Cardiology Dysrhythmias and Basic ECGs PDF

Summary

This is a presentation on the topic of cardiology, dysrhythmias and basic ECGs. It covers various aspects of ECG including learning outcomes, what ECG measures, intervals, waves, conduction blocks, and anti-arrhythmic mechanisms. The presentation also includes pre-assessment questions which aid in understanding the basic concepts needed.

Full Transcript

Cardiology: Dysrhythmias
and Basic ECG’s

BMS200

Week 9
Learning Outcomes
Analyze the following characteristics of a normal ECG:
Heart rate and determination of rhythm
P-R, QRS, Q-T intervals
Normal waveforms in the P, QRS, and T waves
Describe how triggered activity, abnormal automaticity, and re-entry
contribute to the pathophysiology of the most common dysrhythmias
Describe the basic epidemiology, pathogenesis, clinical features, ECG
findings, and prognosis of the following supraventricular dysrhythmias:
Atrial fibrillation, atrial flutter, sinus tachycardia, and paroxysmal
supraventricular tachycardia
Learning Outcomes
Describe the basic epidemiology, pathogenesis, clinical features, ECG
findings, and prognosis of the following ventricular dysrhythmias:
Premature ventricular contraction, idioventricular rhythm, ventricular
tachycardia, ventricular fibrillation, torsades de pointes
Describe the basic epidemiology, pathogenesis, clinical features, ECG
findings, and prognosis of the following types of conduction block:
1st degree heart block, 2nd degree heart block, 3rd degree heart block
Describe the ECG findings that are typical of cardiac ischemia and relate
these findings to basic vascular territories
Briefly describe the pharmacologic mechanism of action and related
adverse effects of common anti-arrhythmic medications
Discuss the pathophysiologic contribution of chronic inflammation and
myocardial fibrosis to the development of common dysrhythmias
What do you think is happening? Did you
“catch” a serious dysrhythmia in your
colleague?
You’ve just purchased a brand-new electronic stethoscope that
records heart sounds and can transmit a simple two-lead ECG to
your smartphone. The audio is great when you test it on yourself,
but the appearance of the ECG seems to change drastically
depending on where you place it on your chest.
Your classmate asks
you to try it out on
them – you record
the following trace
when the device
is placed on
their chest:
Pre-Assessment: What electrical event is
occurring during the Q-T interval of an ECG?

A. The plateau phase of the atrial myocyte action potential
B. The initial depolarization of the atrial myocyte
C. The plateau phase of the ventricular myocyte action
potential
D. Repolarization of the ventricular myocyte
Pre-Assessment: Where in the heart would you find
the cells that usually perform the role of the cardiac
pacemaker?

A. The right atrium, close to the entrance of the superior
vena cava
B. The left atrium, close to the entrance of the right
pulmonary veins
C. Close to where the tricuspid valve attaches next to the
interventricular septum
D. Close to where the mitral valve attaches next to the
interventricular septum
Review: Electrocardiogram (ECG)
Recording of Electrical Impulses: An electrocardiogram (ECG or
EKG) captures electrical activities produced by the heart by placing
electrodes on the skin, which detect the voltage changes resulting
from the depolarization and repolarization of the cardiac muscle.
Size of the Waves: The amplitude of the waves on an ECG
represents the amount of electrical activity occurring in the heart
muscle.
Larger waves indicate greater amounts of electrical activity,
which typically correspond to larger areas of myocardial tissue
being activated.
This can give insights into the health and functionality of the
heart
Review: Electrocardiogram (ECG)
Direction of Voltage Changes: The upward or downward deflections from
the baseline reflect the direction of electrical conduction through the heart.
An upward deflection indicates that the electrical impulse is moving
toward the electrode
a downward deflection suggests that it is moving away.
This is crucial for understanding how different parts of the heart are
activating
Conducting/Automatic Tissues: The conducting tissues (like the SA node, AV
node, and bundle branches) are smaller and generate less electrical activity
than the myocardial tissues, which makes them difficult to register on an
ECG.
The ECG primarily reflects the activity of the larger myocardial cells
that contract and pump blood.
Review: Electrocardiogram (ECG)
Duration of the Waves: The duration of the waves (P
wave, QRS complex, T wave) provides important
information about the timing of electrical events in
the heart.
For example, a prolonged QRS complex may
indicate a delay in ventricular conduction
a prolonged QT interval could suggest a risk of
arrhythmias.
Monitoring the duration of these waves is
essential for assessing cardiac health and function.
Review: What does ECG measure?
ECG leads measure the
extracellular current that travels
from depolarized cells to polarized
(resting) cells
Differences in charge at the
extracellular border of the plasma
membrane
ECG leads only “notice” changes
in membrane potential
“plateaus” do not register as waves
(i.e. phase 4, phase 2 of a myocyte)
Technically, they compare the
difference in voltage between
different regions of the heart
Review: ECG Timing
How do the ECG waves
and intervals correspond
to the excitation along
the conduction pathway?
Recall Cardiac
Physiology lecture and
the role of the AV delay:
Allowing time for
atrial contraction and
optimizing ventricular
filling
 ECG: Amplitude and Vectors
Amplitude:
The amplitude refers to the height of
the waves seen on the ECG. It
indicates the magnitude of the
electrical potential difference across
different parts of the heart.

