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Focal Suppurative Infections of the Nervous System
Despite diverse causes of focal suppurative nervous system infections, a few mostly gram-positive bacterial species predominate, usually related to the infectious portal. Risk factors include cyanotic congenital heart disease (CCHD), hematogenous spread from distant infected sites, penetrating trauma/instrumentation, or contiguous site infection (sinus, middle ear, or mastoid). Oto-rhinosinusitis-related intracranial site frequencies include subdural empyema (49%), epidural abscess (36%), cerebral abscess (21%), and meningitis (10%). Invasive fungal etiology is rare and is associated with altered immune capabilities, broad-spectrum antibacterial exposure, and long-term indwelling foreign material.
Etiology
Bacteria cause >95% of brain abscesses in immunocompetent patients, including oral streptococci, Staphylococcus aureus , anaerobes, Enterobacteriaceae , and others. The Streptococcus milleri group ( S. constellatus, S. intermedius, and S. anginosus) comprise 50%–70% and staphylococci comprise 10%–30%. , Group A Streptococcus is rare. Streptococcus pneumoniae has declined as a cause of meningitis in the pneumococcal conjugate vaccine (PCV) era, but even in pre-PCV rarely caused brain abscess. , Up to 30% of suppurative CNS infections are polymicrobial by culture (up to 43% using molecular assays , ), often including nutritionally variant streptococci (e.g., Abiotrophia species ) or anaerobes (e.g., Bacteroides, Prevotella, and/or Peptostreptococcus spp.). Anaerobe detection classically require anaerobic culture methods, but new molecular methods improve detection rates.
Gram-negative organisms comprise 10%–25% of brain abscesses or subdural empyemas ( Table 46.1 ), most often otogenic in origin or occurring in young infants. , Citrobacter, , Salmonella , Serratia, Proteus , and Cronobacter species (previously Enterobacter sakazakii ) or Bacteroides fragilis are most frequent. C. sakazakii (associated with powdered formula) and Citrobacter koseri cause multifocal brain abscesses.
TABLE 46.1
Likelihood (% of Cases) of Bacterial Pathogen in Focal Suppurative Nervous System Infections
| Epidural abscess | ||||
|---|---|---|---|---|
| Bacteria | Brain Abscess | Subdural Empyema | Cranial | Spinal |
| Mixed | 20–40 | 5–10 | 5–10 | 5–10 |
| Alpha streptococci, not pneumococcus a | 50–70 | 20–30 | 40–60 | 5–10 |
| Anaerobic bacteria b | 20–30 b | 5–10 b | 10–20 | 5–10 |
| Staphylococci | 10–30 | 10–20 | 10–20 | 60–80 |
| Enterobacteriaceae | 10–25 | 5–10 | 5–15 | 5–20 |
| Pathogens of meningitis c | 5–10 | 30–50 | 5–10 | <1 |
| Sterile d | 10–25 | 20–30 | 20–30 | 5–10 |
a Aerobic, anaerobic, or microaerophilic (e.g., Streptococcus anginosus group).
b Mostly anaerobic streptococci.
c Streptococcus pneumoniae , Haemophilus influenzae type b, or Neisseria meningitidis . Much less common in countries with routine use of pediatric conjugate vaccines.
Chronic otitis media, uncontrolled diabetes mellitus, and iatrogenic neutropenia are risk factors for Pseudomonas aeruginosa or Proteus mirabilis . Impaired cell-mediated function, e.g., macrophage- or T-lymphocyte-related defects, or neutrophil phagocytic defects predispose to Listeria monocytogenes or Nocardia spp. ,
Risk states for fungal brain abscesses include premature infants, congenital or acquired neutrophil defects, high-risk leukemias, transplantation (hematopoietic cell transplant [HCT] or solid organ transplant [SOT]), , or poorly controlled acquired immunodeficiency syndrome (AIDS). Over 90% of brain abscesses after HCT are fungal, usually Candida or Aspergillus spp. In premature infants, Candida spp. increasingly cause multiple small brain abscesses.
