ID
Spinal Infection
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Spinal Infection
, Spinal Cord Infection, Discitis, Diskitis
See Also
Spinal Epidural Abscess
Vertebral Osteomyelitis
Acute Spinal Cord Compression
(includes
Spinal Cord Syndrome
)
Osteomyelitis
Epidemiology
Incidence
: 0.2 to 2.8 cases per 10,000 per year
Most common in ages 31 to 70 years old (peak
Incidence
ages 60-70 years old)
Also occurs in children <5 years old
Gender predominance: Males by a ratio >2:1
Precautions
Spinal Epidural Abscess
is frequently misdiagnosed on initial presentation
Triad of back pain, fever and neurologic deficit is present in <15% of cases
Fever
is present in <50% of cases
Be alert for red flag presentations (esp. with back pain)
Unexplained fever (present in 86% of cases)
Focal neurologic deficits with progressive or disabling symptoms (present in 82% of cases)
References
Bhise (2017) Am J Med 130(8): 975-81 +PMID: 28366427
Types
Spinal Infection
Spinal Epidural Abscess
(SEA) - typically the primary infection site
Infection in the space between the
Dura Mater
and the adjacent
Vertebral Column
Of the Spinal Infections, SEA is the most acute of presentations with fever, neurologic deficits and spinal pain
Disc space infection (Discitis)
Vertebra
l infection
Spondylitis
Osteomyelitis
Pathophysiology
Spinal Cord Injury
Mechanisms
Direct compression from
Epidural Abscess
Venous thrombosis or
Thrombophlebitis
of nearby veins
Arterial perfusion disrupted
Bacterial Toxin
induced injury
Inflammatory mediator related injury
Pathophysiology
Sources of Spinal Infection
Hematogenous spread (50%)
Contiguous spread (33%)
Retropharyngeal Abscess
Psoas Abscess
Direct introduction of infection
Spinal injection
Spinal surgery
Pathophysiology
Sites of Spinal Infection
Most cases involve thoracolumbar spine
Anterior
Epidural Abscess
(20%)
Associated infections
Disk space infection (Discitis)
Vertebral Osteomyelitis
Blunt
Trauma
and associated
Hematoma
infection
Direct extension from adjacent infection
Retropharyngeal Abscess
Retroperitoneal abscess
Posterior
Epidural Abscess
(80%)
Distant source (
Cellulitis
, dental,
Pharyngitis
)
Causes
Acute Infection (within 5-10 days)
Staphylococcus aureus
(most common)
Actinomycosis
(rare)
Chronic Infection (within 3-6 months)
Other indolent infections
Fungus
Tuberculosis
(
Pott's Disease
)
Vertebra
l collapse
Sharply angulated spinal deformity
Risk Factors
Idiopathic without risk factors in 20% of cases
Intravenous Drug Abuse
Back pain in
IVDA
is a Spinal Infection until proven otherwise
Immunodeficiency
HIV Infection
or
AIDS
Chronic Renal Failure
(esp.
Dialysis
)
Advanced
Liver
Disease
Diabetes Mellitus
Alcoholism
Malignancy
Immunosuppressant
s (e.g.
Chemotherapy
,
Corticosteroid
s)
Advanced Age
Recent spinal procedure
Spinal surgery
Epidural Anesthesia
Recent back
Trauma
Concurrent infectious sources
Genitourinary infection
Skin Infection
Poor
Dentition
(Associated with Actinomyces)
Symptoms
Back pain (70-90% of cases)
Associated with secondary
Muscle
spasm
Severe localized back pain not relieved with rest
Pain provoked by standing and bearing weight
Children may limp or refuse to crawl or walk
Systemic symptoms
Fever
(30-60% of cases)
Rigors
Malaise
Neurologic compromise (33% to 70% of cases, indicates spinal compression)
Findings are often subtle, especially early in course
Bowel
or
Bladder
dysfunction
Extremity weakness
Signs
Focal tenderness at involved spinous process (60-70% of cases)
Precautions
Keep a high index of suspicion
Classic triad of back pain, fever and neurologic symptoms occurs in <37% of patients
Avoid
Lumbar Puncture
Not diagnostic
Risk of contiguous seeding of subarachnoid space (and secondary
Meningitis
)
Disposition to rapid intervention at time of diagnosis
Delays result in greater risk for neurologic injury
Abscess results in direct mechanical compression of the spinal cord
Local infection may result in ischemic injury to the cord via thrombosis of vessel
Occlusion
Labs
Complete Blood Count
Leukocytosis
(30 to 66% of cases)
Acute phase reactants (increased in 95% of cases)
Erythrocyte Sedimentation Rate
(ESR) increased
C-Reactive Protein
(
C-RP
) increased
Blood Culture
s
