2. INTRODUCTION
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.
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3. COMPONENTS
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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4. INDICATION
Cardiac chamber size and contents
Ejection fraction
Pericardial sac i.e. pericardial effusion, constrictive pericarditis
Ascending aorta assessment of known or suspected adult congenital heart diease.
Evaluation of suspected complication of myocardial ischemia/infarction.
Evaluation of valvular or structural heart disease.
Infective endocarditis
Suspected tumor or thrombus
Cardiomyopathy : dilated, restrictive, and hypertrophic
Pulmonary hypertension
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5. PROCEDURE
A standard echocardiogram is also known as a
transthoracic echocardiogram (TTE), or cardiac
ultrasound.
The subject is asked to lie in the semi recumbent position
on his or her left side with the head elevated.
Ultrasound is transmitted from a transducer having a frequency
of 2.5 to 3.5 MHz for echo in adults.
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
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6. WINDOWS OF ECHO
Evaluation of the heart with
echocardiography requires
"acoustic windows" of the heart.
Bone reflects the ultrasound waves
and so all structures directly behind
bone are not visible with ultrasound.
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7. Parasternal Long-Axis View
(PLAX)
Transducer position: left sternal
edge; 2nd – 4th intercostal space
Marker dot direction: points
towards right shoulder
Most echo studies begin with this
view
It sets the stage for subsequent
echo views
Many structures seen from this
view
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8. Measurements in PLAX view can be used to quantify the
heart:
Left ventricular size and wall thickness
Left atrial linear dimension (as opposed to area)
Left ventricular outflow tract diameter (used to
calculate aortic valve area by the continuity equation)
Aortic annulus, sinus of Valsalva, and aortic root
sizes
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9. Parasternal Short Axis View
(PSAX)
Transducer position: left sternal edge;
2nd – 4th intercostal space.
Marker dot direction: points towards left
shoulder(90˚ clockwise from PLAX view)
By tilting transducer on an axis between
the left hip and right shoulder, short axis
views are obtained at different levels,
from the aorta to the LV apex.
The aortic valve, right ventricular inflow
& outflow tracts visible with the tricuspid
valve
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10. Papillary Muscle (PM)level
•PSAX at the level of the
papillary muscles showing how
the respective LV segments are
identified, usually for the
purposes of describing
abnormal LV wall motion
• LV wall thickness can also be
assessed
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11. Apical 4-Chamber View (AP4CH)
• Transducer position: apex of
heart
• Marker dot direction: points
towards left shoulder
• The AP5CH view is obtained from
this view by slight anterior
angulation of the transducer
towards the chest wall.
• The LVOT can then be visualised
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12. Apical 2-Chamber View (AP2CH)
• Transducer position: apex of the
heart
• Marker dot direction: points
towards left side of neck (45˚
anticlockwise from AP4CH view)
• Good for assessment of LV
anterior wall and LV inferior wall
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13. Sub–Costal 4 Chamber View(SC4CH)
• Transducer position: under the
xiphisternum
• Marker dot position: points
towards left shoulder
• The subject lies supine with head
slightly low (no pillow). With feet
on the bed, the knees are slightly
elevated
• Better images are obtained with
the abdomen relaxed and during
inspiration
• Interatrial septum, pericardial
effusion, desc abdominal aorta
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14. Suprasternal View
• Transducer position: suprasternal
notch
• Marker dot direction: points towards
left jaw
• The subject lies supine with the neck
hyperextended. 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
• Arch of aorta,ascending
aorta,pulmonary artery
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15. TYPES OF ECHOCARDIOGRAPHY
Transthoracic echocardiography
Transesophageal echocardiography
Stress echocardiography
Three-dimensional echocardiography
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16. TRANSESOPHAGEAL ECHOCARDIOGRAPHY
• The oesophagus in its mid-course is 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.
• The transducer to be inserted down the throat into the esophagus (the
swallowing tube that connects the mouth to the stomach).