Length of vector:
The length of the vector corresponds
to the magnitude of the electrical
potential difference (size of
difference) between two points in
the heart during depolarization or
repolarization.
The direction of the vector indicates
the orientation of the electrical
activity (which way the electrical
impulse is traveling).
Placement of ECG Leads - 1
ECG leads are placed to give
a “3-D” view of the
electrical activity of the
heart
Coronal view (left and
right arms, left leg)
Cross-sectional view
(precordial leads)
The vector of depolarization
is displayed relative to the
placement of the ECG lead
Placement of ECG Leads - 2
Bipolar leads compare
voltage changes between
leads. i.e.,
lead I compares voltage
changes between the right
arm and the left arm
“Unipolar” (precordial
leads) leads compare
voltage changes between
a lead (surface of chest
wall) and the center of the
heart
ECG: X and Y axis
Electrical potential changes
across the heart over time
Time – x-axis, in seconds
Electrical potential
changes – voltage in mV,
y-axis

“little box” – 0.1 mV
high, and 0.04 seconds
wide
Each “big box” is 0.5 mV
by 0.2 seconds
Approach to Interpreting ECG
Best to approach them in an organized fashion:
1. Determine rate (Step 1)
Two methods:
Divide 300 by number of large boxes between R-waves (R-R
interval) = rate
5 large boxes = 1 second, 50 large boxes = 10 seconds, so #
of R waves in 50 large boxes X 6 (60 seconds in 1 minute)
(somewhat cumbersome)
2. Determine rhythm (Step 2)
Where are the impulses coming from (P-wave before the QRS, or
something else going on)?
Is it regular? If irregular, is it regularly irregular, or irregularly irregular?
Is it a sinus rhythm? (what is a sinus rhythm?)
Step 2 – Rhythm Normal Sinus Rhythm?
Regular rhythm or
Best determined by looking at a rhythm strip regularly irregular
Usually lead II, often a 10-second recording (50 rhythm
big boxes) Each P-wave is followed
Regular or irregular? by a QRS
regular – can be a normal finding, artificial FYI - P-wave has a
pacemakers can give a regular rhythm as well normal axis and is
irregular – irregularly irregular or regularly the same shape
irregular? each beat
regularly irregular can be normal, as PR interval is constant
heart rate varies with respiration – there QRS interval is < 100 ms
is a pattern to the irregular rhythm (2.5 small boxes)
irregularly irregular is the hallmark of a Each QRS has a P-wave
number of tachycardias, most commonly before it
atrial fibrillation and is abnormal
Normal sinus rhythm =
pacemaker is the SA
node, no abnormalities
of conduction
A Normal 12-Lead ECG

