1. Complicated Pneumonias:�Why So Complicated? Eric D. Zee
Bay Area Pediatric Pulmonary
California Pacific Medical Center
Children’s Hospital & Research Center Oakland
12 November 2010
2. Complicated versus uncomplicated pneumonias
Controversies
Imaging
Approaches and management
Role of Vaccines
Necrotizing pneumonias and post infectious pneumatoceles
Case study Overview
3. Infective pleural effusions
Lung abscess
Necrotizing pneumonia
4. Excess liquid caused by disequilibrium of filtration (formation) and absorption (removal)
Increased filtration with normal or impaired absorption
Normal filtration with impaired absorption
Addition of exogenous fluid (intravenous fluid or peritoneal fluid)
Pleural Fluid
5. Infection and inflammation damages vascular endothelium and promotes capillary leak
Inflammation also promotes increased local blood flow
Net liquid and protein transudation Pleural Fluid
6. Fluid in the pleural space secondary to pneumonia
Parapneumonic effusion
Exudative: high LDH, high protein, low glucose, low pH
Empyema Pleural Fluid
7. Staphylococcus aureus in infants less than 2 years
Streptococcus pneumoniae most common community acquired
Haemophilus influenzae less since vaccine
Pseudomonas aeruginosa less commom
Anaerobes (Fusobacterium and Bacteroides) rare Organisms
8. S pneumo consistent through the years
Since 2000, increased incidence of MSSA, MRSA, Fusobacterium, Pseudomonas and S milleri Organisms
9. Three phases:
Exudative stage: low wbc counts
Fibrinopurulent stage: more wbc, fibrin, start of loculations
Organizational stage : fibrous pleural peel
Infective pleural effusion
10. Differing definitions:
Uncomplicated:
No pleural fluid or necrotic lung versus
Exudative stage
Complicated:
Presence of pleural fluid versus
Fibrinopurluent and organizational stages
Complicated Versus Uncomplicated Pneumonias
11. Imaging modalities?
No consensus on appropriate treatment
Surgery way
Pediatric way
No “trapped lung syndrome” in children unlike adults
No restrictive or obstructive lung sequelae Controversy Abounds
12. Plain films (roentgenogram)
Upright and decubitus films
Easy, readily available, infiltrate and fluid easy to see
Intrapleural pathology and parenchymal disease drawbacks
Ultrasound
Estimate size of effusion
Loculations and pleural thickening easy to see
Imaging
13. Computed tomography
Able to estimate size pleural fluid
Detailed information on anatomy and location of disease (parenchymal versus pleural)
MRI
Detect loculations
Differentiates between inflammatory and non inflammatory changes
Logistical and availability disadvantages in pediatrics
Imaging
14. CT radiation risk is real
Ultrasound superior in resolution pleural fluid and loculations
CT chest is useful in determining parenchymal disease, necrosis, pneumatocele, abscess
CT no additional clinical information not already seen on ultrasound
Ultrasound versus CT
15. More emphasis on staging effusions
Purulence and fibrin may inhibit simple drainage, small caliber chest tubes
Avoid complications and salvage procedures
Meta-analysis: operative versus non-operative therapy
Non-operative: antibiotics and simple chest tube
Operative: VATS, thoracotomy, fibrinolysis
The Surgery Way
16. Non-operative therapy: 20 days
Fibrinolysis: 10 days
VATS: 10 days
Failure rate non-operative therapy: 23.6%
Length of Stay
17. Although primary operative therapy decreases LOS and failure rate, >76% resolve without surgery.
Step-wise approach possible but many favor initial surgery to decrease LOS and morbidity.
VATS cost-effective in centers where chest tubes placed in OR.
The Surgery Way
18. Better than thoracotomy
Not superior than fibrinolysis
Consider if clinical symptoms for compressive effects
VATS
19. Seattle Children’s Hospital: conservative management
Half treated with antibiotics alone
Retrospective study:
Small effusions: <10mm or <¼ thorax
Large effusions:>10mm or >1/4 thorax
Larger effusions required pleural drainage
The Pediatric Way Seattle children’s recommended conservative management; they found retrospectively half of cases required antibiotics alone, although these were associated with small effusions.Seattle children’s recommended conservative management; they found retrospectively half of cases required antibiotics alone, although these were associated with small effusions.
20. Pleural interventions
Chest tube
Chest tube with fibrinolytics
VATS
No consensus VATS versus fibrinolytics is more efficacious
Pleural intervention if clinically ill or CXR shows mediastinal shift The Pediatric Way
21. 28% children with initial simple chest tube required VATS
Seattle advocates initial VATS intervention
Seattle less experience with fibrinolytics
Antibiotics: IV Ceftriaxone and Clindamycin
Vancomycin IV if child critically ill
Less emphasis on staging effusions
The Pediatric Way
22. Mortality and long-term morbidity very low
Pleural intervention directed at decreasing short-term morbidity and LOS
Surgery papers advocate early intervention
LOS with antibiotics alone comparable at 7 days
Chest tubes alone may increase LOS
Those with chest tubes may take longer time to eventual VATS Length of Stay
23. Children usually do well with antibiotics alone
Unusual to require intervention
Drainage possible via airways
Invasive intervention (needle aspiration, bronchoscopy, wedge resection or lobectomy)
Clinical deterioration
Mediastinal shift
Airway compression
Lung Abscesses
24. Increasing incidence since 2000
Increasing detection?
Computed tomography readily available
Antibiotics able to sterilize pleural fluid
Resulting inflammatory reaction
Some advocate surgical resection but controversy remains Necrotizing Pneumonia
25. Query increase in S pneumo complicated pneumonias with PCV 7
Studies from Salt Lake City, Alberta and US National database: increased incidence empyema
Query serotype replacement: non-vaccine serotypes 5 and 19A more prevalent
Query increased MRSA Role of Vaccines