Prevalence of fungi in brain abscesses parallels other invasive fungal disease. Overall, Candida spp. are most common (42%), followed by Aspergillus (29%), other molds (14%), and Cryptococcus (4% and mostly in adults). Endemic fungi ( Histoplasma, Blastomyces, Coccidioides , 3%) occur predominantly in defined endemic geographic areas. Scedosporium spp. is seen increasingly, particularly in HCT recipients. Cryptococcus usually causes meningitis but can cause brain abscess. Other fungi rarely causing brain abscess are listed in Table 46.2 .
TABLE 46.2
Uncommon Pathogens in Brain Abscesses or Focal Ring Enhancing Lesions
| Bacteria | |||
|---|---|---|---|
| Aerobic | Anaerobic | Fungi | Protozoa/Parasites |
| Aggregatibacter aphrophilus | Propionibacterium | Mucormycosis | Taenia solium |
| Streptococcus pneumoniae | Fusobacterium | Pseudallescheria boydii | Toxoplasma |
| Eikenella | Peptostreptococcus | Scedosporium | Entamoeba |
| Enterococcus | Bacteroides | Bipolaris; Curvularia | Schistosoma |
| Moraxella | Clostridium | Histoplasma | Trichinella |
| Pasteurella | Actinomyces | Blastomyces | Strongyloides |
| Bacillus cereus | Coccidioides | Paragonimus | |
| Nocardia | Xylophyla (Cladosporium) | Acanthamoeba | |
| Streptococcus pyogenes a | Verruconis (Ochronis) gallopava | ||
| Listeria | Fonsecaea | ||
| Brucella b | Exophila Ramichloridium |
||
a Streptococcus pyogenes usually concurrent with acute mastoiditis.
b Brucella melitensis occurs mostly in the Middle East and Mediterranean areas.
Protozoa causing brain abscess include Acanthamoeba, Schistosoma, or Paragonimus spp. With poorly controlled HIV in children, Toxoplasma gondii can rarely cause brain abscess. Entamoeba histolytica brain abscess is rare even with amebiasis. Helminthic migration ( Strongyloides stercoralis, Trichinella, or Taenia ) can cause brain abscesses or masses. Neurocysticercosis in patients from endemic areas (e.g., Mexico, Africa) causes single/multiple, often ring-enhancing, central nervous system (CNS) lesions often misconstrued as bacterial brain abscesses.
Table 46.2 lists other uncommon pathogens. Rarely, Mycoplasma or Ureaplasma spp. are causal. Mycobacterium tuberculosis brain abscess is purulent with acid-fast bacilli, differing from tuberculoma, which is a granulomatous mass with epithelioid and giant cells. Magnetic resonance imaging (MRI) differentiates these two conditions.
Location or distribution of lesion(s) suggests the pathogen. Frontal lobe (usually with concomitant sinusitis) suggests oral flora, i.e., Streptococcus spp. (aerobic, microaerophilic, anaerobic), staphylococci, and/or anaerobic bacteria ( Table 46.3 ). With penetrating trauma, S. aureus (often methicillin-resistant S. aureus, MRSA) increases but Streptococcus spp. remain more common. Temporal lobe or cerebellum suggests middle/external-ear pathogens and/or oral flora, or less often Enterobacteriaceae or Pseudomonas spp.
TABLE 46.3
Relative Importance of Organisms by Site of Focal Lesion
| Site | Most Common Pathogens |
|---|---|
| Solitary Lesion | |
| Frontal lobe with sinusitis or oral/dental infection | Oral and/or nasopharyngeal aerobic and/or anaerobic flora, e.g., streptococci, Staphylococcus aureus |
| Temporal lobe area, posterior fossa or cerebellum contiguous with middle ear/mastoid infection | Streptococci (aerobic and anaerobic), anaerobic oral flora, Enterobacteriaceae |
| Post trauma | S. aureus, non-pneumococcal alpha streptococci, Propionibacterium, Enterobacteriaceae |
| Multiple Lesions | |
| Underlying congenital heart disease | Non-pneumococcal alpha streptococci (aerobic and/or anaerobic), Haemophilus spp. |
| With endocarditis | Non-pneumococcal alpha streptococci, S. aureus |
| With lung infection | Oral flora including anaerobes, Nocardia spp. |
| No known risk | S. aureus |
| Immunocompromised host | Toxoplasma, fungi, Nocardia, Enterobacteriaceae |
Hematogenous spread due to endocarditis, septic thrombophlebitis, lung abscess, pleural empyema, bronchiectasis (in cystic fibrosis), osteomyelitis, or skin infections classically produces multiple lesions in the distribution of the middle cerebral artery, but any pattern can be seen.