Rhythm
strip
Step 3 – Intervals (1)
3. Look at the intervals
Are they widened or shortened?
Often a change in an interval is a result of a conduction
system problem
Major intervals of interest:
P-R interval – usually prolongation = AV-nodal
dysfunction
It can be decreased, though in situations where there are
abnormal “connections” between the atria and ventricles
QRS interval – delay in ventricular excitation
QT interval – repolarization abnormalities (as a risk factor
for torsades de pointes)
We consider S-T intervals in the “waves” portion
Step 3 – Intervals (2)
The intervals can often tell you much about where the conduction
problem lies
narrow QRS = usually normal intraventricular conduction pathways
normal QT = normal ventricular repolarization
normal P-R = no abnormal delays/conduction at the AV node
QT varies with
Interval Seconds Small boxes heart rate… so how
do you figure out a
P-R (P-Q) 0.12 – 0.2 3-5 normal QT??
QT corrected =
QRS 0.08 – 0.10 2 – 2.5 QT___
QT QTc = QT/√R-R Less than half of R- √R-R
R usually good QT interval
divided by
square root of
R-R interval
Step 4 – Waves
4. Look at the waves
Are they positioned normally (up or down)?
Are they “funny-shaped” or do they change morphology
from beat to beat?
Are the waves larger/smaller than normal?
Are there waves present that normally aren’t present in
a healthy person?
NOTE: when examining the waves, it is important to look at
them in all leads – they will change from lead to lead
Step 4 – Q-Waves
Abnormal Q-waves – if these abnormalities are
seen, indicates current or prior MI:
“significant” Q-waves are:
wide (> 1 small box or 0.04 sec)
large (> 2 mm deep or > 25% of the total size of the QRS)
or > 1/3 height of the R wave
in leads V1 – V3 are abnormal, always
Since MI is so common, it is key to recognize these
Step 4 – ST
segments
Helps to think about ST segment with waves
instead of intervals
usually with intervals you’re thinking about times
that are shorter or longer than normal
with the ST segment you’re concerned about
elevation or depression
Your biggest concern is ruling out an infarct, but
many things can cause ST depression or elevation
ST Depression and ST Elevation

