E.C.G. UNDERSTANDING AND INTERPRETATION
DrMalathiVenketesham
674 views
30 slides
Jul 26, 2023
Slide 1 of 30
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
About This Presentation
EASY UNDERSTANDING OF THE ECG,RATE,RHYTHM,P WAVE ETC., WITH EXAMPLES..
Slide Content
UNDERSTANDING
E.C.G
DR. K. MALATHI
M.D. SCHOLAR.
DEPT OF KAYACHIKITSA
E.C.G
DR. K. MALATHI
M.D. SCHOLAR.
DEPT OF KAYACHIKITSA
CONTENTS
INTRODUCTION
FUNDAMENTALPRINCIPLES
CONDUCTION SYSTEM OF HEART
LEADS
WHATISELECTRO CARDIOGRAM
NORMAL ECG
RHYTHM, RATE, NORMAL INTERVALS
CLINICAL INTERPRETATION
INTRODUCTION
FUNDAMENTALPRINCIPLES
CONDUCTION SYSTEM OF HEART
LEADS
WHATISELECTRO CARDIOGRAM
NORMAL ECG
RHYTHM, RATE, NORMAL INTERVALS
CLINICAL INTERPRETATION
INTRODUCTION
ELECROCARDIOGRAPHY
-
the process of
producingrecording of the heart's electrical activity
through repeated cardiac cycles.
ELECTROCARDIOGRAM -
(ECG) is a representationof
the electrical events of the cardiac cycle.
EKG –
AGerman version of the word, is a tool used to
visualize the electricity that flows through the Heart.
ELECROCARDIOGRAPHY
-
the process of
producingrecording of the heart's electrical activity
through repeated cardiac cycles.
ELECTROCARDIOGRAM -
(ECG) is a representationof
the electrical events of the cardiac cycle.
EKG –
AGerman version of the word, is a tool used to
visualize the electricity that flows through the Heart.
HISTORY
1842-Italian scientist Carlo Matteuccirealizes
that electricity is associated with the heart beat.
1924 -The noble prize for physiology or
medicine is given to William Einthoven for his
work on ECG.
1842-Italian scientist Carlo Matteuccirealizes
that electricity is associated with the heart beat.
1924 -The noble prize for physiology or
medicine is given to William Einthoven for his
work on ECG.
The importance of the ECG.
▪It is a vital test for determining –
Arrhythmias
Myocardial ischemia and infarction
Pericarditis Chamber hypertrophy
Electrolyte disturbances (i.e. hyperkalemia,
hypokalemia)
Drug toxicity
▪It is a vital test for determining –
Arrhythmias
Myocardial ischemia and infarction
Pericarditis Chamber hypertrophy
Electrolyte disturbances (i.e. hyperkalemia,
hypokalemia)
Drug toxicity
Fundamental Principles
Transmembrane ionic currents are ultimately
responsible for the potentials that are recorded as
an ECG.
An electrode senses positive potentials when an
activation front is moving toward it and negative
potentials when the activation front is moving
away from it.
Transmembrane ionic currents are ultimately
responsible for the potentials that are recorded as
an ECG.
An electrode senses positive potentials when an
activation front is moving toward it and negative
potentials when the activation front is moving
away from it.
Fundamental Principles
Contraction of any muscle is associated with
electrical changes called Depolarization.
A Phase of recovery/relaxation of any muscle
called Repolarization.
These changes can be detected by electrodes
attached to the surface of the body.
Contraction of any muscle is associated with
electrical changes called Depolarization.
A Phase of recovery/relaxation of any muscle
called Repolarization.
These changes can be detected by electrodes
attached to the surface of the body.
Conduction system of the Heart
THE SINO-ATRIAL (SA)
NODE.
THE ATRIO-VENTRICULAR
(AV) NODE.
THE BUNDLE OF HIS.
THE LEFT AND RIGHT
BUNDLE BRANCHES.
THE PURKINJE FIBRES.
