Abnormal signs in chest x ray
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Sep 02, 2020
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About This Presentation
Brief descriptions of different signs in chest x-ray
Slide Content
Abnormal Sign in Chest X-
ray
ray
Silhouette sign:
Density difference delineation of the outline.
There are four basic densities in x-ray images:
gas
fat
water / soft tissue
bone / calcium
Loss of density difference of the adjacent
structures loss of silhouette.
Density difference delineation of the outline.
There are four basic densities in x-ray images:
gas
fat
water / soft tissue
bone / calcium
Loss of density difference of the adjacent
structures loss of silhouette.
Silhouette sign contd…
•The silhouette sign is the absence of depiction
of an anatomic soft-tissue borderresulting
from the juxtaposition of structuresof similar
radiographic attenuation.
•The sign actually refers to the absence of a
silhouette.
•If the borders are retained
–Not adjacent to each other or
–Of different radiographic densities.
•The silhouette sign is the absence of depiction
of an anatomic soft-tissue borderresulting
from the juxtaposition of structuresof similar
radiographic attenuation.
•The sign actually refers to the absence of a
silhouette.
•If the borders are retained
–Not adjacent to each other or
–Of different radiographic densities.
Silhouette Sign
•Cardiac margins are clearly seen because there
is contrast between the fluid density of the heart
and the adjacent air filled alveoli.
•If the adjacent lung is devoid of air, the clarity of
the silhouette will be lost.
•Pleura encircles the lung and diseases ofthe
pleura can also obliterate silhouettes. The same
is true for mediastinal masses.
•Cardiac margins are clearly seen because there
is contrast between the fluid density of the heart
and the adjacent air filled alveoli.
•If the adjacent lung is devoid of air, the clarity of
the silhouette will be lost.
•Pleura encircles the lung and diseases ofthe
pleura can also obliterate silhouettes. The same
is true for mediastinal masses.
Silhouette Adjacent
Lobe/Segment
Right diaphragm RLL/Basal segments
Right heart margin RML/Medial segment
Ascending aorta RUL/Anterior segment
Aortic knob LUL/Apicoposterior segment
Left heart margin Lingula/Inferior segment
Descending aorta LLL/Superior and medial
segments
Left diaphragm LLL/Basal segments
Lobe/Segment
Right diaphragm RLL/Basal segments
Right heart margin RML/Medial segment
Ascending aorta RUL/Anterior segment
Aortic knob LUL/Apicoposterior segment
Left heart margin Lingula/Inferior segment
Descending aorta LLL/Superior and medial
segments
Left diaphragm LLL/Basal segments
Chest radiograph shows silhouette sign, with
obscuration of right border of heart (arrows).
obscuration of right border of heart (arrows).
Lingular segment consolidation
Hilum overlay sign
•This is the same concept as a silhouette sign.
•If the interlobar pulmonary artery can be seen
through the mass,it means that the mass seen
is either in front of or behind it.
•Visibility of pulmonary artery
more than a centimeter within the lateral edge of what
appears to be the cardiac silhouette.
–Useful in differentiating the enlarged cardiac shadow
from anterior mediastinal mass.
•This is the same concept as a silhouette sign.
•If the interlobar pulmonary artery can be seen
through the mass,it means that the mass seen
is either in front of or behind it.
•Visibility of pulmonary artery
more than a centimeter within the lateral edge of what
appears to be the cardiac silhouette.
–Useful in differentiating the enlarged cardiac shadow
from anterior mediastinal mass.
Hilum Overlay Sign: hilar vessels are seen through a
mediastinal mass
mediastinal mass
Hilum convergence sign
•If pulmonary artery branches converge
towards the opacity enlarged artery
•If converge towards heart (i.e., seen
through the opacity) hilar/mediastinal
mass
•If pulmonary artery branches converge
towards the opacity enlarged artery
•If converge towards heart (i.e., seen
through the opacity) hilar/mediastinal
mass
Cervico-thoracic sign
–If the thoracic lesion is in anatomic contact with soft tissues of
neck its contiguous border will be lost.
•Lesion clearly visible above the clavicles lies
posteriorly within the thorax.
•If cephalic border of the lesion disappears as it
approaches the clavicle cervico-thoracic lesion
(partly in anterior mediastinum and partly in neck)
–If the thoracic lesion is in anatomic contact with soft tissues of
neck its contiguous border will be lost.
•Lesion clearly visible above the clavicles lies
posteriorly within the thorax.