S-T depression S-T elevation

NSTEMI or opposite STEMI or opposite
lead from site of lead from site of
STEMI NSTEMI
digoxin pericarditis
hypokalemia LBBB
RBBB or LBBB LVH
RVH or LVH normal if small
implanted implanted
pacemaker pacemaker
Raised ICP hyperkalemia
(intracranial PE
pressure) Raised ICP
Step 4 – T-Waves
T-waves – many abnormalities can The differential for T-wave
occur, but they should be upright in changes is large, and depends
all of the leads except for V1 on a few things:
Some basic abnormalities age – T-wave inversions
are normal in kids
tall T-waves
hyperkalemia ischemia and “metabolic”
strain – i.e. the heart is
early myocardial infarction
working hard with not
small T-waves enough to “feed” it
hypokalemia electrolyte abnormalities
Inverted T-waves what pattern of leads the
myocardial infarction T-wave findings appear in
ventricular hypertrophy (i.e. does it correspond to
a vascular territory)?
Step 4 – P-Waves
P-wave abnormalities
P-wave shapes that change from
beat-to-beat (indicates the
“pacemaker” is not the same each
beat)
P-wave absence – think atrial
fibrillation FYI - Atria enlarge for the
More P-waves than QRS complexes same reason other heart
– heart block chambers enlarge
FYI: P-waves that indicate atrial Increased atrial “afterload”
hypertrophy
see diagram for right and left atrial i.e., a stenotic AV valve
hypertrophy patterns Atria are “stretched” by
many ECGs will also determine an more fluid than usual
atrial axis – between 0 and +75 failure of the ventricle
degrees
General Pathophysiology of
Dysrhythmias (1)
Re-entry:
Normal depolarization wave enters a pathological space
in the heart (i.e., area of ischemic injury), contraction
cannot occur because the tissue is not functioning
properly BUT it may allow a slower conduction of this
wave towards healthy tissue
IF healthy cardiac tissue have completed their original
refractory period, then this wave of depolarization can
trigger an action potential called “re-entry” and resulting
in tachycardia
(1) conditions that slow conduction but not block
(2) conditions that shorten refractory period of healthy cells
General Pathophysiology of
Dysrhythmias (2)
Ectopic Foci or Abnormal Automaticity:
Scar tissue (i.e., post-MI or other injury) changes local plasma
electrolyte concentrations or their movements across channels
resulting occurrence of automaticity in previously non-
pacemaker cells – ectopic foci
Inhibition of Na+/K+ pump results in intracellular accumulation of
Na+ and Ca2+ which partially depolarize the membrane
Can occur in healthy individuals occasionally
Situations that promote abnormal automaticity:
(1) Increase of intracellular Ca2+
(2) Decrease of K+ conductance at rest
Catecholamines (fatigue, stress), hyperkalemia, hypercalcemia,
heart distention
General Pathophysiology of
Dysrhythmias (2)
Ectopic Foci or Abnormal Automaticity:
Cardiac Metabolism:
IR K+ channels get inactivated by intracellular ATP (when
metabolism is ok, no extra K+ is effluxing from the
myocyte) and get activated by intracellular ADP (when the
cardiac myocyte is metabolically stressed i.e., ischemia)
allowing K+ to efflux and thus reducing the refractory
period
General Pathophysiology of
Dysrhythmias (3)
Triggered Activity:
Ventricular arrhythmia, whereby a normal action
potential is followed by an abnormal depolarization of
ventricular muscle that occurs before the original action
potential has completed its course
Example: premature ventricular contractions (PVC)
Conditions that favor this:
Situations that prolong action potential duration
