The document discusses echocardiography and stress echocardiography. It provides details on various views obtained during echocardiography including parasternal long axis, parasternal short axis, apical 4-chamber, and subcostal views. It describes the technique, advantages, and disadvantages of transthoracic echocardiography and transesophageal echocardiography. Stress echocardiography involves exercising on a treadmill or stationary bike while monitoring the heart with echocardiography before and after exercise. Dobutamine stress echocardiography uses a drug instead of exercise to stress the heart. The document is authored by Dr. Ihtisham Sahil and focuses on echocardiography techniques
5. Description
It is a type of ultrasound test that uses high
pitched sound waves to produce an image of the
heart.
The sound waves are sent through a device called
a transducer and are reflected off the various
structures of the heart.
These echoes are converted into pictures of the
heart that can be seen on a video monitor.
Dr. IHTISHAM SAHIL
BS RADIOLOGY
HIMS PESHAWAR
6. COMPONENETS
Pulse generator - applies high amplitude voltage
to energize the crystals.
Transducer - converts electrical energy to
mechanical (ultrasound) energy and vice versa.
Receiver - detects and amplifies weak signals.
Display - displays ultrasound signals in a variety
of modes.
Memory - stores video display .
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9. INDICATIONS
Hypertension
Aortic and Major Arterial Disease
Pre-Operative Echocardiography for Elective
and Semi-urgent Surgery
Ejection fraction
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10. CONTRAINDICATIONS
Echocardiography has no contraindications. It
should be kept in mind, however, that this
modality may yield only limited information in
patients at the extremes of adult body weight,
because a thick chest wall (in markedly obese
patients) or overcrowded ribs (in severely
underweight patients) may limit the penetration
of ultrasound waves.
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11. Standard Echo Windows
Standard positions on the chest wall
are used for placement of the
transducer called “echo windows
1. Suprasternal
2. Right parasternal
3. Left parasternal
4. Apical
5. Sub costal
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13. Parasternal long-axis
view (PLAX)
Pt Positioning: left lateral decubitus.
transducer positioning: placed near
the sternum in the left third or fourth intercostal
space .
Marker dot direction: points towards
right shoulder.
Closest structure to the
transducer.
The right ventricular outflow tract (RVOT),in
the upper site of the image. Dr. IHTISHAM SAHIL
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14. Parasternal long-axis
view (PLAX)
Structures seen :
– proximal aorta
– aortic valve
– left atrium
– mitral valve
– left ventricle
– IV septum
– posterior wall
– right ventricle
– pericardium.
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17. Parasternal Short Axis View
(PSAX)
Transducer position: left sternal edge;
2nd–4th space
Marker dot direction: points towards left
shoulder (90° clockwise from PLAX).
By tilting the transducer on an axis between
the left hip and right shoulder, short-axis cuts
are obtained at different levels, from the aorta
to the LV apex .
This angulations of the transducer from the
base to apex of the heart for short-axis views
is known as “bread-loafing”.
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20. Apical 4-Chamber View
(A4CH View)
Transducer position: apex of the heart.
Marker dot direction: points towards left
shoulder.
Structures seen:
– right and left ventricle
– right and left atrium
– mitral, tricuspid valves
– IA and IV septum
– left ventricular apex
– lateral wall left ventricle
– free wall right ventricle.
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22. Apical 5-Chamber View
(A5CH view)
The A5CH view is obtained after the A4CH
view by slight downward tilting of the
transducer. The 5th chamber added is the left
ventricular outflow tract (LVOT).
Transducer position: as in A4CH view.
Marker dot direction: as in A4CH view.
Structures seen:
— LV outflow tract
— aortic valve
— proximal aorta.
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24. Sub costal View
Pt position:
The subject lies supine with the head held
slightly low, feet planted on the couch and the
knees slightly flexed.
Better images are obtained with the abdomen
relaxed and during the phase of inspiration.
Transducer position: under the
xiphisternum
Marker dot position: points towards left
shoulder.
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25. Sub costal View
Structures seen:
As in A4CH view.