Hematogenous pathogens usually are S. aureus, aerobic or anaerobic streptococci, but rarely include Candida, Nocardia, Aspergillus, or Actinomyces spp. S. aureus is more frequent with prosthetic valve endocarditis or prolonged bacteremia (de novo or intravascular catheter associated). Aggregatibacter (formerly Haemophilus ) aphrophilus (a HACEK organism) is relatively common in patients with CCHD.
Pathogens of subdural empyema correlate with pathogenesis. In young children, subdural empyema usually accompanies bacterial meningitis (infrequent in countries with universal use of conjugate vaccines for Haemophilus influenzae type b [Hib], pneumococcus, and meningococcus) ( Table 46.2 ). ,
Subdural empyemas not accompanying bacterial meningitis have the same pathogens as brain abscesses. Aerobic and anaerobic streptococci (e.g., S. intermedius and S. anginosus group) predominate when associated with sinusitis. S. aureus is more common postoperatively or post trauma but can occur after sinus/ear infection. Cultures are sterile in 20%–30%, likely due to: antibacterial pretreatment; nonviability of fastidious or anaerobic bacteria; or nonoptimal collection, transportation, or isolation procedures. Recent use of molecular diagnostics has allowed pathogen detection in culture negative samples.
Rare subdural pathogens include nontyphoidal Salmonella , S. pyogenes , Burkholderia , Brucella melitensis , Propionibacterium, Prevotella, fungi (e.g., Candida albicans, Pseudallescheria boydii ), or M. tuberculosis . Gram-negatives are increasingly detected in both subdural empyema and epidural abscess.
S. aureus is the most common cause of epidural abscess (cranial or spinal). , However, S. pneumoniae or S. agalactiae also cause cranial epidural abscesses. Cranial epidural abscesses occur in immunocompromised hosts due to Pseudallescheria, Aspergillus, , Candida spp., Zygomycetes, or M. tuberculosis . Spinal epidural abscess rarely is due to B. melitensis (Middle Eastern and Mediterranean area), Nocardia asteroides group, Actinomyces israelii, Cryptococcus neoformans, or Aspergillus. Epidural and other paravertebral abscess can complicate Bartonella henselae vertebral osteomyelitis. ,
Intracranial septic thrombophlebitis is mostly associated with sinus, mastoid, or facial infections ( S. pneumoniae, , S. pyogenes, or S. aureus) . Other otopathogens or non-group A streptococci are also reported. Anaerobes (e.g., Fusobacterium species ), while rare (most often associated with Lemierre disease), have been more frequent since 2005 and can have severe complications. Polymicrobial infections can occur. ,
Epidemiology
Brain abscess is uncommon in developed countries (1 per 8.8 million population). Risks vary geographically, e.g., associated with chronic otitis media in China (60%) but less in Europe (30%). Peak age is 4–7 years among the 25% of brain abscesses occurring before 15 years of age. Neonatal brain abscesses are most frequently associated with gram-negative bacterial meningitis. In immunocompetent hosts, most brain abscesses are solitary, but are multiloculated in 10%–20%. Multiple abscesses most frequently follow hematogenous spread or occur in neonates or immune compromised patients.
Intracranial subdural empyema occurs predominantly in males (3:1) of teen years, but is sex neutral in young children, originating from paranasal sinus or middle ear/mastoid infection in about 85%, and hematogenously in 5%–10%. Intracranial subdural empyema after neurosurgical procedures (e.g., craniotomy) is infrequent (0.04%).
