Basics of EKG Interpretation
Outline
The Normal Conduction System
Waveforms and Intervals
EKG Leads
Standard Limb Leads
All Limb Leads
Precordial Leads
Precordial Leads
Anatomic Groups (Summary)
Rate
Rule of 300
What is the heart rate?
What is the heart rate?
What is the heart rate?
The Rule of 300
10 Second Rule
What is the heart rate?
The QRS Axis
Determining the Axis
Determining the Axis
The Quadrant Approach
The Quadrant Approach
Quadrant Approach: Example 1
Quadrant Approach: Example 2
The Equiphasic Approach
Equiphasic Approach: Example 1
Equiphasic Approach: Example 2
Systematic Approach
Rhythms/Arrhythmias
Sinus Rhythms: Criteria/Types
Sinus Arrhythmias: Criteria/Types
Normal Sinus Rhythm
Sinus Bradycardia
Sinus Tachycardia
Sinus Arrhythmia
Atrial Arrhythmias: Criteria/Types
Atrial Arrhythmias: Criteria/Types
Premature Atrial Contraction
Ectopic Atrial Rhythm
Wandering Atrial Pacemaker
Multifocal Atrial Tachycardia
Atrial Flutter
Atrial Flutter
Atrial Fibrillation
Atrial Fibrillation
Atrial Tachycardia
Junctional Arrhythmias: Criteria
Junctional Arrhythmias: Criteria
Junctional Arrhythmias: Types
Premature Junctional Contractions
Junctional Escape Rhythm
Accelerated Junctional Tachycardia
Junctional Tachycardia
AV Nodal Reentrant Tachycardia (AVNRT)
Rate Summary
AV Nodal Blocks
1st Degree AV Block
2nd Degree AV Block Type 1
2nd Degree AV Block Type 2
3rd Degree AV Block
Another Consideration: Wolfe-Parkinson-White (WPW)
WPW
Ventricular Arrhythmias: Criteria/Types
Premature Ventricular Contraction
Idioventricular Rhythm
Accelerated Idioventricular Rhythm
Ventricular Tachycardia
Torsades de Pointes
Ventricular Tachycardia/Fibrillation
Ventricular Fibrillation
Chamber Enlargements
Left Ventricular Hypertrophy (LVH)
EKG Criteria: Diagnosis of LVH
EKG Criteria
LVH with Strain
Right Ventricular Hypertrophy
Right Ventricular Hypertrophy
Right Ventricular Hypertrophy: Causes
Right Ventricular Hypertrophy: Causes
Left Atrial Enlargement: Causes
Left Atrial Enlargement: Criteria
Lead II
P Wave: Left Atrial Enlargement
Left Atrial Enlargement Lead V1
Right Atrial Enlargement: Causes
Right Atrial Enlargement: Criteria
Right Atrial Enlargement
Bundle Branch Blocks
Bundle Branch Blocks
Left Bundle Branch Block: Causes
Criteria for Left Bundle Branch Block (LBBB)
Left Bundle Branch Block
Right Bundle Branch Block: Causes
Criteria for Right Bundle Branch Block (RBBB)
Right Bundle Branch Block
Right Bundle Branch Block
Anterior Septal with RBBB
Ischemia and Infarction
Normal Complexes and Segments
J Point
Ischemia
Measurements
ST-Segment Elevation
ST Segment Depression
EKG Changes: Ischemia → Acute Injury→ Infarction
Evolution of Transmural Infarction
Evolution of a Subendocardial Infarction
Hyperacute T waves
Q Waves
Look for Grouped Patterns (Footprints)
Anterior Septal (Left Anterior Descending)
Anterior Lateral (Left Circumflex)
Inferior (Right Coronary Artery)
ST-T Wave Changes
Strain in Hypertrophy
Strain in LVH
Strain in RVH
Strain vs Infarction
Pericarditis
Digoxin Changes
Ventricular Aneurysm
T waves
9.46M
Category: medicinemedicine

Basics of EKG Interpretation

1. Basics of EKG Interpretation

Arnold Seto, MD, MPA
Chief of Cardiology
Long Beach VA Medical Center

2. Outline

1.
2.
3.
4.
5.
Review of the conduction system
QRS breakdown
Rate
Axis
Rhythms

3. The Normal Conduction System

4. Waveforms and Intervals

5. EKG Leads

The standard EKG has 12 leads:
3 Standard Limb Leads
3 Augmented Limb Leads
6 Precordial Leads
The axis of a particular lead represents the viewpoint from
which it looks at the heart.