The subcostal view is particularly useful when transthoracic E is
technically difficult because of the following reasons:
– severe morbid obesity
– chest wall deformity
– pulmonary emphysema.
The following structures are better seen from the subcostal
view than from the apical 4-chamber view:
– inferior vena cava
– descending aorta
– interatrial septum
– pericardial effusion.
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27. Suprasternal View
Pt Position: he subject lies supine with the
neck hyperextended by placing a pillow under
the shoulders. The head is rotated slightly
towards the left. The position of arms or legs
and the phase of respiration have no bearing on
this echo window.
Transducer position:suprasternal notch.
Marker dot direction: points towards left jaw.
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30. Echocardiography Types
Transthoracic echocardiogram
Conventional echocardiography is performed from the anterior chest
wall (precordium) and is known as transthoracic echo.
Echocardiography can also be performed from the esophagus which
is known as transesophageal echo.
For transthoracic echo, the subject is asked to lie in the
semirecumbent position on his or her left side with the head slightly
elevated.
The left arm is tucked under the head and the right arm lies along
the right side of the body.
This position opens the intercostal spaces through which
echocardiography can be performed, while most of the heart is
masked from the ultrasound beam by the ribs.
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31. Better images are obtained during expiration when there is least
‘air-tissue’ interface.
Ultrasound is transmitted from a transducer having a frequency
of 2.5 to 3.5 MHz for echo in adults.
This frequency is used to study deep seated structures because
of better penetration. A transducer frequency of 5.0 MHz is
suitable for pediatric echo, since the heart is more superficial in
children.
Ultrasound jelly is applied on the transducer and it is placed on
the chest at the site of an “echo window”.
Most of the time, the left parasternal and apical windows are
routinely used.
The transducer has a reference line or dot on one side, in order
to orient it in the correct direction, for obtaining various echo
views.
The transducer is variably positioned, in terms of location and
direction, for different echo images.
It can be tilted (superiorly or inferiorly), to bring into focus the
structure of interest and rotated (clockwise or anticlockwise), to
fine-tune the image.
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32. Apical four chamber
Subcostal
Various transthoracic
echocardiogram views
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33. Left parasternal long axis
Apical two chamber
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34. Left ventricle short axis
Aortic valve short axis
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35. TRANSESOPHAGEAL
ECHO
Principle
Anatomically speaking, the esophagus in its
mid-course is strategically located posterior to
the heart and anterior to the descending
aorta. This provides an opportunity to
interrogate the heart and related mediastinal
structures with a high frequency transducer
positioned in the esophagus for better image
resolution.
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36. Technique
A miniature transducer is mounted onto a probe or
gastroscope similar to the one employed for upper
gastrointestinal endoscopy. The scope is advanced
to various depths in the esophagus to examine
cardiac and related structures. By manoeuvring the
transducer and the angle of beam from controls on
the handle, different views of the heart are
obtained.
This ‘back-door’ approach to echocardiography
has both advantages and disadvantages. Dr. IHTISHAM SAHIL
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37. Advantages
Useful alternative to transthoracic echo if the latter is technically
difficult due to obesity, chest wall deformity, emphysema or
pulmonary fibrosis.
Useful complement to transthoracic echo because of better
image quality and resolution due to two reasons:
– absence of acoustic barrier between the ultrasound beam and
the rib cage, chest wall and lung tissue.
– greater proximity to the heart and therefore the ability to use
higher frequency probe with vastly improved image quality and
precise spatial resolution.
Useful supplement to transthoracic echo, which cannot
examine the posterior aspect of the heart. Structures suc as left
atrial appendage, descending aorta and pulmonary veins can
only be visualized by TEE.
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38. Disadvantages
The transesophageal echo (TEE) views are
significantly different from standard
transthoracic echo views. Novel TEE images
require a comprehensive understanding of
the spatial relationship between cardiac
structures.
It requires short-term sedation, oxygen
administration and ECG monitoring since,
there are chances of hypoxia, arrhythmia and
angina. Rarely, respiratory depression or
allergic reactions may occur.