•If cephalic border of the lesion disappears as it
approaches the clavicle cervico-thoracic lesion
(partly in anterior mediastinum and partly in neck)
Cervicothoracic sign
mass extending above the level of the clavicle and there is lung tissue
in front of it, so this must be a mass in the posterior mediastinum.
mass extending above the level of the clavicle and there is lung tissue
in front of it, so this must be a mass in the posterior mediastinum.
Thoraco-abdominal sign
•Posterior costophrenic sulcus extends
more caudally than anterior basilar lung.
•Lesion extends below the dome of
diaphragm must be in posterior chest
whereas lesion terminates at dome must
be anterior.
•Posterior costophrenic sulcus extends
more caudally than anterior basilar lung.
•Lesion extends below the dome of
diaphragm must be in posterior chest
whereas lesion terminates at dome must
be anterior.
Air bronchogram
•Visualization of air-filled bronchi
surrounded by air-less lung.
Normal lung. Bronchi not seen Bronchi visible because the air
in the surrounding alveoli has
been replaced by fluid.
•Visualization of air-filled bronchi
surrounded by air-less lung.
Normal lung. Bronchi not seen Bronchi visible because the air
in the surrounding alveoli has
been replaced by fluid.
Air Bronchogram
•In a normal chest x-ray, the tracheobronchial
tree is not visible beyond 4th order.
•The lumen of bronchus contains air and the
surrounding alveoli contain air. Thus there is no
contrast to visualize bronchi.
•The air column in bronchi beyond 4th order
becomes recognizable if the surrounding alveoli
is filled, providing a contrast = Air
bronchogram.
•In a normal chest x-ray, the tracheobronchial
tree is not visible beyond 4th order.
•The lumen of bronchus contains air and the
surrounding alveoli contain air. Thus there is no
contrast to visualize bronchi.
•The air column in bronchi beyond 4th order
becomes recognizable if the surrounding alveoli
is filled, providing a contrast = Air
bronchogram.
Chest x-ray of a patient with right upper lobe consolidation.
•Indicates that the lesion is intrapulmonary.
•Seen in
–Pneumonia
–Pulmonary edema
–Hyaline membrane disease
–Alveolar cell carcinoma
–Lymphoma
–Radiation pneumonitis
•Seen in
–Pneumonia
–Pulmonary edema
–Hyaline membrane disease
–Alveolar cell carcinoma
–Lymphoma
–Radiation pneumonitis
Bilateral upper lobe consolidation
•Air alveologram
–Tiny areas of radiolucency within the
surrounding air-less lung
–Tiny areas of radiolucency within the
surrounding air-less lung
Patterns of Parenchymal Opacity
•Shadowing in the lungs is due to:
–Alveolar disease
–Interstitial disease
•This distinction is sometimes difficult and there is
often overlap between the two.
•But it does help in interpretation and deciding
the possible cause of an abnormality. There are
often features of both.
•Shadowing in the lungs is due to:
–Alveolar disease
–Interstitial disease
•This distinction is sometimes difficult and there is
often overlap between the two.
•But it does help in interpretation and deciding
the possible cause of an abnormality. There are
often features of both.
•Alveolar / Air-space / Acinar opacities
–Acinus
•functional unit, distal to a terminal bronchiole
•6-8 mm in size
•Communication via pores of Kohn and channels of
Lambert
–Acinus
•functional unit, distal to a terminal bronchiole
•6-8 mm in size
•Communication via pores of Kohn and channels of
Lambert
Acinar Shadows
•Features
–Acinar nodules –6-8mm sized nodules
–Fluffy (ill-defined) margins
–Early coalescence consolidation
–Air bronchogram / alveologram
–Segmental / lobar distribution
–Bat's wing (butterfly) distribution
–Rapidly changing over time
•Features
–Acinar nodules –6-8mm sized nodules
–Fluffy (ill-defined) margins
–Early coalescence consolidation
–Air bronchogram / alveologram
–Segmental / lobar distribution
–Bat's wing (butterfly) distribution
–Rapidly changing over time
•Alveolar nodules
Alveolar cell ca
•Acinar Nodules
•Nodules of varying
size with irregular
margins
•Acinar Nodules
•Nodules of varying
size with irregular
margins
Interstitial opacities
Interstitium the tissue in which the blood
vessels and bronchi lie within the lungs.
•leads to a non homogenous pattern of shadowing
which may take many forms.
