Basics of Chest Sonography

and Anatomy of Chest Wall

By

Gamal Rabie Agmy , MD , FCCP Professor of Chest Diseases ,Assiut University

ERS National Delegate of Egypt

• Diagnostic ultrasonography

is the only clinical imaging

technology currently in use

that does not depend on

electromagnetic radiation.

Ultrasound Transducer

Speaker

transmits sound pulses

Microphone

receives echoes

• Acts as both speaker & microphone Emits very short sound pulse

Listens a very long time for returning echoes

• Can only do one at a time

Physical Principles

Cycle • 1 Cycle = 1 repetitive periodic oscillation

Cycle

Frequency

• # of cycles per second

• Measured in Hertz (Hz)

-Human Hearing 20 - 20,000 Hz

-Ultrasound > 20,000 Hz

-Diagnostic Ultrasound 2.5 to 10

MHz

(this is what we use!)

frequency 1 cycle in 1 second = 1Hz

1 second

= 1 Hertz

High Frequency

• High frequency (5-10 MHz)

greater resolution

less penetration

• Shallow structures

vascular, abscess, t/v gyn,

testicular

Low Frequency

• Low frequency (2-3.5 MHz)

greater penetration

less resolution

• Deep structures

Aorta, t/a gyn, card, gb, renal

Wavelength

• The length of one complete cycle

• A measurable distance

Wavelength

Wavelength

Amplitude

• The degree of variance from the normal

Amplitude

The Machine

Ultrasound scanners

• Anatomy of a scanner:

– Transmitter

– Transducer

– Receiver

– Processor

– Display

– Storage

Transmitter

• a crystal makes energy into sound waves and then receives sound waves and converts to energy

• This is the Piezoelectric effect

• u/s machines use time elapsed with a presumed velocity (1,540 m/s) to calculate depth of tissue interface

• Image accuracy is therefore dependent on accuracy of the presumed velocity.

Transducers

• Continuous mode

– continuous alternating current

– doppler or theraputic u/s

– 2 crystals –1 talks, 1 listens

• Pulsed mode

– Diagnostic u/s

– Crystal talks and then listens

Receiver

• Sound waves hit and make voltage

across the crystal-

• The receiver detects and amplifies

these voltages

• Compensates for attenuation

Signal Amplification

• TGC (time gain

compensation)

– Manual control

– Selective enhancement or suppression of sectors of the image

– enhance deep and suppress superficial

*blinders

• Gain

– Manual control

– Affects all parts of the image equally

– Seen as a change in “brightness” of the images on the entire screen

*glasses

Changing the TGC

Changing the Gain

Displays

• B-mode

– Real time gray scale, 2D

– Flip book- 15-60 images per second

• M-mode

– Echo amplitude and position of moving

targets

– Valves, vessels, chambers

“B” Mode

“M” Mode

Image properties

• Echogenicity- amount of energy reflected back from tissue interface

– Hyperechoic - greatest intensity - white

– Anechoic - no signal - black

– Hypoechoic – Intermediate - shades of gray

Hyperechoic

Hypoechoic

Anechoic

Image Resolution

• Image quality is dependent on

– Axial Resolution

– Lateral Resolution

– Focal Zone

– Probe Selection

– Frequency Selection

– Recognition of Artifacts

Axial Resolution

• Ability to differentiate two objects along

the long axis of the ultrasound beam

• Determined by the pulse length • Product of wavelength λ and # of cycles in

pulse

• Decreases as frequency f increases

• Higher frequencies produce better

resolution

Axial Resolution

• 5 MHz transducer

– Wavelength 0.308mm

– Pulse of 3 cycles

– Pulse length

approximately 1mm

– Maximum resolution

distance of two objects

= 1 mm

• 10 MHz transducer

– Wavelength 0.15mm

– Pulse of 3 cycles

– Pulse length

approximately 0.5mm

– Maximum resolution

distance of two objects

= 0.5mm

Axial Resolution

body

screen

Lateral Resolution

• The ultrasound beam is made up of

multiple individual beams

• The individual beams are fused to

appear as one beam

• The distances between the single

beams determines the lateral resolution

Lateral resolution

• Ability to differentiate objects along an

axis perpendicular to the ultrasound

beam

• Dependent on the width of the

ultrasound beam, which can be

controlled by focusing the beam

• Dependent on the distance between the

objects

Lateral Resolution

body

screen

Focal Zone • Objects within the focal zone • Objects outside of focal zone

Focal zone Focal zone

Probe options • Linear Array

• Curved Array

Ultrasound Artifacts

• Can be falsely interpreted as real

pathology

• May obscure pathology

• Important to understand and appreciate

Ultrasound Artifacts

• Acoustic enhancement

• Acoustic shadowing

• Lateral cystic shadowing (edge artifact)