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39. Complications with TEE
Major
• Esophageal rupture or perforation
• Laryngospasm or bronchopasm
• Sustained ventricular tachycardia
Minor
• Retching and vomiting
• Sore-throat and hoarseness
• Blood-tinged sputum
• Tachycardia or bradycardia
• Hypoxia and ischemia
• Transient BP rise or fall
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40. Contraindications to TEE
Absolute
• Uncooperative patient
• Poor cardiorespiratory status
• Esophageal obstruction
• Tracheoesophageal fistula
• Active bleed or coagulopathy
Relative
• Large esophageal varices• Prior esophageal surgery
• Unstable cervical arthritis
• Atlantoaxial dislocation
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43. Stress Echocardiography
A stress echocardiography, also called an echocardiography
stress test or stress echo, is a procedure that determines
how well your heart and blood vessels are working. During
a stress echocardiography, you'll exercise on a treadmill or
stationary bike while your doctor monitors your blood
pressure and heart rhythm.
Technique:
The echocardiogram is performed just prior and just
after the exercise. NPO for four hours before the test.
Do not drink or eat caffeine products (cola, chocolate,
coffee, tea) for 24 hours before the test.
Do not take any over-the-counter medications that
contain caffeine for 24 hours before the test.
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44. Do not take the following heart medications
for 24 hour before the test unless doctor tells
Beta-blockers (for example, Tenormin,
Lopressor, Toprol, or Inderal) Isosorbide
dinitrate (for example, Isordil, Sorbitrate)
Isosorbide mononitrate (for example, Ismo,
Indur, Monoket) Nitroglycerin (for example,
Deponit, Nitrostat, Nitropatches)
Do not discontinue any medication without
talking with doctor.
Continue
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45.
46. Dobutamine stress
echocardiogram
A form of stress echocardiogram.
Instead of exercising to stress the heart, the stress is obtained
by giving a drug that stimulates the heart an makes it "think" it is
exercising.
The test is used to evaluate heart and valve function when
unable to exercise on a treadmill or stationary bike.
It is also used to determine how well heart tolerate activity and
likelihood of having coronary artery disease, as well as
evaluating the effectiveness of cardiac treatment plan.
Most dobutamine stress protocols start at an infusio rate of
5microgram/kg/mt and increase to a peak dose of 40 or 50 ug /
kg / min
To further increase heart rate, a bolus injection of 0.25—1 .0
mg atropine is added
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47. PREPARATION
Wear comfortable clothing.
Do not eat for a minimum of 4 hours before the test.
Drinking water is allowed before the test.
If diabetic, juice is allowed in the morning with insulin
(1/2 dose). If on pills ,do not take medication until after
the test is complete.
Do not drink caffiene (coffee or tea) the day of the test.
Stop taking all medications including beta blockers,
calcium channel blockers, nitrates and digoxin for 24
hours prior to test
ECG electrodes will be placed to monitor
electrocardiogram
Blood pressure and ECG will be monitored throughout
the test.
Lie on left side on an exam table.
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48. An intravenous line (IV) will be inserted and
dobutamine is administered . While the infusion of
dobutamine is going on continous echo images will
be taken. The medication will cause heart to react as
if exercising.
The dobutamine may give a warm, flushing feeling
and some patients experience a mild headache.
Report if there is chest pain, arm or jaw pain ,short of
breath, dizzy or feel lightheaded.
The IV line will be removed once all of the
medication has entered bloodstream.
Intravascular ultrasound:
A form of echocardiography performed during
cardiac catheterization.
During this procedure, the transducer is threaded
into the heart blood vessels via a femoral catheter
Used to provide detailed information about the
atherosclerosis (blockage) inside the blood vessels.
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49.
50. The Modalities of Echo
The following modalities of echo are used clinically:
1 Conventional echo
Two-Dimensional echo (2-D echo)
Motion- mode echo (M-mode echo)
2 Doppler Echo
Continuous wave (CW) Doppler
Pulsed wave (PW) Doppler
Colour flow(CF) Doppler
All modalities follow the same principle of ultrasound
Differ in how reflected sound waves are collected
and analyzed
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51. TWO-DIMENSIONAL (2-
D) ECHO
This technique is used to "see“ the actual
structures and motion of the heart structures
at work.