6. Standard Limb Leads

7. All Limb Leads

8. Precordial Leads

Adapted from: www.numed.co.uk/electrodepl.html

9. Precordial Leads

10. Anatomic Groups (Summary)

11. Rate

► Rule
► 10
of 300
Second Rule

12. Rule of 300

Take the number of “big boxes” between
neighboring QRS complexes, and divide this
into 300. The result will be approximately
equal to the rate
Although fast, this method only works for
regular rhythms.

13. What is the heart rate?

www.uptodate.com
(300 / 6) = 50 bpm

14. What is the heart rate?

www.uptodate.com
(300 / ~ 4) = ~ 75 bpm

15. What is the heart rate?

(300 / 1.5) = 200 bpm

16. The Rule of 300

It may be easiest to memorize the following table:
# of big
boxes
Rate
1
300
2
150
3
100
4
75
5
60
6
50

17. 10 Second Rule

As most EKGs record 10 seconds of rhythm per
page, one can simply count the number of beats
present on the EKG and multiply by 6 to get the
number of beats per 60 seconds.
This method works well for irregular rhythms.

18. What is the heart rate?

The Alan E. Lindsay ECG Learning Center ; http://medstat.med.utah.edu/kw/ecg/
33 x 6 = 198 bpm

19. The QRS Axis

By near-consensus, the
normal QRS axis is defined
as ranging from -30° to +90°.
-30° to -90° is referred to as a
left axis deviation (LAD)
+90° to +180° is referred to as
a right axis deviation (RAD)

20. Determining the Axis

► The
Quadrant Approach
► The
Equiphasic Approach

21. Determining the Axis

Predominantly
Positive
Predominantly
Negative
Equiphasic

22. The Quadrant Approach

1. Examine the QRS complex in leads I and aVF to determine
if they are predominantly positive or predominantly
negative. The combination should place the axis into one
of the 4 quadrants below.

23. The Quadrant Approach

2. In the event that LAD is present, examine lead II to
determine if this deviation is pathologic. If the QRS in II is
predominantly positive, the LAD is non-pathologic (in other
words, the axis is normal). If it is predominantly negative, it
is pathologic.

24. Quadrant Approach: Example 1

The Alan E. Lindsay
ECG Learning Center
http://medstat.med.utah.
edu/kw/ecg/
Negative in I, positive in aVF RAD

25. Quadrant Approach: Example 2

The Alan E. Lindsay
ECG Learning Center
http://medstat.med.utah.
edu/kw/ecg/
Positive in I, negative in aVF
Predominantly positive in II
Normal Axis (non-pathologic LAD)

26. The Equiphasic Approach

1. Determine which lead contains the most equiphasic QRS
complex. The fact that the QRS complex in this lead is
equally positive and negative indicates that the net
electrical vector (i.e. overall QRS axis) is perpendicular to
the axis of this particular lead.
2. Examine the QRS complex in whichever lead lies 90° away
from the lead identified in step 1. If the QRS complex in
this second lead is predominantly positive, than the axis of
this lead is approximately the same as the net QRS axis. If
the QRS complex is predominantly negative, than the net
QRS axis lies 180° from the axis of this lead.

27. Equiphasic Approach: Example 1

The Alan E. Lindsay ECG Learning Center ; http://medstat.med.utah.edu/kw/ecg/
Equiphasic in aVF Predominantly positive in I QRS axis ≈ 0°

28. Equiphasic Approach: Example 2

The Alan E. Lindsay ECG Learning Center ; http://medstat.med.utah.edu/kw/ecg/
Equiphasic in II Predominantly negative in aVL QRS axis ≈ +150°

29. Systematic Approach

► Rate
► Rhythm
► Axis
► Wave
Morphology
P, T, and U waves and QRS
complex
► Intervals
PR, QRS, QT
► ST Segment

