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Pulmonary Edema Pathophysiological Considerations Manifestations on Chest Radiography

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Title: Pulmonary Edema Pathophysiological Considerations Manifestations on Chest Radiography


1
Pulmonary EdemaPathophysiological
Considerations Manifestations on Chest
Radiography
  • Kathryn Glassberg MS4
  • February 2006

2
Pulmonary Edema Overview
  • Pathophysiology Edema as an end result of a
    multitude of diverse insults (not just heart
    failure vs. ARDS!)
  • Physiologic approach for radiologic evaluation of
    edema
  • Hydrostatic edema
  • Permeability edema /- diffuse alveolar damage
  • Mixed permeability and hydrostatic edema

3
Pulmonary Edema
  • Edema occurs when physiologic resorption of fluid
    via lymphatics is overwhelmed
  • Causes usually divided into hydrostatic and
    increased capillary permeability, but both
    mechanisms can occur in the same patient!
  • Chest radiography, when combined with clinical
    data, helps distinguish pathologic cause in vast
    majority of cases

4
Causes of Pulmonary Edema1
5
Causes of Pulmonary Edema1
6
Pathophysiology overview2
  • Normally, excess hydrostatic transudate from
    pulmonary capillaries is filtered into
    peribronchovascular lymphatics and removed

7
Pathophysiology overview2
  • In hydrostatic edema, transudate accumulates in
    the interstitum initially, only entering alveoli
    in severe cases
  • In permeability edema associated with diffuse
    alveolar damage (DAD), exudate fills the
    interstitum and the alveoli

8
Hydrostatic Edema3
  • The lungs can accommodate increases in fluid the
    lymphatic flow can increase 3-10x before edema
    develops
  • Higher hydrostatic pressures force fluid through
    endothelial cell pores, but the tighter junctions
    of epithelial cells prevent fluid from entering
    alveoli until pulmonary capillary pressures reach
    40 mm Hg, causing stress failure

9
Hydrostatic Edema radiologic manifestations3
  • Earliest sign vascular indistinctness
  • Bronchial wall thickening/peribronchial cuffing
  • Septal lines Kerley A, B, C
  • Thickened fissures
  • Severe edema dependent ground glass opacities
    reflecting alveolar involvement
  • Often associated with bilateral transudative
    pleural effusions

10
Hydrostatic Edema radiologic manifestations3
  • Cephalization or inversion not specific for
    edema
  • Reflects chronic pulmonary venous changes in
    patients with left-sided heart failure
  • Vascular pedicle width
  • patients with volume overload often have widened
    vascular pedicles when compared to previous
    studies
  • However, patients can certainly have hydrostatic
    edema despite a narrow pedicle, thus this sign
    can be misleading

11
Vascular indistinctness
Normal
Edema
Images courtesy of Dr. Marc Gosselin
12
Vascular Indistinctness
Normal
Edema
Images courtesy of Dr. Marc Gosselin
13
Peribronchial cuffing
  • Images shown are pre- and post-treatment for
    hydrostatic edema
  • Arrowheads point to Kerley A lines

14
Septal Lines3
  • The presence of septal lines reflects fluid
    accumulation between the lung lobules
  • Kerley lines
  • A long, diagonal, central
  • B short, horizontal, extend to lateral pleural
    surfaces
  • C reticular pattern of 1 cm polygons
    representing septal lines viewed on end (Ive
    heard Dr. Kerley is the only one who has ever
    really seen these)

15
Septal Lines
  • Septal lines in a patient with cardiac failure

16
Septal Lines
  • Lateral view of same patient note fluid in
    both fissures

17
Septal Lines
  • All three Kerleys claim to be present can you
    find them?

18
Septal Lines
  • Even in you cant name the lines, you can see
    that this patient has severe hydrostatic edema in
    need of treatment!

A
B
C?
19
Evolving hydrostatic edema4
  • 33 year-old with AML admitted for renal
    failure and fluid overload

20
Evolving hydrostatic edema4
  • Arrows indicate peri-bronchial cuffing
  • Note increasing size of azygous vein

21
Evolving hydrostatic edema4
  • Arrowheads indicate septal lines
  • Note ground-glass, indicating alveolar edema

22
Permeability Edema
  • multiple insults can cause increased pulmonary
    vessel permeability resulting in leakage of fluid
    AND protein
  • In its most severe form, the disease is a
    combination of vessel permeability and DAD,
    leading to the acute respiratory distress
    syndrome (ARDS)

23
ARDS pathology3
  • Acutely, exudative edema in the alveoli causes
    hyaline membrane formation
  • Type II epithelial cells then proliferate and,
    usually, fibrosis occurs

24
ARDS Radiologic manifestations3
  • Patchy, diffuse ground glass opacities
  • Pattern of opacification does not change with
    position change, as the exudates are trapped in
    alveoli
  • Septal lines, peribronchial cuffing, and thick
    fissures are usually ABSENT
  • In severe cases, air bronchograms can be seen
  • Good rule of thumb presence of ET tube!

