Francisella tularensis: Difference between revisions
From IDWiki
Francisella tularensis
(→) |
(→) |
||
Line 94: | Line 94: | ||
*Without treatment, complications include meningitis, encephalitis, pericarditis, peritonitis, osteomyelitis, splenic rupture, and thrombophlebitis |
*Without treatment, complications include meningitis, encephalitis, pericarditis, peritonitis, osteomyelitis, splenic rupture, and thrombophlebitis |
||
*Rarely, [[Guillain-Barré syndrome]] following ulceroglandular tularemia |
*Rarely, [[Guillain-Barré syndrome]] following ulceroglandular tularemia |
||
*Mortality is 60% without treatment, and decreases to 2 to 4% with antibiotics |
|||
==Diagnosis== |
==Diagnosis== |
Revision as of 10:08, 3 September 2020
- Zoonontic infection carried on rodents and rabbits and transmitted by biting insects
- Presentation depends on route of entry: (ulcero)glandular, oculoglandular, pharyngeal, typhoidal, or pneumonic
- Treatment is streptomycin
Background
Microbiology
- A fastidious Gram-negative coccobacillus
- Multiple subspecies, including tularensis, holarctica, novocida, mediasiatica, which are further subdivided into clades, and related species Francisella philomiragia and Francisella hispaniensis
- Subspecies of importance to humans include:
- Subspecies tularensis (type A strains)
- Found in North America and rarely Europe
- Two major clades (AI and AII) and four subclades (AIa, AIb, AIIa, and AIIb)
- Overall the subspecies is the most virulent subspecies, and specifically the AIb subclade is the most virulent strain
- Subspecies holarctica (type B strains)
- Found in the entire northern hemisphere as well as Australia
- Four major clades (B4 in North America, B6 in Western Europe, B12 in Eastern Europe and Central Asia, and B16 in Japan and other areas in Eastern Asia) and a number of subclades
- Subspecies novicida
- Rare cause of disease in humans, usually in immunocompromised hosts, and presents with bacteremia rather than tularemia
- Subspecies mediasiatica does not cause disease in humans
- Subspecies tularensis (type A strains)
History
- Discovered in 1911 in Tulare county, California
- Many names: deer fly fever, rabbit fever, etc...
Epidemiology
- Zoonotic infection whose main animal reservoirs are rodents and rabbits
- In North America, the most important reservoirs are Sylvilagus species (especially Sylvilagus nuttalii, the cottontail rabbit) and Lepus species lagomorphs (rabbits), and a number of rodents including voles, squirrels, muskrats, and beavers
- In Europe, the reservoirs include voles, hamsters, mice, and hares
- Essentially worldwide Northern Hemisphere distribution, especially in the US, Japan, Russia, and Scandinavian countries
- Transmission:
- Vector-borne
- In North America, by Amblyomma americanum ticks, Dermacentor variabilis ticks, Dermacentor andersoni ticks, Chrysops discalis deer flies
- In Europe, Aedes cinereus and Ochlerotatus exrucians mosquitoes are more important, as well as Chrysops relictus deer flies and Haematopota pluvialis horse flies
- Direct contact with animal products, including skinning, dressing, and eating wild game
- Viable in carcasses and dust for up to 136 days
- Inhalation of aerosolized vectors (e.g. lawn-mowing), contact with contaminated water or mud, and animal bites of animals that have killed infected reservoir hosts (e.g. cats killing rodents)
- Vector-borne
Pathophysiology
- Infectious dose depends on route, but is as low as 10 to 50 organisms when injected intradermally or inhaled (or several orders of magnitude higher if ingested)
- TLR4 has less affinity for its LPS compared to other bacteria
- Capsule inhibits IgM and complement C3
- Capsule-deficient strains are both less immunogenic and less virulent
- Facultative intracellular growth
- Can infect and persist within erythrocytes, providing protection against aminoglycosides
Clinical Manifestations
- Incubation period of 3 to 5 days (range 1 to 21 days)
- The first symptom is usually a papule at the site of inoculation that develops into an ulcer over 1 to 2 days, but this may go unnoticed
- This is followed by fever which likely corresponds to initial lymphohematogenous dissemination
- Other common symptoms include chills, headache, malaise, anorexia, and fatigue