30. Rhythms/Arrhythmias

► Sinus
► Atrial
► Junctional
► Ventricular

31. Sinus Rhythms: Criteria/Types

►P
waves upright in I, II, aVF
► Constant
P-P/R-R interval
► Rate
► Narrow
► P:QRS
► P-R
QRS complex
ratio 1:1
interval is normal and constant

32. Sinus Arrhythmias: Criteria/Types

► Normal
Sinus Rhythm
► Sinus
Bradycardia
► Sinus
Tachycardia
► Sinus
Arrhythmia

33. Normal Sinus Rhythm

• Rate is 60 to 100

34. Sinus Bradycardia

• Can be normal variant
• Can result from medication
• Look for underlying cause

35. Sinus Tachycardia

• May be caused by exercise, fever,
hyperthyroidism
• Look for underlying cause, slow the rate

36. Sinus Arrhythmia

• Seen in young patients
• Secondary to breathing
• Heart beats faster

37. Atrial Arrhythmias: Criteria/Types

►P
waves inverted in I, II and aVF
► Abnormal
shape
Notched
Flattened
Diphasic
► Narrow
QRS complex

38. Atrial Arrhythmias: Criteria/Types

► Premature
► Ectopic
Atrial Contractions
Atrial Rhythm
► Wandering
► Multifocal
Atrial Pacemaker
Atrial Tachycardia
► Atrial
Flutter
► Atrial
Fibrillation

39. Premature Atrial Contraction

• QRS complex narrow
• RR interval shorter than sinus QRS
complexes
• P wave shows different morphology
than sinus P wave

40. Ectopic Atrial Rhythm

• Narrow QRS complex
• P wave inverted

41. Wandering Atrial Pacemaker

• 3 different P wave morphologies
possible with ventricular rate < 100 bpm

42. Multifocal Atrial Tachycardia

• 3 different P wave morphologies
with ventricular rate> 100 bpm

43. Atrial Flutter

• Regular ventricular rate 150 bpm
• Varying ratios of F waves to QRS
complexes, most common is 4:1
• Tracing shows 2:1 conduction

44. Atrial Flutter

• Tracing shows 6:1 conduction

45. Atrial Fibrillation

• Tracing shows irregularly irregular
rhythm with no P waves
• Ventricular rate usually > 100 bpm

46. Atrial Fibrillation

• Tracing shows irregularly irregular
rhythm with no P waves
• Ventricular rate is 40

47. Atrial Tachycardia

• Tracing shows regular ventricular rate
with P waves that are different from sinus
P waves
• Ventricular rate is usually 150 to 250 bpm

48. Junctional Arrhythmias: Criteria

AV Nodal Blocks
• Delay conduction of impulses from
sinus node
• If AV node does not let impulse
through, no QRS complex is seen
• AV nodal block classes:
1st, 2nd, 3rd degree

49. Junctional Arrhythmias: Criteria

1st Degree AV Block
• PR interval constant
• >.2 sec
• All impulses conducted

50. Junctional Arrhythmias: Types

nd
2
Degree AV Block Type 1
• AV node conducted each impulse
slower and finally no impulse is
conducted
• Longer PR interval, finally no QRS
complex

51. Premature Junctional Contractions

nd
2
Degree AV Block Type 2
• Constant PR interval
• AV node intermittently conducts
no impulse

52. Junctional Escape Rhythm

rd
3
Degree AV Block
• AV node conducts no impulse
• Atria and ventricles beat at intrinsic
rate (80 and 40 respectively)
• No association between P waves and
QRS complexes

53. Accelerated Junctional Tachycardia

Another Consideration:
Wolfe-Parkinson-White (WPW)
• Caused by bypass
tract
• AV node is bypassed,
delay
• EKG shows short PR
interval <.11 sec
• Upsloping to QRS
complex (delta wave)

54. Junctional Tachycardia

WPW
• Delta wave, short PR interval

55. AV Nodal Reentrant Tachycardia (AVNRT)

Ventricular Arrhythmias:
Criteria/Types
► Wide
QRS
complex
► Rate
:
variable
► No
P waves
► Premature
Ventricular
Contractions
► Idioventricular
► Accelerated
Rhythm
IVR
► Ventricular
Tachycardia
► Ventricular
Fibrillation