Identify responsible organism in 60% of cases
Imaging
Precautions
Image the entire spine (cervical, thoracic and lumbar)
Skip lesions are common in Spinal Infections
Gadolinium-enhanced Spine MRI (preferred)
Test Sensitivity
>90%
Enhancing Lesion seen in T2-Weighted Images
Differentiates Diskitis from
Vertebral Osteomyelitis
Skip lesions are present in 15% of cases and have several associated risk factors
Older age
Very high
Erythrocyte Sedimentation Rate
(ESR)
Concurrent area of infection outside the spine
Longer symptom duration
CT with Myelography
Indicated when MRI is contraindicated or unavailable
Underestimates
Spinal Epidural Abscess
size
Evaluation
Have a high index of suspicion (see precautions above)
Low risk patients (significant risk factors, reassuring history and exam)
No imaging needed
Moderate risk patients (risk factors present, but no motor deficits)
Obtain CRP and ESR and if elevated obtain MRI
High risk patients (motor deficits identified)
Obtain MRI
Differential Diagnosis
See
Cauda Equina Syndrome
Flu-like Symptoms with Spine Pain and Acute Neurologic Symptoms (e.g. cord syndrome,
Peripheral Neuropathy
)
Spinal Epidural Abscess
or Discitis
Menigitis or
Encephalitis
Transverse Myelitis
Endocarditis
Myocarditis
Toxic Shock Syndrome
Psoas Abscess
Carbon Monoxide Poisoning
Swaminathan, Shoenberger and Long in Swadron (2023) EM:Rap 23(3): 19-21
Management
Emergent Neurosurgery or
Spine Surgery
Consultation
Surgical decompression of
Epidural Abscess
(first-line, preferred management)
Indications
Developing or worsening neurologic deficits
However, pre-surgical paralysis may not benefit from surgery
Cervical or
Thoracic Spine
involvement
Higher risk for neurologic complications than
Lumbar Spine
(except
Cauda Equina Syndrome
)
Phlegmon
Open decompression (preferred)
May be performed with endoscopy-assisted surgery
Percutaneous drainage (aspiration under CT guidance)
Consider in posterior
Spinal Epidural Abscess
AND
Lack of neurologic deficit OR high surgical risk patient
References
Epstein (2015) Surg Neurol Int 6(suppl 19): S476-86 [PubMed]
Empiric
Antibiotic
s
Start early empiric therapy and modify based on culture results
Discuss with neurosurgery (may ask to withhold
Antibiotic
s until surgical culture obtained)
Typical IV
Antibiotic
duration: 6 weeks
Drug 1:
MRSA
Coverage (
Staphylococcus aureus
is most common cause, used with drug 2 below)
Vancomycin
15-20 mg/kg IV every 8-12 hours (dosing must be calculated based on weight, levels)
Alternatives:
Linezolid
,
Daptomycin
Drug 2:
Gram Negative
, esp.
IVDA
,
Immunosuppression
, UTI (used in combination with
MRSA
Drug 1 coverage)
Gram Negative
Coverage without
Pseudomonas
coverage
Ceftriaxone
2 g IV every 24 hours
Cefepime
2 g IV every 8 hours
Levofloxacin
750 mg IV every 24 hours
Gram Negative
With
Pseudomonas
coverage as indicated (e.g.
IV Drug Abuse
, recent hospitalization)
Ceftazidime
1-2 g IV every 8-12 hours
Ciprofloxacin
400 mg IV every 12 hours
Piperacillin
-Tazobactam 4.5 g IV every 6 to 8 hours
Meropenem
1 g IV every 8 hours
Drug 3:
Anaerobe
Coverage
Metronidazole
500 mg IV every 6 hours
Candida Coverage Indications
Immunocompromised
State
Recent
Spine Surgery
Other modified
Antibiotic
coverage
Mycobacterium tuberculosis
suspected
Prognosis
Positive prognostic indicators
Intact or only mild neurologic symptoms prior to intervention
Most accurate prognostic indicator
Neurologic symptoms progress with delayed diagnosis
Residual deficits persist after surgery in 50% of cases (paralysis is often irreversible)
Age under 60 years
Cord symptoms (e.g.
Bladder
dysfunction) <24 hours
No comorbid conditions
Thecal sac compression <50%
Complications
Cauda Equina Syndrome
Results from direct mechanical compression of cord
Meningitis
(or overwhelming
Sepsis
)
Results from spread into subarachnoid space
Mortality
Mortality rate: 5%
References
Dasburg (2020) Crit Dec Emerg Med 34(6): 28-9
Della-Giustina (2014) Crit Dec Emerg Med 28(3): 2-9
Long and Carlson in Swadron (2022) EM:Rap 22(7): 7-9
Bond (2016) Biomed Res Int 2016:1614328 +PMID: 28044125 [PubMed]
Chao (2002) Am Fam Physician 65(7):1341-6 [PubMed]
Tompkins (2010) J Emerg Med 39(3): 384-90 [PubMed]
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