•alveoli are still aerated and therefore there is no air
bronchogram or silhouette sign.
•disease may be diffuse or localised.
Interstitium the tissue in which the blood
vessels and bronchi lie within the lungs.
•leads to a non homogenous pattern of shadowing
which may take many forms.
•alveoli are still aerated and therefore there is no air
bronchogram or silhouette sign.
•disease may be diffuse or localised.
Interstitial Opacity
Type Example
•Reticular/linear
•Reticulonodular
•Branching
•Idiopathic pulmonary
fibrosis
•Sarcoidosis
•Allergic
bronchopulmonary
aspergillosis
Type Example
•Reticular/linear
•Reticulonodular
•Branching
•Idiopathic pulmonary
fibrosis
•Sarcoidosis
•Allergic
bronchopulmonary
aspergillosis
Contd..
Type of Interstitial
opacities
Example
Nodular
•Miliary (<2 mm)
•Micronodule (2–7 mm)
•Nodule (7–30 mm)
•Mass (>30 mm)
•Atelectasis
•Miliary tuberculosis
•Acute hypersensitivity pneumonitis
•Metastatic disease, granuloma
•Bronchogenic carcinoma
•Endobronchial neoplasm
Type of Interstitial
opacities
Example
Nodular
•Miliary (<2 mm)
•Micronodule (2–7 mm)
•Nodule (7–30 mm)
•Mass (>30 mm)
•Atelectasis
•Miliary tuberculosis
•Acute hypersensitivity pneumonitis
•Metastatic disease, granuloma
•Bronchogenic carcinoma
•Endobronchial neoplasm
Patterns of Interstitial
Opacities in CXR
Opacities in CXR
reticular pattern
•a reticular pattern is a collection of
innumerable small linear opacities that, by
summation, produce an appearance
resembling a net.
•a reticular pattern is a collection of
innumerable small linear opacities that, by
summation, produce an appearance
resembling a net.
Chest radiograph shows reticular pattern
reticulonodular pattern
•A combined reticular and nodular pattern, the
reticulonodular pattern is usually the result of the
summation of points of intersection of
innumerable lines, creating the effect on chest
radiographs of superimposed micronodules.
•The dimension of the nodules depends on the
size and number of linear or curvilinear
elements.
•A combined reticular and nodular pattern, the
reticulonodular pattern is usually the result of the
summation of points of intersection of
innumerable lines, creating the effect on chest
radiographs of superimposed micronodules.
•The dimension of the nodules depends on the
size and number of linear or curvilinear
elements.
Chest radiograph shows reticulonodular pattern
Bilateral reticulonodular shadowing most obvious at the bases.
This patient had rheumatoid arthritis.
This patient had rheumatoid arthritis.
Magnified chest radiograph shows a nodular
pattern.
pattern.
Kerley Lines
•Indicative of interstitial disease.
•A: Long wavy lines in upper and mid lung field
•B: 2-3 cm long, 1-2mm thick, pleural based in
bases perpendicular to lateral chest; reliable,
thickening of interlobular septa.
•C: Fine fibrillatory lines: You can imagine this on
most cases
•Indicative of interstitial disease.
•A: Long wavy lines in upper and mid lung field
•B: 2-3 cm long, 1-2mm thick, pleural based in
bases perpendicular to lateral chest; reliable,
thickening of interlobular septa.
•C: Fine fibrillatory lines: You can imagine this on
most cases
Kerley C lines
Kerley A lines
Kerley B lines
Kerley A lines
Kerley B lines
Kerley lines
Causes of Kerley’s lines (A,B & C)
•Transient
–Common: Pulmonary edema
–Rare: Pneumonia, pulmonary hemorrhage, Transient
respiratory distress of newborn
•Persistent
–Common:
•Lymphangitic metastases
•Pneumoconiosis
•Rheumatic mitral valve disease
–Rare:
•Alveolar cell carcinoma
•Congenital heart disease
•Interstitial fibrosis of any cause
•Lymphoma
•Mineral oil aspiration etc.
•Transient
–Common: Pulmonary edema
–Rare: Pneumonia, pulmonary hemorrhage, Transient
respiratory distress of newborn
•Persistent
–Common:
•Lymphangitic metastases
•Pneumoconiosis
•Rheumatic mitral valve disease
–Rare:
•Alveolar cell carcinoma
•Congenital heart disease
•Interstitial fibrosis of any cause
•Lymphoma
•Mineral oil aspiration etc.