THE SINO-ATRIAL (SA)
NODE.
THE ATRIO-VENTRICULAR
(AV) NODE.
THE BUNDLE OF HIS.
THE LEFT AND RIGHT
BUNDLE BRANCHES.
THE PURKINJE FIBRES.
ECG Leads
The standard ECG has 12 leads:
3 Standard Limb Leads
3 Augmented Limb Leads
6 Precordial Leads
Bipolar Leads: Two different points on the
body.
Unipolar Leads: One point on the body and
a virtual reference point with zero electrical
potential, located in the center of the heart
The standard ECG has 12 leads:
3 Standard Limb Leads
3 Augmented Limb Leads
6 Precordial Leads
Bipolar Leads: Two different points on the
body.
Unipolar Leads: One point on the body and
a virtual reference point with zero electrical
potential, located in the center of the heart
▪Limbleadsare:
▪I,II,II.
▪Eachoftheleadsarebipolar;
▪Therewillbeapositiveendatone
electrodeandnegativeattheother.
▪ThepositioningforleadsI,II,and
IIIwerefirstgivenbyEinthoven
(Einthoven’striangle).
AugmentedUnipolarleads
▪aVR,AvlandaVFareunipolar;
▪Onelimbwith‘O’reference.
▪I,II,II.
▪Eachoftheleadsarebipolar;
▪Therewillbeapositiveendatone
electrodeandnegativeattheother.
▪ThepositioningforleadsI,II,and
IIIwerefirstgivenbyEinthoven
(Einthoven’striangle).
AugmentedUnipolarleads
▪aVR,AvlandaVFareunipolar;
▪Onelimbwith‘O’reference.
Precordialleads
Theprecordialleadslieinthe
transverse(horizontal)plane,
perpendiculartotheothersixleads
.
Theprecordialleadslieinthe
transverse(horizontal)plane,
perpendiculartotheothersixleads
.
The ECG Paper
Horizontally
One small box -0.04 s
One large box -0.20 s
Vertically
One large box -0.5 mV
•Speed = 25mm/sec
•V
LimbLeads
= 10mm/mV
•V
ChestLeads
= 10mm/mV
Horizontally
One small box -0.04 s
One large box -0.20 s
Vertically
One large box -0.5 mV
•Speed = 25mm/sec
•V
LimbLeads
= 10mm/mV
•V
ChestLeads
= 10mm/mV
NORMAL ECG
P wave
QRSComplex
T wave
U wave
PR interval
PRsegment
ST segment
QTinterval
P wave
QRSComplex
T wave
U wave
PR interval
PRsegment
ST segment
QTinterval
IMPORTANT POINTS TO
READ ECG PAPER…
Standardization (calibration)
P waves
PR interval/AV conduction
QRS COMPLEX /interval
ST segments
T waves
Rhythm
Heart rate
READ ECG PAPER…
Standardization (calibration)
P waves
PR interval/AV conduction
QRS COMPLEX /interval
ST segments
T waves
Rhythm
Heart rate
P WAVE –
Represents the electrical depolarization of the atria of the
heart.
Always positive in lead I and II
Always negative in lead aVR
< 3 small squares ie0.12sec in duration
< 2.5 small squares(2.5mm) in amplitude
Tall peaked ‘Pulmonale P’ in
Right atrial enlargement,
Pulmonary hypertension
and Right ventricular failure
Represents the electrical depolarization of the atria of the
heart.
Always positive in lead I and II
Always negative in lead aVR
< 3 small squares ie0.12sec in duration
< 2.5 small squares(2.5mm) in amplitude
Tall peaked ‘Pulmonale P’ in
Right atrial enlargement,
Pulmonary hypertension
and Right ventricular failure
Right atrial enlargement-
The P waves are tall
(>2.5mm), especially in leads II, III and avF.