56. Rate Summary

Premature Ventricular Contraction
• Occurs earlier than sinus beat
• Wide, no P wave

57. AV Nodal Blocks

Idioventricular Rhythm
• Escape rhythm
• Rate is 20 to 40 bpm

58. 1st Degree AV Block

Accelerated Idioventricular Rhythm
• Rate is 40 to 100 bpm

59. 2nd Degree AV Block Type 1

Ventricular Tachycardia
• Rate is > than 100 bpm

60. 2nd Degree AV Block Type 2

Torsades de Pointes
• Occurs secondary to prolonged
QT interval

61. 3rd Degree AV Block

Ventricular Tachycardia/Fibrillation
• Unorganized activity of ventricle

62. Another Consideration: Wolfe-Parkinson-White (WPW)

Ventricular Fibrillation

63. WPW

Chamber Enlargements

64. Ventricular Arrhythmias: Criteria/Types

Left Ventricular Hypertrophy (LVH)
► Differential
Diagnosis
Hypertension (HTN)
Aortis Stenosis (AS)
Aortic Insufficiency (AI)
Hypertrophic Cardiomyopathy (HCM)
Mitral Regurgitation (MR)
Coarctation of the Aorta (COA)
Physiologic

65. Premature Ventricular Contraction

Left Ventricular Hypertrophy (LVH)
► False
positive
Thin chest wall
Status post mastectomy
Race, Sex, Age
Left Bundle Branch Block (LBBB)
Acute MI
Left Anterior Fascicular Block
Incorrect standardization

66. Idioventricular Rhythm

EKG Criteria: Diagnosis of LVH

67. Accelerated Idioventricular Rhythm

LVH with Strain

68. Ventricular Tachycardia

Right Ventricular Hypertrophy
► Reversal
of precordial pattern
R waves prominent in V1 and V2
S waves smaller in V1 and V2
S waves become prominent in V5
V6
and

69. Torsades de Pointes

Right Ventricular Hypertrophy

70. Ventricular Tachycardia/Fibrillation

Right Ventricular Hypertrophy:
Causes
► Chronic
Obstructive Pulmonary Disease
► Pulmonary HTN
Primary
► Pulmonary Embolus
► Mitral Stenosis
► Mitral Regurgitation
► Chronic LV failure

71. Ventricular Fibrillation

Right Ventricular Hypertrophy:
Causes
► Tricuspid
► Atrial
Regurgitation
Septal Defect
► Pulmonary
► Tetralogy
Stenosis
of Fallot
► Ventricular
Septal Defect

72. Chamber Enlargements

Left Atrial Enlargement: Causes
► Mitral
Stenosis
► Mitral
Regurgitation
► Left
ventricular hypertrophy
► Hypertension
► Aortic
Stenosis
► Aortic
Insufficiency
► Hypertrophic
Cardiomyopathy

73. Left Ventricular Hypertrophy (LVH)

Left Atrial Enlargement: Criteria
►P
wave
► Notch
in P wave
Any lead
Peaks > 0.04 secs
► V1
Terminal portion of P wave > 1mm deep
and > 0.04 sec wide

74.

Lead II

75. EKG Criteria: Diagnosis of LVH

P Wave: Left Atrial Enlargement

76. EKG Criteria

Left Atrial Enlargement
Lead V1

77. LVH with Strain

Right Atrial Enlargement: Causes
► CHD
Tricuspid Stenosis
Pulmonary Stenosis
► COPD
► Pulmonary
HTN
► Pulmonary
Embolus
► Mitral
Regurgitation
► Mitral
Stenosis

78. Right Ventricular Hypertrophy

Right Atrial Enlargement: Criteria
► Tall,
peaked P wave
> 2.5 mm in any lead
► Most
prominent P waves in leads I, II
and aVF

79. Right Ventricular Hypertrophy

Right Atrial Enlargement

80. Right Ventricular Hypertrophy: Causes

Bundle Branch Blocks

81. Right Ventricular Hypertrophy: Causes

Bundle Branch Blocks
► Left
Complete
Incomplete
► Right
Complete
Incomplete
► Complete
QRS > .12 secs
► Incomplete
QRS .10 - .12 secs