Bradycardia and reduced or prolonged phase 3 (K+ efflux/
repolarization)
Tachycardia and increased calcium accumulation within
myocyte
Chronic Inflammation and Myocardial
Fibrosis and Dysrhythmias
Chronic inflammation
Immune cells (macrophages, mast cells, T-cells) can promote
myocardial repair (as in acute inflammation) OR fibrosis by releasing
cytokines that direct function of cardiac fibroblasts
Cardiac fibroblasts are triggered to transform into
myofibroblasts
This transformation is supported by fibrosis-promoting factors:
angiotensin II, aldosterone, catecholamines, connective tissue growth
factor, endothelin, platelet-derived growth factor, reactive oxygen
species, TGF-Beta and inflammatory cytokines
Myofibroblasts produce more ECM and secrete substances that
promote fibrosis
Myocardial fibrosis leads to remodeling of myocardial collagen
May cause local delay in portion of the heart
Promotes reentry
Supraventricular Dysrhythmias
Atrial fibrillation
Most common type of arrhythmia
Risk Factors: age, hypertension, chronic lung or heart disease,
congenital heart disease, increased alcohol, sleep apnea
Pathophysiology: atrial structural (ECM, fibrous tissue
deposition) and electrical (tachycardia, shortening of refractory
period) remodeling leading to ectopic foci
Once fibrillation occurs ! (1) turbulent blood flow (2) reduced
effectiveness of heart’s function (3) risk increased thrombus
formation
Sx: asymptomatic OR chest pain, palpitations, dyspnea,
tachycardia, nausea, dizziness, diaphoresis, fatigue
ECG: narrow complex “irregular irregular” pattern with no
distinguishable p-wave
Prognosis: leading cardiac cause of stroke
Atrial Fibrillation ECG 1
Narrow complex “irregular irregular” pattern with
no distinguishable p-wave
Atrial Fibrillation ECG 2
Narrow complex “irregular irregular” pattern with
no distinguishable p-wave
Supraventricular Dysrhythmias
Atrial flutter
VERY common
Pathophysiology: re-entry mechanism due to fibrosis
(1) Different refractory period
(2) Fast and slow conductions – together these allow for re-
entry
ECG: Fast atrial rate (300 bpm) with fixed or variable
ventricular rate
Flutter waves without an isoelectric line in between QRS
complex
SX: fatigue,
palpitations,
syncope
Supraventricular Dysrhythmias
Sinus tachycardia
Normal rhythm, heart beats faster and results in increased
cardiac output
Often due to exercise or stress; concerning when occurs
at rest
Physiological (normal): catecholamines due to exercise,
stress, pain, or anxiety
Pathological (concerning)
Cardiac causes include myocarditis, coronary artery
syndrome and others
Non-cardiac: pulmonary embolism, hypoxia, hypoglycemia,
dehydration, infection, electrolyte imbalance, shock and
others
Supraventricular Dysrhythmias
Paroxysmal supraventricular tachycardia (SVT)
Intermittent (paroxysmal) episodes of supraventricular
tachycardia with sudden onset and termination
Originate either in the atria or AV node and can create either
regular or irregular rhythms
MANY Etiologies: hyperthyroidism, caffeine, cocaine, structural
heart disease, rheumatic dz, PE, pneumonia, anxiety, MVP,
myocarditis, pericarditis…
Pathophysiology: most often re-entry, sometimes due to
increased automaticity or trigger
Re-entry circuits: SA node, atria, AV node or accessory pathway
SX: dizziness, syncope, nausea, dyspnea, palpitations, neck pain,
chest discomfort, anxiety, diaphoresis
Prognosis: good if no structural problems, otherwise can lead to
heart failure, MI or pulmonary edema
Paroxysmal supraventricular
tachycardia (SVT) – ECG