Signs of collapse of lungs
–Direct signs
•Opacity/loss of aeration of the affected lobe
•Crowding of vessels
•Dispalcement / bowing of fissures
–Indirect signs
•Compensatory hyperinflation of normal lung
•Ipsilateral mediastinal/ tracheal displacement
•Displacement of hilum
•Elevation of hemi-diaphragm
•Crowding of ribs on affected side
–Direct signs
•Opacity/loss of aeration of the affected lobe
•Crowding of vessels
•Dispalcement / bowing of fissures
–Indirect signs
•Compensatory hyperinflation of normal lung
•Ipsilateral mediastinal/ tracheal displacement
•Displacement of hilum
•Elevation of hemi-diaphragm
•Crowding of ribs on affected side
•Lobar collapse
The lobes collapse in characteristic fashion:
–1. The upper lobes collapse upwards,
medially and anteriorly
–2. The middle lobe goes downwards and
medially
–3. The lower lobes collapse posteriorly,
medially and downwards.
The lobes collapse in characteristic fashion:
–1. The upper lobes collapse upwards,
medially and anteriorly
–2. The middle lobe goes downwards and
medially
–3. The lower lobes collapse posteriorly,
medially and downwards.
The lesser
fissure moves
upwards but
remains pivoted
at the R hilum
medially
Lateral view.
The upper lobe
collapses
upwards,
anteriorly, and
towards the
mediastinum.
Collapse of the R upper lobe.
Opacity in the upper lobe,
silhouette sign upper
mediastinum & upward
displacement of the lesser
fissure.
fissure moves
upwards but
remains pivoted
at the R hilum
medially
Lateral view.
The upper lobe
collapses
upwards,
anteriorly, and
towards the
mediastinum.
Collapse of the R upper lobe.
Opacity in the upper lobe,
silhouette sign upper
mediastinum & upward
displacement of the lesser
fissure.
S Curve of Golden
•When there is a mass adjacent to a
fissure, the fissure takes the shape ofan
"S". The proximal convexity is due to a
mass, and the distal concavity is due to
atelectasis.
•When there is a mass adjacent to a
fissure, the fissure takes the shape ofan
"S". The proximal convexity is due to a
mass, and the distal concavity is due to
atelectasis.
Posteroanterior radiograph of the chestdemonstrates the
Golden S sign. Note the convexity (arrowhead) from the
mass and the concavity (arrow) of the minor fissure
Golden S sign. Note the convexity (arrowhead) from the
mass and the concavity (arrow) of the minor fissure
•Golden S sign
Lt upper lobe collapse
•Mediastinal shift to left
•Density left upper lung field
•Loss of aortic knob and left hilar
silhouettes
•Mediastinal shift to left
•Density left upper lung field
•Loss of aortic knob and left hilar
silhouettes
Bowing Sign
•In LUL atelectasis or following resection,
the oblique fissure bows forwards (lateral
view).
•Bowing sign refers to this feature.
•In LUL atelectasis or following resection,
the oblique fissure bows forwards (lateral
view).
•Bowing sign refers to this feature.
Bowing sign
Luftsichel sign
•Luft = air; sichel = crescent
•With complete collapse, the left upper lobe retracts
medially and superiorly.
•Hyperexpanded superior segment of the left lower lobe
produces a crescent of lucency interposed between the
atelectatic left upper lobe and the aortic arch.
•This crescent of air is termed the luftsichel sign.
•Other features of left upper lobe collapse are present
•Luft = air; sichel = crescent
•With complete collapse, the left upper lobe retracts
medially and superiorly.
•Hyperexpanded superior segment of the left lower lobe
produces a crescent of lucency interposed between the
atelectatic left upper lobe and the aortic arch.
•This crescent of air is termed the luftsichel sign.
•Other features of left upper lobe collapse are present
Luftsichel sign
Rt. middle lobe collapse. There
is a density next to the heart,
below the R hilum, which is
roughly triangular in shape
Lateral view shows the middle
lobe collapse more clearly. The
triangular opacity anteriorly is
the collapsed lobe
is a density next to the heart,
below the R hilum, which is
roughly triangular in shape
Lateral view shows the middle
lobe collapse more clearly. The
triangular opacity anteriorly is
the collapsed lobe
AtelectasisRight Lower Lobe
•Density in right
lower lung field
•Indistinct right
diaphragm
•Right heart
silhouette retained
•Transverse fissure
moved down
•Right hilum
moved down
•Density in right
lower lung field
•Indistinct right
diaphragm
•Right heart
silhouette retained
•Transverse fissure
moved down
•Right hilum
moved down
Left Lower Lobe Atelectasis
•Inhomogeneous cardiac
density
•Left hilum pulled down
•Non-visualization of left
diaphragm
•Triangular retrocardiac
atelectatic LLL
•Inhomogeneous cardiac
density
•Left hilum pulled down
•Non-visualization of left
diaphragm
•Triangular retrocardiac
atelectatic LLL
Plate (linear) atelectasis
•Is a focal area of subsegmental atelectasis with a linear
configuration, almost always extending to the pleura.