82. Left Atrial Enlargement: Causes

Left Bundle Branch Block: Causes
► Normal
variant
► Idiopathic
degeneration of the
conduction system
► Cardiomyopathy
► Ischemic
► Aortic
heart disease
Stenosis
► Hyperkalemia
► Left
Ventricular Hypertrophy

83. Left Atrial Enlargement: Criteria

Criteria for Left Bundle Branch
Block (LBBB)
► Bizarre
QRS Morphology
High voltage S wave in V1, V2 & V3
Tall R wave in leads I, aVL and V5-6
► Often LAD
► QRS Interval
► ST depression in leads I, aVL, & V5-V6
► T wave inversion in I, aVL, & V5-V6

84. Lead II

Left Bundle Branch Block

85. P Wave: Left Atrial Enlargement

Right Bundle Branch Block:
Causes
► Idiopathic
degeneration of the
conduction system
► Ischemic heart disease
► Cardiomyopathy
► Massive Pulmonary Embolus
► Ventricular Hypertrophy
► Normal Variant

86. Left Atrial Enlargement Lead V1

Criteria for Right Bundle
Branch Block (RBBB)
► QRS
morphology
Wide S wave in leads I and V4-V6
RSR’ pattern in leads V1, V2 and V3
► QRS duration
► ST depression in leads V1 and V2
► T wave inversion in leads V1 and V2

87. Right Atrial Enlargement: Causes

Right Bundle Branch Block

88. Right Atrial Enlargement: Criteria

Right Bundle Branch Block

89. Right Atrial Enlargement

Anterior Septal with RBBB

90. Bundle Branch Blocks

Ischemia and Infarction

91. Bundle Branch Blocks

Normal Complexes and Segments

92. Left Bundle Branch Block: Causes

J Point

93. Criteria for Left Bundle Branch Block (LBBB)

Ischemia
•T wave inversion, ST segment depression
•Acute injury: ST segment elevation
•Dead tissue: Q wave

94. Left Bundle Branch Block

Measurements

95. Right Bundle Branch Block: Causes

ST-Segment Elevation

96. Criteria for Right Bundle Branch Block (RBBB)

ST Segment Depression
Can be characterised as:► Downsloping
► Upsloping
► Horizontal

97. Right Bundle Branch Block

EKG Changes: Ischemia →
Acute Injury→ Infarction

98. Right Bundle Branch Block

Evolution of Transmural
Infarction

99. Anterior Septal with RBBB

100. Ischemia and Infarction

Evolution of a Subendocardial
Infarction

101. Normal Complexes and Segments

102. J Point

Hyperacute T waves

103. Ischemia

Q Waves
Non Pathological Q waves
Q waves of less than 2mm are normal
Pathological Q waves
Q waves of more than 2mm
indicate full thickness myocardial
damage from an infarct
Late sign of MI (evolved)

104. Measurements

Look for Grouped Patterns
(Footprints)
► ST
Depressions = Ischemia
► ST
Elevations = injury
►Q
Waves & T Wave Inversion = Infarction

105. ST-Segment Elevation

Anterior Septal (Left Anterior
Descending)

106. ST Segment Depression

Anterior Lateral (Left Circumflex)

107. EKG Changes: Ischemia → Acute Injury→ Infarction

Inferior (Right Coronary Artery)

108. Evolution of Transmural Infarction

109.

110. Evolution of a Subendocardial Infarction

111.

112. Hyperacute T waves

113. Q Waves

114. Look for Grouped Patterns (Footprints)

ST-T Wave Changes

115. Anterior Septal (Left Anterior Descending)

Strain in Hypertrophy

116. Anterior Lateral (Left Circumflex)

Strain in LVH

117. Inferior (Right Coronary Artery)

Strain in RVH

118.

Strain vs Infarction

119.

Pericarditis

120.

Digoxin Changes

121.

Ventricular Aneurysm

122.

T waves

123.

Summary
► Basic
physiology of the conduction
system
► Origin
of a normal EKG
► Systematic
► Major
EKG
approach to reading an EKG
abnormalities when reading an
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