Left Atrial Enlargement -
Notched/bifid (‘M’ shaped)
P wave (P ‘mitrale’) in limb leads
To diagnose LAE you can use the following criteria:
II > 0.04 s between notched peaks, or
V1 Neg. deflection > 0.04 s wide x 1 mm deep
The P waves are tall
(>2.5mm), especially in leads II, III and avF.
Left Atrial Enlargement -
Notched/bifid (‘M’ shaped)
P wave (P ‘mitrale’) in limb leads
To diagnose LAE you can use the following criteria:
II > 0.04 s between notched peaks, or
V1 Neg. deflection > 0.04 s wide x 1 mm deep
PR interval-
.0.12 to 0.20 s (3 -5 small squares).
.Short PR –Wolff-Parkinson-White
.Long PR –1st Degree AV block
.means delay in AV junction, delay allows time for
the atria to contract before the ventricles contract
.0.12 to 0.20 s (3 -5 small squares).
.Short PR –Wolff-Parkinson-White
.Long PR –1st Degree AV block
.means delay in AV junction, delay allows time for
the atria to contract before the ventricles contract
QRS COMPLEX –
Normal QRS duration is o.12sec
prolongation of the QRS complex indicates
Slow ventricular depolarization
Bundlebranchblock–duration exceeds 120
sec. with incomplete blocks the QRS interval is
between 110 to 120 sec.
Hypokalaemia
Exaggerated QRS –Ventricular hypertrophy,
Hyperkaleamia
Normal QRS duration is o.12sec
prolongation of the QRS complex indicates
Slow ventricular depolarization
Bundlebranchblock–duration exceeds 120
sec. with incomplete blocks the QRS interval is
between 110 to 120 sec.
Hypokalaemia
Exaggerated QRS –Ventricular hypertrophy,
Hyperkaleamia
RIGHT BUNDLE BRANCH
BLOCK
LEFT BUNDLE BRANCH
BLOCK
The wide QRS complex
assumes a unique, virtually
diagnostic shape in those
leads overlying the right
ventricle
MARROW
The wide QRS complex
assumes a unique,
virtually diagnostic shape
in those leads overlying
the right ventricle
WILLIUM
BLOCK
LEFT BUNDLE BRANCH
BLOCK
The wide QRS complex
assumes a unique, virtually
diagnostic shape in those
leads overlying the right
ventricle
MARROW
The wide QRS complex
assumes a unique,
virtually diagnostic shape
in those leads overlying
the right ventricle
WILLIUM
QT interval
–
Beginning oftheQ wave to end of the T wave
Normal duration 0.35 –0.45 sec
Mrasuredin lead aVl.
Abnormalprolongation –Ventricular arrhythmia,
Rheumaticfever, Hypokalaemia, Hypocalcemia,Acute
myocarditis
Abnormal shortening –Hypercalcemia ,Hyperthermia
Vagal stimulation Hyperkalaemia, Digoxin therapy
–
Beginning oftheQ wave to end of the T wave
Normal duration 0.35 –0.45 sec
Mrasuredin lead aVl.
Abnormalprolongation –Ventricular arrhythmia,
Rheumaticfever, Hypokalaemia, Hypocalcemia,Acute
myocarditis
Abnormal shortening –Hypercalcemia ,Hyperthermia
Vagal stimulation Hyperkalaemia, Digoxin therapy
St segment –
ST Segment is flat (isoelectric)
Elevation or depression of ST segment by 1 mm or more is
significant.
ST Segment is flat (isoelectric)
Elevation or depression of ST segment by 1 mm or more is
significant.
T wave
–
Normal T wave is asymmetrical, first half having a gradual slope
than the second.
Abnormal T waves are symmetrical, tall, peaked, biphasic or
inverted.
•Peaked T waves
•Hyperacute T waves
•Inverted T waves
•Biphasic T waves
•‘Camel Hump’ T waves
•Flattened T waves
–
Normal T wave is asymmetrical, first half having a gradual slope
than the second.
Abnormal T waves are symmetrical, tall, peaked, biphasic or
inverted.
