboviral, enteroviral, VZV) — distinguished by epidemiology, CSF findings, MRI patterns [7][24]
• Autoimmune encephalitis (anti-NMDAR, LGI1) — more subacute onset, psychiatric features, seizures; antibody testing differentiates [23][25]
• Guillain-Barré syndrome — mimics paralytic rabies; ascending weakness without altered consciousness [2]
• Delirium tremens — alcohol withdrawal history, tremor, hallucinations; no hydrophobia [10]
• Hysterical pseudohydrophobia — psychogenic; no autonomic dysfunction or progression [10]
• Postvaccinal encephalomyelitis — history of nervous-tissue rabies vaccine (older formulations) [10]
• Cerebral malaria, bacterial meningitis — in endemic settings, consider concurrent infections

9. Past Medical History

• Prior rabies vaccination status — critical for determining PEP regimen and prognosis; most survivors had received at least partial vaccination before symptom onset [8][16]
• Previous animal bites or PEP courses
• Immunocompromised states (HIV, chemotherapy) — may alter immune response and PEP efficacy; immunocompromised patients should receive 5-dose PEP schedule [18]
• History of organ transplantation (rare transmission route) [17]
• No specific chronic illnesses predispose to rabies, but immunosuppression may impair viral clearance

10. Physical Exam

• Vital signs: tachycardia, hypertension or hypotension, hyperpyrexia, irregular respirations [10][13]
• Inspection of bite wound: look for healing bite marks, especially on extremities, face, or hands; may show local inflammation
• Neurological exam:
  • Fluctuating level of consciousness with periods of lucidity and agitation [2]
  • Hydrophobia test: offering water provokes visible pharyngeal spasms and terror [8]
  • Aerophobia test: blowing air on face triggers spasms
  • Hypersalivation ("foaming at the mouth")
  • Cranial nerve palsies (more common in bat-acquired cases) [19]
  • Myoclonus, tremor, fasciculations
  • Late: flaccid paralysis, areflexia, coma [2]
• Autonomic signs: piloerection, diaphoresis, pupillary dilation, priapism, lacrimation
• Cardiac: irregular rhythm, signs of heart failure (myocarditis) [11][13]
• Myoedema (mounding of muscle on percussion) — seen in paralytic form [2]

11. Lab Studies

• Routine labs: plasma neutrophil leukocytosis; otherwise often unremarkable [26]
• CSF: mild lymphocytic pleocytosis in only ~60% of patients in the first week; mildly elevated protein (more pronounced in bat-acquired cases); normal glucose [19][26]
• Antemortem diagnostic panel (contact CDC or public health lab): [6][27]
  • Saliva: RT-PCR for RABV RNA (sensitivity ~86%) [28]
  • Nuchal skin biopsy (nape of neck, hair follicle-containing): immunohistochemistry for rabies antigen in cutaneous nerves [6][27]
  • Serum and CSF: rabies virus neutralizing antibody (RFFIT) — in unvaccinated patients, CSF antibody confirms diagnosis [6]
  • CSF: RT-PCR for RABV RNA (sensitivity ~45% antemortem, higher postmortem) [28]
• Sequential sampling is indicated if initial tests are negative but clinical suspicion remains high [6]
• Neurofilament light chain (NfL): emerging biomarker — significantly elevated in rabies vs. other encephalitides [29]
• No single test is sufficient for antemortem diagnosis; multiple specimen types are required [27]

12. Imaging

• MRI brain (preferred over CT): [2][30]
  • Non-comatose phase: subtle, ill-defined T2/FLAIR hyperintensities in brainstem, hippocampi, hypothalami, deep/subcortical white matter — without gadolinium enhancement (a distinguishing feature from other viral encephalitides) [2][30]
  • Comatose phase: more widespread T2 hyperintensities; gadolinium enhancement may appear along brainstem and midline structures [2]
  • Brachial plexus enhancement on the bitten side may be seen even during prodrome [2]
  • Novel findings include dentate nuclei involvement, cranial nerve enhancement, "hot cross bun" sign in pons [31]
• CT head: low sensitivity; may show only diffuse edema in late stages
• The lack of contrast enhancement in a noncomatose encephalitis patient should raise suspicion for rabies over other viral encephalitides [30]

The following MRI demonstrates characteristic brainstem T2 hyperintensities in a confirmed case of rabies encephalitis:

13. Special Tests

• Direct fluorescent antibody (DFA) test: gold standard for postmortem diagnosis on brain tissue; detects rabies antigen [27]
• Negri bodies: eosinophilic cytoplasmic inclusions in hippocampal and cerebellar Purkinje neurons — pathognomonic on histopathology [32]
• Virus isolation from saliva [27]
• WHO clinical case definition: acute neurologic syndrome dominated by hyperactivity (furious) or paralysis, progressing to coma and death within 7–10 days [6]
• Animal testing: if the biting animal is available, DFA testing of brain tissue; 10-day observation period for dogs, cats, and ferrets [8][17]