• Wide beam artifact

• Side lobe artifact

• Reverberation artifact

• Gain artifact

• Contact artifact

Acoustic Enhancement

• Opposite of acoustic shadowing

• Better ultrasound transmission allows

enhancement of the ultrasound signal

distal to that region

Acoustic Enhancement

Acoustic Shadowing

• Occurs distal to any highly reflective or

highly attenuating surface

• Important diagnostic clue seen in a

large number of medical conditions

– Biliary stones

– Renal stones

– Tissue calcifications

Acoustic Shadowing

• Shadow may be more prominent than

the object causing it

• Failure to visualize the source of a

shadow is usually caused by the object

being outside the plane of the

ultrasound beam

Acoustic Shadowing

Acoustic Shadowing

Lateral Cystic Shadowing

• A type of refraction artifact

• Can be falsely interpreted as an

acoustic shadow (similar to gallstone)

X

Lateral Cystic Shadowing

Beam-Width Artifact

• Gas bubbles in the duodenum can

simulate a gall stone

• Does not assume a dependent posture

• Do not conform precisely to the walls of

the gallbladder

Beam-Width Artifact

Beam-width artifact Gas in the duodenum simulating stones

Side Lobe Artifact

• More than one ultrasound beam is

generated at the transducer head

• The beams other than the central axis

beam are referred to as side lobes

• Side lobes are of low intensity

Side Lobe Artifact

• Occasionally cause

artifacts

• The artifact by be

obviated by

alternating the angle

of the transducer

head

Side Lobe Artifact

Reverberation Artifacts

• Several types

• Caused by the echo bouncing back and

forth between two or more highly

reflective surfaces

Reverberation Artifacts

• On the monitor parallel bands of

reverberation echoes are seen

• This causes a “comet-tail” pattern

• Common reflective layers

– Abdominal wall

– Foreign bodies

– Gas

Reverberation Artifacts

Reverberation Artifacts

Gain Artifact

Contact artifact

• Caused by poor probe-

patient interface

Traditionally, air has been considered the

enemy of ultrasound and the lung has been

considered an organ not amenable to

ultrasonographic examination. Visualizing the

lung is essential to treating patients who are

critically ill.

Lines written on ultrasound in the five

Light’s editions

43

78

102

122

278

1983 1990 1995 2001 2008

1998 -2008

2009

2010

V SCAN

Probes

A high-resolution linear transducer of 5–10 MHz is suitable for imaging the thorax wall and the parietal pleura (Mathis 2004). More recently introduced probes of 10–13 MHz are excellent for evaluating lymph nodes (Gritzmann 2005), pleura and the surface of the lung.

For investigation of the lung a convex or sector probe

of 3–5 MHz provides adequate depth of penetration.

Transthoracic Sonography

Scanning Positions for Chest Sonography

http://radiographics.rsnajnls.org/cgi/content/full/20/3/653/F1

Normal Anatomy

Normal lung surface

Left panel: Pleural line and A line (real-time). The pleural line is located 0.5 cm below the rib line in the adult. Its visible length between two ribs in the longitudinal scan is approximately 2 cm. The upper rib, pleural line, and lower rib (vertical arrows) outline a characteristic pattern called the bat sign.

http://radiographics.rsnajnls.org/content/vol22/issue1/images/large/g02jae1g2a.jpeg

Normal Chest Ultrasound

Superficial tissues

ribs

Poste

rior a

coustic

shadow

ing

Impure

acoustic

shadow

ing

Pleural line

Muscle

Fat

Pleura

Lung

http://radiographics.rsnajnls.org/content/vol22/issue1/images/large/g02jae1g2b.jpeg

http://radiographics.rsnajnls.org/cgi/content/full/22/1/e1/F3A

http://radiographics.rsnajnls.org/cgi/content/full/22/1/e1/F3C

the "seashore sign" (Fig.3).

Duplex Doppler sonogram of a 5 x 3 cm hypoechoic mass

(adenocarcinoma) in upper lobe of left lung shows blood flow

at margin of tumor near pleura. Spectral waveform reveals

arteriovenous shunting: low-impedance flow with high

systolic and diastolic velocities. Pulsatility index = 0.90,

resistive index = 0.51, peak systolic velocity = 0.47 m/sec, end

diastolic velocity =0.23 m/sec, peak frequency shift = 3.8 kHz,

Duplex Doppler sonogram in 67-year-old man with pulmonary

tuberculosis in lower lobe of left lung shows several blue and

red flow signals in massiike lesion. Spectral waveform reveals

high-impedance flow. Pulsetility index = 4.20, resistive index =

0.93, peak systolic velocity = 0.45 m/sec, end diastolic

velocity = 0.03 m/sec, Doppler angle = 21#{

Alveolar-interstitial

syndrome

(Chest. 2008; 133:836-837)

© 2008 American College of Chest

Physicians

Ultrasound: The Pulmonologist’s New

Best Friend

Momen M. Wahidi, MD, FCCP

Durham, NC

Director, Interventional Pulmonology, Duke

University Medical Center, Box 3683,

Durham, NC 27710