Spinal subdural abscess is rare in children; obesity is a possible risk factor. Spinal epidural abscess also is rare (<200 reported pediatric cases; , 6/100,000 hospital admissions). ,
Intracranial epidural abscess is the most common CNS suppurative complication of oto-mastoid infection. Posterior fossa epidural abscesses originate from middle ear/mastoid infections after osseous erosion of the petrous pyramid or over the sigmoid sinus plate, from orbital abscesses or frontal sinusitis via valveless emissary veins, or concurrent with subdural empyema or cavernous sinus thrombosis. After neurosurgical procedures, epidural abscess is 10–40 times more frequent than subdural empyema but is uncommon (0.43%–1.8%).
Suppurative intracranial thrombophlebitis usually accompanies another intracranial infection, which usually is extradural, e.g., mastoiditis or paranasal sinusitis. However, 10%–20% originate from facial (typically the middle third) or dental infections. Otogenic-infection related cerebral venous thrombosis also has been reported.
Pathogenesis
Brain Abscess
Traditionally brain abscesses were mostly hematogenous due to CCHD ( Box 46.1 ); 6% of patients with unrepaired CCHD develop brain abscess. Brain infarction or emboli lead to infection, with the risk increasing over time. Right-to-left shunting allows transiently circulating pathogens to bypass the lung’s reticuloendothelial filter. Uncorrected tetralogy of Fallot and transposition of the great vessels were the most common CCHD predisposing to brain abscesses, but now represent fewer cases (about 28% overall) due to routine early surgical repair.
BOX 46.1
Risk Factors for Brain Abscess
Within hematogenous and contiguous spread, conditions are in order by relative frequency.
Hematogenous (Approximately 30%)
-
Uncorrected cyanotic congenital heart disease
-
Septic thrombophlebitis
-
Lung infections, bronchiectasis
-
Cystic fibrosis
-
Esophageal/rectal dilatation or endoscopy a
a It is unclear whether some infections result from direct spread from mucosal site via local drainage through the Batson plexus.
,
-
Hereditary hemorrhagic telangiectasia
-
Pulmonary arteriovenous malformation
-
Hepatopulmonary syndrome
-
Septic abortion
Contiguous Spread (Approximately 40%)
-
Middle ear and/or mastoid infection
-
Sinusitis
-
Meningitis
-
Other focal infections (e.g., teeth, orbit, bone)
-
Penetrating head trauma
-
Ventriculoperitoneal shunt infection
-
Postoperative intracranial surgery
-
Halo device to immobilize cervical spine
Unknown Source (Approximately 30%)
Within hematogenous and contiguous spread, conditions are in order by relative frequency.
Endocarditis (especially acute left-sided) predisposes to brain abscess due to septic embolization. Increased magnitude/duration of bacteremia increases risk of CNS infection. Septic emboli from deep neck phlebitis accompanying parapharyngeal infection (Lemierre disease) can lead to brain abscesses, which often is polymicrobial, due to oral flora and/or anaerobic flora, e.g., Fusobacterium spp. Metastatic brain abscesses also can occur from distant pyogenic infections, e.g., bone, teeth, skin, abdomen, chronic lung abscess, empyema and bronchiectasis.
Chronic pyogenic lung disease due to immunoglobulin deficiencies, or bronchiectasis from longstanding cystic fibrosis, increases risk of brain abscess. Rarely, brain abscess occurs due to pulmonary arteriovenous malformations, aspirated foreign body, or hepatopulmonary syndrome. Endoscopy-associated brain abscess is rare but can follow translocation of intestinal bacterial to paravertebral veins and then to the cavernous sinus. Septic abortion and in situ intrauterine devices are associated with brain abscess.
Extension from nearby infection (middle ear, cholesteatoma, mastoid, sinus, orbit, face, or scalp) is now the most common cause of brain abscess (about 36%) . Otogenic sources dominate in young children, but in male adolescents paranasal sinus sources dominate. In teenagers, frontal, ethmoid, and sphenoid sinuses have thin bony/cartilaginous walls abutting the dura mater, allowing CNS ingress from infectious/inflammatory erosion (osteitis). Other portals of entry include pre-existing or posttraumatic anatomic cranial defects or diploic/emissary veins.