Ultrasound is transmitted along several scan
lines(90-120), over a wide arc(about 900) and
many times per second.
The combination of reflected ultrasound
signals builds up an image on the display
screen.
A 2-D echo view appears coneshaped on the
monitor.
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52. Two-dimensional echo (2-D Echo) views:
A. Parasternal long-axis (PLAX) view
B. Apical four-chamber (A4CH) view
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53. MOTION-MODE (M-
MODE) ECHO
In the M-mode tracing, ultrasound is transmitted and received along
only one scan line.
This line is obtained by applying the cursor to the 2-D image and
aligning it perpendicular to the structure being studied. The transducer
is finely angulated until the cursor line is exactly perpendicular to the
image.
M-mode is displayed as a continuous tracing with two axes. The
vertical axis represents distance between the moving structure and the
transducer. The horizontal axis represents time.
Since only one scan line is imaged, M-mode echo provides greater
sensitivity than 2-D echo for studying the motion of moving cardiac
structures.
Motion and thickness of ventricular walls, changing size of cardiac
chambers and opening and closure of valves is better displayed on M-
mode.
Simultaneous ECG recording facilitates accurate timing of cardiac
events. Similarly, the flow pattern on color flow mapping can be timed in
relation to the cardiac cycle.
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54. Motion-mode echo (M-mode Echo) levels:
A. Mitral valve (MV) level
B. Aortic valve (AV) level
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55. Doppler
echocardiography
Doppler echocardiography is a method for detecting
the direction and velocity of moving blood within the
heart.
Pulsed Wave (PW):
useful for low velocity flow e.g. MV flow.
PW Doppler transmits ultrasound in pulses and waits
to receive the returning ultrasound after each pulse.
However, PW Doppler provides a better spectral
tracing than CW Doppler, which is used for
calculations.
PW Doppler modality is used to localize velocity
signals and
abnormal flow patterns picked up by CW Doppler and
color flow mapping, respectively.
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56. Pulsed wave (PW) Doppler signal of a stenotic aortic valve
from a single view; maximum velocity is 2 m/sec
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57. Continuous Wave (CW)
Useful for high velocity flow e.g aortic stenosis
CW Doppler transmits and receives ultrasound continuously. It
can measure high velocities without any upper limit and is not
hindered by the phenomenon of aliasing.
This Doppler modality is used for rapid scanning of the heart in
search of high velocity signals and abnormal flow patterns.
CW Doppler display forms the basis for placement of “sample
volume” to obtain PW Doppler spectral tracing.
CW Doppler is used for grading the severity of valvular stenosis
and assessing the degree of valvular regurgitation.
An intracardiac left-to-right shunt such as a ventricular septal
defect can be quantified.
By using CW Doppler signal of the tricuspid valve, pulmonary
artery pressure can be calculated.
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58. Continuous wave (CW) Doppler signal of stenotic aortic valve
from multiple views; maximum velocity is 3 m/sec
APX: apical 5 chamber view
RPS: right parasternal view
SSN: suprasternal notch
59. Color Flow (CF)
It is also known as real-time Doppler imaging.
Color Doppler provides a visual display of
blood flow within the heart, in the form of a
color flow map.
Different colors are used to designate the
direction of blood flow. Red is flow toward,
and Blue is flow away from the transducer
with turbulent flow shown as a mosaic
pattern.
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60. Color flow map of a normal mitral valve from A4CH view showing a red-colored jet
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61. Color flow map of ventricular outflow tract from A5CH view
showing a blue jet
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62. APPLICATIONS OF
COLOR DOPPLER
Stenotic Lesions:
Color Doppler can identify, localize and quantitate
stenotic lesions of the cardiac valves. It visually
displays the stenotic area and the resultant jet as
distinc from normal flow.
Regurgitant Lesions:
Color Doppler can diagnose and estimate the severity
of regurgitant lesions of the valves. It displays the
regurgitant jet as a flow-map distinct from the normal
flow pattern.
Intracardiac Shunts:
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