25
ARDS Radiologic manifestations3
  • Caution While a normal sized heart and narrow
    vascular pedicle are helpful signs, neither is
    specific for injury edema

26
ARDS
  • Patchy diffuse ground glass
  • Air bronchograms
  • ET tube

27
Permeability Edema without DAD3
  • Seen in IL-2 therapy for metastatic disease,
    hantavirus pulmonary syndrome
  • Severe capillary permeability without alveolar
    involvement
  • Radiographically, resembles hydrostatic edema
    (septal lines, peribronchial cuffing) because
    alveolar epithelium remains intact

28
Mixed hydrostatic and permeability edema
  • High-altitude pulmonary edema
  • Neurogenic edema
  • Reexpansion and post-obstructive

29
High-altitude pulmonary edema (HAPE)3
  • Hypoxia causes non-uniform pulmonary
    vasoconstriction, leaving other lung units
    over-perfused and predisposed to edema
  • Higher pressures can result in some capillary
    damage and stress failure

30
High-altitude pulmonary edema3
  • Radiographs show patchy ground glass with a
    central distribution favoring peribronchial
    cuffing and vascular indistinctness over septal
    lines

31
Neurogenic Edema3
  • Pathophysiology similar to HAPE neural
    mechanisms result in non-uniform vasoconstriction
  • High protein content of fluid indicates capillary
    leakage involved as well

32
Neurogenic Edema3
  • Classically, neurogenic edema has an upper lobe
    predominance however, it can present with any
    pattern
  • Often clears rapidly, arguing for intact alveoli

33
Neurogenic Edema4
  • 54 year-old woman with intracranial hemorrhage
  • Note upper lobe predominance

34
Reexpansion and Postobstructive Edema3
  • Both occur in setting of high negative pleural
    pressure
  • Reexpansion usually seen as localized lung
    injury, with alveolar filling and exudative
    fluid, arguing for increased permeability as a
    cause
  • Postobstructive pattern usually hydrostatic,
    secondary to increased central blood volume
    caused by the relief of obstruction

35
Reexpansion Edema4
Right pneumothorax
One-hour post chest-tube placement
36
Postobstructive Edema4
  • Postextubation Laryngospasm note central
    distribution and peribronchial cuffing.

37
Conclusions
  • Hydrostatic Edema is characterized by
  • Vascular indistinctness
  • Peribronchial cuffing
  • Septal lines/fissure thickening
  • Permeability Edema with DAD (ARDS) is
    characterized by
  • Diffuse, patchy ground glass opacities
  • Air bronchograms
  • Overlap is seen in pathophysiology, thus can be
    reflected in the radiograph

38
Summary Table1
Hydrostatic Permeability with DAD
Heart size Often enlarged Usually not enlarged
Septal Lines Common Absent
Peribronchial cuffs Common Not common
Air bronchograms Not common Very common
Regional distribution Even or central Patchy or peripheral
39
Hydrostatic and Permeability Edema
Images courtesy of Dr. Marc Gosselin
40
The condition of the capillary endothelium and
that of the alveolar epithelium are the main
determinants3
41
References
  • 1Milne ENC and Massimo P. Reading the Chest
    Radiograph A Physiologic Approach. Mosby, 1993.
  • 2Ware LB and Matthay MA. Acute pulmonary edema.
    The New England Journal of Medicine. 2005 353
    2788-96.
  • 3Ketai LH and Godwin JD. A new view of pulmonary
    edema and acute respiratory distress syndrome.
    Journal of Thoracic Imaging. 1998 13 147-171.
  • 4Gluecker T. Capasso P. Schnyder P. Gudinchet F.
    Schaller MD. Revelly JP. Chiolero R. Vock P.
    Wicky S. Clinical and radiologic features of
    pulmonary edema. Radiographics. 19(6)1507-31
    discussion 1532-3, 1999 Nov-Dec.

42
References
  • Images taken from
  • myweb.lsbu.ac.uk/ dirt/museum/p6-71.html
  • www.bcm.edu/.../cases/ pediatric/text/7a-desc.htm
  • http//www.hcoa.org/hcoacme/chf-cme/chf00030.htm
  • http//www-medlib.med.utah.edu/WebPath/LUNGHTML/LU
    NG131.html
  • http//www-medlib.med.utah.edu/WebPath/LUNGHTML/LU
    NG133.html
  • http//www.lumen.luc.edu/lumen/MedEd/MEDICINE/PULM
    ONAR/CXR/atlas/images/310a1.jpg
  • www.high-altitude-medicine.com/ AMS-medical.html
  • Sherman SC. Reexpansion pulmonary edema a case
    report and review of the current literature.
    Journal of Emergency Medicine. Jan 2003 24(1)
    23-7.
  • Thanks to Dr. Marc Gosselin for images, insights
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