•Peaked T waves
•Hyperacute T waves
•Inverted T waves
•Biphasic T waves
•‘Camel Hump’ T waves
•Flattened T waves
U WAVE –
U wave related to afterdepolarizations which follow
repolarization
Following flat T wave, More prominent at slow heart rates
U wave related to afterdepolarizations which follow
repolarization
Following flat T wave, More prominent at slow heart rates
AXIS DEVIATION
▪The QRS axis represents overall direction of the heart’s
electrical activity.
▪Normal QRS axis 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)
▪QRS complex in leads I and aVF
▪Determine if they are predominantly positive or negative
▪The QRS axis represents overall direction of the heart’s
electrical activity.
▪Normal QRS axis 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)
▪QRS complex in leads I and aVF
▪Determine if they are predominantly positive or negative
Thumbs up
Romeo Juliet
REACHING towards
Thumbs down
LEAVING Away
each other
Romeo Juliet
REACHING towards
Thumbs down
LEAVING Away
each other
RHYTHM
Evaluate the rhythm strip at the bottom of the 12-lead for the
following-
Is the rhythm regular or irregular?
Is there a P wave before every QRS complex?
Sinus Rhythm
is regular with normal P, Q-R-S, T deflections
and intervals.
Sinus Bradycardia
Sinus Tachycardia
AV Heart Block
Atrial Fibrillation
Atrial Flutter
Ventricular Tachycardia
Ventricular Fibrillation
Asystole
Evaluate the rhythm strip at the bottom of the 12-lead for the
following-
Is the rhythm regular or irregular?
Is there a P wave before every QRS complex?
Sinus Rhythm
is regular with normal P, Q-R-S, T deflections
and intervals.
Sinus Bradycardia
Sinus Tachycardia
AV Heart Block
Atrial Fibrillation
Atrial Flutter
Ventricular Tachycardia
Ventricular Fibrillation
Asystole
RATE
Large square method Count the number of “big boxes”
between two QRS complexes, and divide this into 300
for regular rhythm.
Small square method Similar to above, except 1500 is
divided by the number of SMALL squares between
consecutive R waves
R wave method Number of R waves (rhythm strip) X 6
•Useful for slow and/or irregular rhythms
Large square method Count the number of “big boxes”
between two QRS complexes, and divide this into 300
for regular rhythm.
Small square method Similar to above, except 1500 is
divided by the number of SMALL squares between
consecutive R waves
R wave method Number of R waves (rhythm strip) X 6
•Useful for slow and/or irregular rhythms
Technical Errors and Artifacts
Artifacts that may interfere with interpretation can come
from movement of the patient or electrodes, electrical
disturbances related to current leakage and grounding
failure, and external sources such as electrical stimulators
or cauteries.
Misplacement of one or more electrodes is a common
cause for errors.
Significant misplacement of precordial electrodes.
Artifacts that may interfere with interpretation can come
from movement of the patient or electrodes, electrical
disturbances related to current leakage and grounding
failure, and external sources such as electrical stimulators
or cauteries.
Misplacement of one or more electrodes is a common
cause for errors.
Significant misplacement of precordial electrodes.
Dr.K.Malathi
M.D.Scholar
Dept.Ofkayachikitsa
M.D.Scholar
Dept.Ofkayachikitsa
Categories
GeneralDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 674
- Slides 30
- Favorites 2
- Age 862 days
Related Slideshows
22
Pray For The Peace Of Jerusalem and You Will Prosper
RodolfoMoralesMarcuc
32 views
26
Don_t_Waste_Your_Life_God.....powerpoint
chalobrido8
35 views
31
VILLASUR_FACTORS_TO_CONSIDER_IN_PLATING_SALAD_10-13.pdf
JaiJai148317
32 views
14
Fertility awareness methods for women in the society
Isaiah47
30 views
35
Chapter 5 Arithmetic Functions Computer Organisation and Architecture
RitikSharma297999
29 views
5
syakira bhasa inggris (1) (1).pptx.......
ourcommunity56
30 views