ECG:
Regular rhythm
Fast heart rate (150-250 bpm)
Often narrow QRS complex
Ventricular Dysrhythmias
Premature ventricular contraction (PVC’s)
Heartbeat is initiated by Purkinje fibers
Can occur in isolation or as a double (Normal beat (QRS) – PVC – PVC –
Normal beat (QRS).) or triplet (Normal beat (QRS) – PVC – PVC – PVC -
Normal beat (QRS).)
More than three PVC’s are termed ventricular tachycardia
Common (FYI 1-4% of population)
Etiology: often unknown, caffeine, excess catecholamines, anxiety,
electrolyte imbalance, alcohol, sleep deprivation, structural heart
disease, anemia, hyperthyroidism
Pathophysiology:
Ectopic nodal automaticity
Re-entry
Triggered activity
Ventricular Dysrhythmias
Premature ventricular contraction (PVC’s)
SX:
“Skipped heartbeat” followed by fluttering sensation
(palpitation), though majority are asymptomatic
Lightheadedness, chest pain, chest discomfort, dyspnea, anxiety
(syncope very rare)
Prognosis: if no heart disease – no problem, if heart disease
than increased mortality risk
ECG: abnormal and wide QRS complex occurring earlier than
expected in cardiac cycle
Ventricular Dysrhythmias
Idioventricular rhythm
Slow regular ventricular rhythm with a rate of less than 50 bpm
(typically), absence of P waves, and a prolonged QRS interval –
the SA node isn’t working, and the ventricle takes over!
Etiology: heart block, electrolyte abnormalities, medications,
during reperfusion after MI
Pathophysiology:
Suppression of SA and AV nodes that allow ventricles to take over
and generate rhythm (50 bpm)
SX: mostly asymptomatic OR palpitations, lightheadedness,
fatigue or syncope
ECG: wide QRS complex, rate < 50 (idioventricular) or 50-100
(accelerated idioventricular rhythm)
Ventricular Dysrhythmias
Ventricular Tachycardia (VT)
Most commonly due to ischemic heart disease
SX: palpitations, chest pain, dyspnea, syncope, cardiac
arrest
ECG: Greater than 3 consecutive ventricular beats with
rate of 100-250 bpm and wide QRS complex
Potentially life threatening (sudden cardiac death due
to progression to ventricular fibrillation)
Pathophysiology: Diverse group of tachycardia’s
Re-entry (most common) – scar related
Triggered activity and enhanced automaticity
Ventricular Dysrhythmias
Ventricular tachycardia (VT)
Pathophysiology and Prognosis:
Leads to low cardiac output due to significant reduction
in preload and thus stroke volume
If heart is hypoperfused it may lead to ventricular
fibrillation or cardiomyopathy, heart failure or other
complications
Ventricular Dysrhythmias
Ventricular Fibrillation
Irregular (uncoordinated) electrical activity, ventricular rate
>300 bpm, which compromises cardiac output significantly!
Leads to sudden cardiac death (fatal within minutes if not
treated – defibrillator and CPR)
Etiology: myocardial infarction, electrolyte abnormalities,
congenital QT abnormalities, alcohol use,
cardiomyopathies, hypothermia and others
Pathophysiology:
Increased automaticity by Purkinje cells
Triggered activity
Possible re-entry
Ventricular Dysrhythmias
Ventricular Fibrillation
SX: chest pain, dyspnea, nausea, vomiting prior to
sudden collapse (unconscious, unresponsive, no pulse)
ECG: (1) fibrillations of various amplitudes and shapes
(2) no identifiable P wave, QRS complex or T wave (3)
heart rate between 150-500 bpm
Ventricular Dysrhythmias
Torsades de pointes
Form of ventricular tachycardia
ECG: polymorphic; “twisting” varying in amplitude QRS complexes
Associated with QTc prolongation (>500 ms)
Congenital or acquired (LOTS of medications can cause the QTc to be
prolonged)
Rhythm may terminate spontaneously or progress to ventricular
fibrillation
Pathophysiology is not fully understood but believed to be due to
prolonged repolarization phase due to delay in K+ efflux. If an
ectopic beat occurs during this time, it can trigger Torsades de
pointes
SX: most asymptomatic OR syncope, palpitations, dizziness
Cardiac death is the presenting sx in 10% of cases
Conduction Block
Types of arrhythmias characterized by a delay or
complete block in the electrical conduction system
of the heart, particularly affecting the
atrioventricular (AV) node or the bundle branches.
They can lead to inadequate heart rate and may
cause symptoms such as dizziness, fatigue, or
syncope.
 Types of Heart Blocks
First-Degree AV Block:
Description: Prolonged PR interval (>200 ms) on ECG but every impulse is
conducted to the ventricles.
Symptoms: Usually asymptomatic and often benign.
Second-Degree AV Block:
Type I (Wenckebach):
Description: Progressive prolongation of the PR interval until a QRS
complex is dropped.
Symptoms: Often asymptomatic but can cause occasional dizziness.
Type II:
Description: Consistent PR intervals with sudden drops of QRS complexes
(can be more serious).
Symptoms: May lead to bradycardia and require monitoring or pacemaker.
 Types of Heart Blocks
Third-Degree AV Block (Complete Heart Block):
Description: No impulses from the atria reach the
ventricles, resulting in independent atrial and ventricular
rates.
Symptoms: Can cause severe bradycardia, syncope, or
heart failure; often requires pacemaker insertion.
Conduction Block
1st degree AV Heart Block
Abnormally slow conduction through the AV node
resulting in a prolonged P-R interval (>.20 seconds)
without any disruptions of atrial or ventricular
conduction
Typically, asymptomatic and does not require treatment
as typically does not result in complications
Possible caused by increased vagal tone (younger
patients) or fibrotic changes in cardiac conduction
(elderly patients)
Conduction Block
2nd degree Heart Block
Delay in conduction of the AV node resulting in prolonged PR
interval and missing QRS
Mobitz Type 1 (aka Wenckebach)
No structural problem, high vagal tone but can be due to cardiac
problems
ECG: progressively prolonged PR interval until finally the
action potential wave can’t get through AV node and there is
not QRS complex following P wave, then process restarts
Mobitz Type 2
Mostly seen in patients with structural heart disease
Can progress to complete heart block (3rd degree)
ECG: constant PR interval with 1 P wave being dropped every
certain number of beats (but only 1!), as in its not followed by a
QRS
 Conduction Block
2nd degree Heart
Block
SX: can be
asymptomatic OR
fatigue, dyspnea,
chest pain,
presyncope or
syncope or even
sudden cardiac
arrest (Mobitz
Type 2)
Conduction Block
3rd degree (Complete) Heart Block
Complete loss of communications between atria and ventricles
via AV node (fairly rare)
Cardiac output is significantly reduced – fatal if not treated
promptly (FYI most treated with pacemaker)
Either the AV node or the Purkinje fibers step in to act as
pacemakers for the ventricles
Bradycardia