- May also have cough, myalgias, chest discomfort, vomiting, sore throat, abdominal pain, and diarrhea
- May have a relative bradycardia (more common in US than Europe)
- These symptoms may remit and relapse, presenting as a subacute relapsing fever over weeks, with associated weight loss, deconditioning, and lymphadenopathy
- Bloodwork may show leukocytosis and elevated ESR, as well as occasional thrombocytopenia, hyponatremia, elevated liver enzymes, elevated CK, myoglobinuria, and steril pyuria
Ulceroglandular Tularemia
- Ulcer develops at site of inoculation with tender lymphadenopathy and systemic symptoms
Glandular Tularemia
- Ulcer is undetectable or healed, only lymphadenopathy and systemic illness remains
Oculoglandular Tularemia
- Entry through the conjuctiva
- Rare
Pharyngeal Tularemia
- Entry through the oropharynx, with exudative pharyngitis/tonsillitis
- May be difficult to distinguish from other forms of tularemia that also may have sore throat
Typhoidal Tularemia
- Febrile illness without lymphadenopathy or ulcer, sometimes with diarrhea
- May involve endocarditis
- Patient often has an underlying chronic disease
- Often rapidly-progressive and fatal
Pneumonic Tularemia
- Acquired by direct inhalation, often from sheep shearing, landscaping, and microbiology laboratory work
Complications and Prognosis
- Suppurative lymphadenopathy is the most common complication despite antibiotics, and may require drainage
- Severe disease may cause DIC, renal failure, rhabdomyolysis, jaundice, and hepatitis
- Without treatment, complications include meningitis, encephalitis, pericarditis, peritonitis, osteomyelitis, splenic rupture, and thrombophlebitis
- Rarely, Guillain-Barré syndrome following ulceroglandular tularemia
- Mortality is 60% without treatment, and decreases to 2 to 4% with antibiotics
Diagnosis
- Diagnosis is primarily clinical, and treatment should be given while attempting to confirm with diagnostic testing
- Culture
- Notify lab that tularemia is suspected before sending samples
- Gram stain is very rarely positive
- May be isolated from blood, pleural fluid, lymph nodes, wounds, sputum, and gastric aspirates
- Grows slowly on standard culture media, needs cystine-rich media (e.g. chocolate agar, BHI, or cystine media)
- Looks bacillary in logarithmic growth phase (small Gram-negative rod), slow-growing only on chocolate agar
- Serology is the most common test used to diagnose
- Can use tube agglutination (used in Ontario and the US), microagglutination, hemagglutination, enzyme-linked immunosorbent assay (used in Europe), or immunochromatographic assay
- IgM and IgG appear together, usually after 2 weeks and peak at 4 to 5 weeks
- Can persist for at least 10 years
- Presumptive positive with a single titre ≥1:160 (tube agglutination) or ≥1:128 (microagglutination), but this can also be compatible with remote infection
- Definitive diagnosis is made with a four-fold rise in acute and convalescent serology collected 2 to 3 weeks apart, with at least one test being above the threshold for presumptive positive
- May cross-react with Brucella, Proteus OX19, Legionella, and Yersinia
- DFA and PCR are available at reference labs
- Automated methods should not be used, due to the risk of aerosolization, and may also misindentify as Haemophilus or Aggregatibacter species
Management
- For severe disease, streptomycin 10 mg/kg (max 1 g) IM q12h for 7 to 10 days
- Alternatives include gentamicin or amikacin
- For mild to moderate disease, alternatives include:
- Doxycycline 100 mg po bid for 14 to 21 days
- Ciprofloxacin 500 mg po bid for 10 to 14 days
- For meningitis, use an aminoglycoside (as above) plus either IV ciprofloxacin, doxycycline, or chloramphenicol for 14 to 21 days
- Aminoglycosides have poor CNS penetration
Prevention
Vaccination
- Live attenuated vaccine derived from holarctica
Lab Safety
- This is a biosafety risk group 3 organism
- Should be suspected with any slowly-growing, small, and poorly-staining Gram-negative coccobacillus is isolated on chocolate agar but not blood agar
- Automated laboratory identification systems should not be used, because the risk of aerosol generation
- Commonly misidentified by automated methods as Haemophilus or Aggregatibacter species