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18. Advantages of TEE
Useful alternative to transthoracic echo in case of 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
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19. Useful supplement to transthoracic echo, which
cannot examine the posterior aspect of the heart.
Structures such as left atrial appendage, descending
aorta and pulmonary veins can only be visualized by
TEE.
very high sensitivity for locating a blood clot inside
the left atrium.
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20. Disadvantages
It takes longer to perform a TEE than a TTE.
It may be uncomfortable for the patient.
It requires short-term sedation, oxygen
administration and ECG monitoring since, there are
chances of hypoxia, arrhythmia and angina.
TEE images require a comprehensive understanding
of the spatial relationship between cardiac structures.
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21. 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 basic of echocardiography by dr.himanshu 21
22. Contraindications to TEE
Unrepaired tracheoesophageal fistula
History prior esophageal surgery
Esophageal obstruction or stricture
Perforated hollow viscus
Gastric or esophageal bleeding
Poor airway control
Severe respiratory depression
Oropharyngeal pathology
Uncooperative, unsedated patient
Severe coagulopathy
Cervical spine injury
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23. STRESS ECHOCARDIOGRAM
A stress test accompanied by echocardiography.
During a stress.echo, patient exercise on a treadmill or statio
nary bike with blood pressure and heart rhythm monitoring.
The echocardiography is performed both before and after the
exercise to compare structural differences.
To assess for any abnormalities in wall motion of the heart.
This is used to detect obstructive coronary artery disease
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24. Technique:
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.
Do not take the following heart medications for 24 hour before the
test unless doctor tells.
*Beta-blockers * Isosorbide dinitrate
*Isosorbide mononitrate *Nitroglycerin
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26. DOBUTAMINE STRESS ECHOCARDIOGRAM
A form of stress echocardiogram.
The test is used to evaluate heart and valve function when
unable to exercise on a treadmill or stationary bike.
Most dobutamine stress protocols start at an infusion rate
of 5 ug/kg/min 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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27. 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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29. 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.
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.
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30. 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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31. Motion-mode echo (M-mode Echo) levels:
A. Mitral valve (MV) level
B. Aortic valve (AV) level
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32. 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.
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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33. Continuous Wave (CW)
Useful for high velocity flow e.g aortic stenosis
CW Doppler transmits and receives ultrasound continuously
This Doppler modality is used for rapid scanning of the heart in
search of high velocity signals and abnormal flow patterns.
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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34. 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. (BART)
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35. Color flow map of a normal mitral valve from A4CH view
showing a red-colored jet
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36. Color flow map of ventricular outflow tract from A5CH view
showing a blue jet
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37. 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 distinct
from normal flow.
Regurgitant Lesions:
Color Doppler can diagnose and estimate the severity of regurgitant
lesions of the valves
Intercardiac shunts
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38. THREE DIMENSION ECHO
Future direction in echo
Obviates the need for cognitive 3 D construction of 2
D image plane
Useful in:-
1. ventricular volume assessment
2. Study of asymmetrical stenotic valve
3. Complex structural relationships in congenital
heart disease .
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39. MYOCARDIAL CONTRAST ECHO
Application of ultrasonic
contrast agent, to accurately
delineate areas of reduced
myocardial blood flow or
perfusion defect related to
coronary occlusion
Contrast exist as microbubbles
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40. Echo findings in Heart
diseases
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41. DIALATED CARDIOMYOPATHY
The ventricles are dilated more
than the normal.
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42. HYPERTROPHIC CARDIOMYOPATHY
• The intra ventricular
septum appears thickened
• IVS:LVPW ratio >1.5
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43. RESTRICTIVE CARDIOMYOPATHY
• Thick and bright septum
• Reduced size of ventricles
• Dilated RA and LA
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47. MITRAL STENOSIS
• Thickening of valve leaflets
• Restricted opening of valve
• Dilatation of left atrium
• Diastolic doming of anterior
leaflets
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48. MITRAL REGURGITATION
• Regurgitant jet in LA on
A4CH view.
• Extent of MR jet fills the LA
Cavity indicates severity of
MR.
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