•Also known as discoidor plate like atelectasis.
•It is commonly horizontal but sometimes oblique or
vertical.
•The thickness of the atelectasis may range from a few
millimeters to more than 1 cm.
•Seen in impaired diaphragmatic motion: thoracic trauma,
subphrenic disease, pathologic elevation of diaphragm,
normal hypersthenic individuals with a high diaphragm.
•Is a focal area of subsegmental atelectasis with a linear
configuration, almost always extending to the pleura.
•Also known as discoidor plate like atelectasis.
•It is commonly horizontal but sometimes oblique or
vertical.
•The thickness of the atelectasis may range from a few
millimeters to more than 1 cm.
•Seen in impaired diaphragmatic motion: thoracic trauma,
subphrenic disease, pathologic elevation of diaphragm,
normal hypersthenic individuals with a high diaphragm.
Chest radiograph shows basal linear atelectasis
•Plate atelectasis
•linear subsegmental atelectatic shadows
at the lung bases
•linear subsegmental atelectatic shadows
at the lung bases
Cut Off Sign
•An abrupt ending of visualized bronchus =
"cut off sign".
•It indicates an intrabronchial lesion.
•This is useful to identify the etiology of
atelectasis .
•An abrupt ending of visualized bronchus =
"cut off sign".
•It indicates an intrabronchial lesion.
•This is useful to identify the etiology of
atelectasis .
Open Bronchus Sign / Alveolar
Atelectasis
•Presence of air bronchogram in atelectatic
lung.
•indicates that the airways are patent.
•Commonly seen in adhesive alveolar
atelectasis.
Atelectasis
•Presence of air bronchogram in atelectatic
lung.
•indicates that the airways are patent.
•Commonly seen in adhesive alveolar
atelectasis.
Open bronchus sign
Close up view
Air crescent/ halo sign
•An air crescent is a collection of air in a
crescentic shape that separates the wall of a
cavity from an inner mass.
•The air crescent sign is often considered
characteristic of either Aspergilluscolonization of
preexisting cavities or retraction of infarcted lung
in angioinvasive aspergillosis.
•other causes:
–tuberculosis, Wegener granulomatosis, intracavitary
hemorrhage, lung cancer, lung gangrene
•An air crescent is a collection of air in a
crescentic shape that separates the wall of a
cavity from an inner mass.
•The air crescent sign is often considered
characteristic of either Aspergilluscolonization of
preexisting cavities or retraction of infarcted lung
in angioinvasive aspergillosis.
•other causes:
–tuberculosis, Wegener granulomatosis, intracavitary
hemorrhage, lung cancer, lung gangrene
Magnified chest radiograph shows air crescent
(arrows) adjacent to mycetoma
(arrows) adjacent to mycetoma
Halo Sign
In a cavity with fungus ball there is a crescentic lucent space along the upper
portion of a density giving the appearance of a halo.
In a cavity with fungus ball there is a crescentic lucent space along the upper
portion of a density giving the appearance of a halo.
Double Density
•Heart should be of uniform density, except over vertebra
and descending aorta.
•If increased density in one portion compared to rest of
the heart, consider an abnormal density either in front or
behind the heart.
•Left atrial enlargement can be recognized by the circular
double density.
•LLL disease,hiatal hernia and posterior mediastinal
masseswill give double density over left side of heart.
•Esophageal disease, posterior mediastinal masses and
hiatal hernia can give double density over right side of
cardiac density.
•Heart should be of uniform density, except over vertebra
and descending aorta.
•If increased density in one portion compared to rest of
the heart, consider an abnormal density either in front or
behind the heart.
•Left atrial enlargement can be recognized by the circular
double density.
•LLL disease,hiatal hernia and posterior mediastinal
masseswill give double density over left side of heart.