14. ECG

• Cardiac involvement is common and clinically significant [1][11][13]
• Supraventricular arrhythmias (most common cardiac finding) [13]
• ST-segment elevation mimicking STEMI — due to interstitial myocarditis, not coronary occlusion [11]
• Heart block (including complete heart block) — may be the terminal event [12]
• Autonomic denervation manifests as loss of heart rate variability [33]
• ECG should be obtained in all suspected cases; continuous telemetry monitoring is essential
• Vagus nerve neuritis found at autopsy explains many of the cardiac manifestations [12]

15. Assessment

• Encephalitic rabies is a clinical diagnosis supported by exposure history and confirmed by specialized laboratory testing [6]
• Average survival from symptom onset to death: 5.7 days (furious form) without intensive care [2]
• Only ~34 well-documented survivors exist; most had received partial vaccination and/or were infected with bat RABV variants; many had severe neurological sequelae [8][14]
• The disease is almost 100% fatal once clinical signs appear [1][5]
• Atypical presentations (focal brainstem signs, myoclonus, hemichorea, Horner syndrome) are more common with bat RABV variants and contribute to frequent misdiagnosis [2][34]
• Complications in ICU-managed patients include ARDS, diabetes insipidus, myocarditis, GI bleeding, and multi-organ failure [1][20]

16. Treatment Plan

Initial stabilization

• Airway management — early intubation may be needed for inspiratory spasms and airway protection
• IV access, continuous telemetry, ICU admission
• Aggressive sedation with benzodiazepines (midazolam) and ketamine for agitation, spasms, and dysautonomia [2]
• Avoid neuromuscular paralysis if possible (masks clinical progression)

Definitive management

• No proven curative therapy exists [1][14-15]
• Decision between aggressive critical care vs. palliative approach should be made early with the patient's family:
  • Favorable factors for aggressive approach: prior partial vaccination, young age, immunocompetent, bat RABV variant, early neutralizing antibody detection, mild neurological disease at presentation [8]
  • Palliative approach: liberal sedation (midazolam, opioids) to relieve suffering; appropriate for most cases, especially canine RABV variant [2][8]
• Milwaukee Protocol should no longer be used — at least 64 failures documented [14]
• Manage complications: vasopressors for hemodynamic instability, antiarrhythmics, correction of DI/SIADH, ventilatory support

PEP (pre-symptom only)

• Wound cleansing with soap/water for ≥15 minutes + povidone-iodine [3][8]
• HRIG 20 IU/kg infiltrated into and around wound [17]
• Rabies vaccine IM: days 0, 3, 7, 14 (4-dose schedule per ACIP) [18]

17. Disposition

• All suspected rabies cases require ICU admission once neurological symptoms develop [1][8]
• Strict contact and droplet precautions for healthcare workers; PEP for any staff with mucous membrane or open wound exposure to patient saliva [17]
• Rabies is a nationally notifiable disease — immediate notification to local/state public health department and CDC [6]
• Infectious disease and neurology consultation
• Palliative care consultation when aggressive treatment is not pursued or deemed futile
• No role for observation unit or outpatient management once symptomatic

18. Follow Up / Return Precautions

For exposed but asymptomatic patients receiving PEP

• Complete the full vaccine series on schedule (days 0, 3, 7, 14) [18]
• Return immediately for any neurological symptoms: paresthesia at bite site, anxiety, agitation, difficulty swallowing, fever with behavioral changes
• Wound care follow-up; monitor for secondary bacterial infection

For symptomatic patients

• Prognosis is nearly uniformly fatal; family counseling and goals-of-care discussions are paramount [1][14]
• Rare survivors require prolonged neurorehabilitation; most have significant neurological sequelae [8][14]
• Healthcare workers exposed to patient secretions should receive PEP evaluation

Public health follow-up

• Ensure the biting animal is captured for testing or observation if possible [8]
• Contact tracing for other potential exposures from the same animal source

References

1. Rabies: A Medical Perspective. — Jackson AC. Revue Scientifique Et Technique. 2018.

2. Human Rabies: Neuropathogenesis, Diagnosis, and Management. — Hemachudha T, Ugolini G, Wacharapluesadee S, et al. The Lancet. Neurology. 2013.

3. Human Rabies Despite Post-Exposure Prophylaxis: A Systematic Review of Fatal Breakthrough Infections After Zoonotic Exposures. — Whitehouse ER, Mandra A, Bonwitt J, et al. The Lancet. Infectious Diseases. 2023.

4. Use of a Modified Preexposure Prophylaxis Vaccination Schedule to Prevent Human Rabies: Recommendations of the Advisory Committee on Immunization Practices - United States, 2022. — Rao AK, Briggs D, Moore SM, et al. MMWR. Morbidity and Mortality Weekly Report. 2022.

5. Neuroimmunology of rabies: New insights into an ancient disease. — Bastos V, Pacheco V, Rodrigues ÉDL, et al. Journal of Medical Virology. 2023.