Bacterial meningitis rarely causes brain abscess except in neonates. Thrombophlebitis, venous stasis, and/or ischemia likely contribute to the pathogenesis. Focal deep cerebritis, deep infarcts, and virulence factors of the pathogen, e.g., S. aureus or Cronobacter , are important. Rarely, pyogenic infection spreads between the lateral ventricles.
Postoperative or post-traumatic brain abscess is uncommon (about 9%). However, risk increases with bone flap reimplantation, penetrating skull injury (e.g., dog bite, pencil puncture, lawn dart, ), or open fracture. Oral flora can penetrate via intraoral punctures (such as chopsticks). Gut-associated ascending infection along a ventriculoperitoneal (VP) shunt or an untreated central shunt infection are sources. Other rare causes are orthopedic halo devices or intracranial migration of foreign bodies (e.g., cervical spinal sublaminar or interspinous wires). Pre-existing intracerebral hematoma, necrosis, or neoplasm rarely can serve as a nidus for an abscess.
Subdural Empyema
In young children, subdural empyema classically followed bacterial meningitis but now is rare in the conjugate vaccine era. In older children, extracranial infection (e.g., middle ear, sinus, or calvarium) is the usual source. Risk increases with post-mastoidectomy bone defects, prior craniotomy, skull trauma, septic phlebitis of emissary veins, VP shunt, , pre-existing hematoma, halo-pin traction, bacteremic lung abscess, or endoscopic procedures.
Epidural Abscess
Intracranial epidural abscesses usually extend from infected sinuses, middle ear, or orbit, and rarely from penetrating head injuries, fetal monitoring, or wrestling injury. Tightly adhering dura usually impedes expansion of epidural abscesses leading to insidious clinical presentations. Epidural abscesses do extend (e.g., to the subdural space, brain) causing multifocal intracranial infections. S. aureus is most frequent, sometimes from deep leg or pelvic septic venous thrombosis.
Although nearly one-third of spinal epidural abscesses have no identified source, they usually are hematogenous (e.g., from infected skin, soft tissue, bone, respiratory or urinary tract). Less common sources are: nearby infections (bacterial meningitis, osteomyelitis, or abscess in retropharynx, retroperitoneum or abdomen); iatrogenic introductions (post spinal fracture, penetrating injury, spinal surgery, spinal fusion, spinal rod placement, lumbar puncture, corticosteroid injection, or epidural analgesia ); fistulas (Crohn disease), midline neuroectodermal defects, dermal sinuses; or intradural tumors (e.g., lipoma).
Intracranial Septic Venous Thrombosis
Intracranial septic thrombosis can follow bacterial meningitis (e.g., superior sagittal sinus), or arise from contiguous infection (sinuses, ear, face, or oropharynx) via emissary veins. Lateral venous sinus involvement usually is otogenic; cavernous sinus thromboses originate from teeth, paranasal/sphenoid sinuses, or the face. , Septic venous sinus thrombosis can occur contiguous with an epidural abscess or by hematogenous spread.
Clinical Manifestations
Brain Abscess
The mean duration of bacterial brain abscess symptoms before diagnosis is 2 weeks but ranges up to 4 months. Abscess location affects clinical presentation ( Box 46.2 ). Frontal lobe inflammation (most common with sino-facial abscess in an adolescent) may not produce symptoms until mass effect increases intracranial pressure (ICP). Parietal lobe abscesses can remain silent until extending to the sensorimotor cerebral cortex. Pathogen virulence and host immune status also affect clinical acuity.
BOX 46.2
Signs and Symptoms in Relation to Site of Brain Abscess
Any Site
-
Signs of increased intracranial pressure (often late signs)
-
Headache, nausea, emesis, papilledema
-
Depressed consciousness
-
Behavioral changes
-
Confusion, decreased attentiveness
Frontal Lobe
-
Behavioral changes
-
Personality changes, emotional lability, impulsive behavior
-
Motor abnormalities
-
Motor speech disorder (apraxia), forced grasping and sucking
-
Focal weakness, hemiparesis
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