•Esophageal disease, posterior mediastinal masses and
hiatal hernia can give double density over right side of
cardiac density.
Double density
Bulging Fissure Sign
Consolidation spreading rapidly, causing lobar expansion and
bulging of the adjacent fissure inferiorly .
The most common infective causative agents are
Klebsiella pneumoniae,Streptococcus pneumoniae,
Pseudomonas aeruginosa,Staphylococcus aureus
Consolidation spreading rapidly, causing lobar expansion and
bulging of the adjacent fissure inferiorly .
The most common infective causative agents are
Klebsiella pneumoniae,Streptococcus pneumoniae,
Pseudomonas aeruginosa,Staphylococcus aureus
Continuous Diaphragm Sign
Continuous lucencyoutlining the
base of the heart, representing
pneumomediastinum.
Air in the mediastinumtracks
extrapleurally, between the heart
and diaphragm .
Pneumopericardiumcan have a
similar appearance but will show
air circumferentially outlining the
heart.
Continuous lucencyoutlining the
base of the heart, representing
pneumomediastinum.
Air in the mediastinumtracks
extrapleurally, between the heart
and diaphragm .
Pneumopericardiumcan have a
similar appearance but will show
air circumferentially outlining the
heart.
CT angiogram Sign
Identification of vessels within an
airless portion of lung on contrast-
enhanced CT .
The vessels are prominently seen
against a background of low-
attenuation material .
Associated with:
bronchoalveolarcell carcinoma
lymphoma
infectious pneumonias.
Identification of vessels within an
airless portion of lung on contrast-
enhanced CT .
The vessels are prominently seen
against a background of low-
attenuation material .
Associated with:
bronchoalveolarcell carcinoma
lymphoma
infectious pneumonias.
Deep Sulcus Sign
This sign refers to a deep
collection of intrapleuralair
(pneumothorax) in the
costophrenicsulcusas seen
on the supine chest
radiograph .
This sign refers to a deep
collection of intrapleuralair
(pneumothorax) in the
costophrenicsulcusas seen
on the supine chest
radiograph .
Fallen Lung Sign
This sign refers to the appearance
of the collapsed lung occurring
with a fractured bronchus .
The bronchial fracture results in
the lung to fall away from the
hilum, either inferiorly and laterally
in an upright patient or posteriorly,
as seen on CT in a supine patient.
DD:
Pneumothorax causes a lung to
collapse inward toward the hilum.
This sign refers to the appearance
of the collapsed lung occurring
with a fractured bronchus .
The bronchial fracture results in
the lung to fall away from the
hilum, either inferiorly and laterally
in an upright patient or posteriorly,
as seen on CT in a supine patient.
DD:
Pneumothorax causes a lung to
collapse inward toward the hilum.
Finger in Glove Sign
In allergic bronchopulmonaryaspergillosis.
The impacted bronchi appear radiographicallyas opacities with distinctive
shapes.
In allergic bronchopulmonaryaspergillosis.
The impacted bronchi appear radiographicallyas opacities with distinctive
shapes.
Hampton Hump Sign
Pulmonary infarction secondary to pulmonary embolismproduces
an abnormal area of opacificationon the chest radiograph, which
is always in contact with the pleural surface.
Pulmonary infarction secondary to pulmonary embolismproduces
an abnormal area of opacificationon the chest radiograph, which
is always in contact with the pleural surface.
Juxtaphrenic Peak Sign
This sign refers to a small triangular shadow that obscures the dome of the
diaphragm secondary to upper lobe atelectasis . The shadow is caused by
traction on the lower end of the major fissure, the inferior accessory fissure, or
the inferior pulmonary ligament.
This sign refers to a small triangular shadow that obscures the dome of the
diaphragm secondary to upper lobe atelectasis . The shadow is caused by
traction on the lower end of the major fissure, the inferior accessory fissure, or
the inferior pulmonary ligament.
THANK YOU
QUESTIONS
•Silhouette Sign.
•Hilum overlay sign.
•Air bronchogram.
•Patterns of parenchymal opacities.
•Causes of kerely’s line.
•Signs of collapse of lung.
•Luftsichel sign.
•Air crescent sign.
•Continous diaphragm sign.
•Silhouette Sign.
•Hilum overlay sign.
•Air bronchogram.
•Patterns of parenchymal opacities.
•Causes of kerely’s line.
•Signs of collapse of lung.
•Luftsichel sign.
•Air crescent sign.
•Continous diaphragm sign.
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