6. Rabies. — Ryan M. Wallace and David R. Shlim CDC Yellow Book. 2025.

7. Acute Viral Encephalitis. — Tyler KL. The New England Journal of Medicine. 2018.

8. Current Status of Rabies and Prospects for Elimination. — Fooks AR, Banyard AC, Horton DL, et al. Lancet. 2014.

9. Vital Signs: Trends in Human Rabies Deaths and Exposures - United States, 1938-2018. — Pieracci EG, Pearson CM, Wallace RM, et al. MMWR. Morbidity and Mortality Weekly Report. 2019.

10. The Clinical Picture of Rabies in Man. — Warrell DA. Transactions of the Royal Society of Tropical Medicine and Hygiene. 1976.

11. Rabies Encephalitis With Myocarditis Mimicking ST-Elevation Myocardial Infarction. — Park SC, Crane IM, Pal K, Cagnina RE. Open Forum Infectious Diseases. 2019.

12. Diagnosis, Management and Post-Mortem Findings of a Human Case of Rabies Imported Into the United Kingdom From India: A Case Report. — Pathak S, Horton DL, Lucas S, et al. Virology Journal. 2014.

13. Pathophysiologic Studies in Human Rabies. — Warrell DA, Davidson NM, Pope HM, et al. The American Journal of Medicine. 1976.

14. Demise of the Milwaukee Protocol for Rabies. — Jackson AC. Clinical Infectious Diseases : An Official Publication of the Infectious Diseases Society of America. 2025.

15. Antiviral Therapy for Human Rabies. — Appolinario CM, Jackson AC. Antiviral Therapy. 2014.

16. Current and Future Approaches to the Therapy of Human Rabies. — Jackson AC. Antiviral Research. 2013.

17. FDA Drug Label. — Food and Drug Administration (DailyMed)..

18. Use of a Reduced (4-Dose) Vaccine Schedule for Postexposure Prophylaxis to Prevent Human Rabies: Recommendations of the Advisory Committee on Immunization Practices. — Rupprecht CE, Briggs D, Brown CM, et al. MMWR. Recommendations and Reports : Morbidity and Mortality Weekly Report. Recommendations and Reports. 2010.

19. Clinical Features of Dog- And Bat-Acquired Rabies in Humans. — Udow SJ, Marrie RA, Jackson AC. Clinical Infectious Diseases : An Official Publication of the Infectious Diseases Society of America. 2013.

20. Human Rabies: Clinical Features, Diagnosis, Complications, and Management. — Udwadia ZF, Udwadia FE, Katrak SM, et al. Critical Care Medicine. 1989.

21. Correlation of Clinical and Neuroimaging Findings in a Case of Rabies Encephalitis. — Pleasure SJ, Fischbein NJ. Archives of Neurology. 2000.

22. Boostability After Single-Visit Pre-Exposure Prophylaxis With Rabies Vaccine: A Randomised Controlled Non-Inferiority Trial. — Overduin LA, Koopman JPR, Prins C, et al. The Lancet. Infectious Diseases. 2024.

23. Encephalitis. — Binks SNM, Saylor D, Easton A, Thakur KT, Irani SR. Lancet. 2026.

24. Viral Encephalitis. — Venkatesan A, Murphy OC. Neurologic Clinics. 2018.

25. Acute Encephalitis in Immunocompetent Adults. — Venkatesan A, Michael BD, Probasco JC, Geocadin RG, Solomon T. Lancet. 2019.

26. Rabies and Other Lyssavirus Diseases. — Warrell MJ, Warrell DA. Lancet. 2004.

27. Guide to Utilization of the Microbiology Laboratory for Diagnosis of Infectious Diseases: 2024 Update by the Infectious Diseases Society of America (IDSA) and the American Society for Microbiology (ASM). — Miller JM, Binnicker MJ, Campbell S, et al. Clinical Infectious Diseases : An Official Publication of the Infectious Diseases Society of America. 2024.

28. Utility of real‐time Taqman PCR for antemortem and postmortem diagnosis of human rabies. — Mani RS, Madhusudana SN, Mahadevan A, et al. Journal of Medical Virology. 2014.

29. Neurofilament Light Chain: A Potential Diagnostic Biomarker for Rabies. — Siddalingaiah N, Lodha L, Ashwini MA, et al. Microbiology and Immunology. 2025.

30. MR Imaging in Human Rabies. — Laothamatas J, Hemachudha T, Mitrabhakdi E, Wannakrairot P, Tulayadaechanont S. AJNR. American Journal of Neuroradiology. 2003.

31. Neuroimaging Findings in Rabies Encephalitis. — Bhat MD, Priyadarshini P, Prasad C, Kulanthaivelu K. Journal of Neuroimaging : Official Journal of the American Society of Neuroimaging. 2021.

32. Histopathology of vaccine‐preventable diseases. — Solomon IH, Milner DA. Histopathology. 2017.

33. Survival after Treatment of Rabies with Induction of Coma. — Willoughby RE, Tieves KS, Hoffman GM, et al. The New England Journal of Medicine. 2005.

34. Comparative Pathogenesis of Rabies in Bats and Carnivores, and Implications for Spillover to Humans. — Begeman L, GeurtsvanKessel C, Finke S, et al. The Lancet. Infectious Diseases. 2018.