Week 1

Question 1

What are the phases of a cardiac action potential?

Answer 1

• Phase 0: Rapid Na+ influx through open fast Na+ channels
• Phase 1: Transient K+ channels open and K+ efflux returns TMP to 0mV
• Phase 2: Influx of Ca2+ through L-type Ca2+ channels is electrically balanced by K+ efflux through delayed rectifier K+ channels
• Phase 3: Ca2+ channels close but delayed rectifier K+ channels remain open and return TMP to -90mV
• Na+, Ca2+ channels closed, open K+ rectifier channels keep TMP stable at -90 mV

Question 2

What is electro-mechanical coupling?

Answer 2

Electrical events cause mechanical events and their

inter-relationship in the heart is important for function

Question 3

What do we measure with ECG?

Answer 3

Electrical signal. It’s relationship to mechanical and

functional properties of the heart is what makes it a valuable component of the cardiac exam

Question 4

What does an electrocardiogram do?

Answer 4

Captures the electrical activity produced by the heart’s contraction cycle.

Question 5

What forms the basis for an electrocardiogram?

Answer 5

The detection of current electrical impulses generated from the flow of charged particles along this pathway that are detectable
on the surface of the skin

Question 6

Where are the electrodes of an ECG in reference to the body?

Answer 6

The negative is on the right arm and the positive electrode is usually on the left leg

Question 7

ECG leads capture signal going from where to where?

Answer 7

From the negative terminal to the positive terminal

Question 8

What end of the ECG captures/receives the signal?

Answer 8

The positive terminal

Question 9

What do ECG bipolar leads utilize?

Answer 9

A negative and positive electrode and record the electrical activity between them.

Question 10

What do ECG unipolar leads utilize?

Answer 10

Utilize a single positive recording electrode and a combination of the other electrodes to serve as a composite negative electrode

Question 11

Where do the bipolar leads go?

Answer 11

Limb: Right arm, left arm, left leg

Question 12

Where do the unipolar leads go?

Answer 12

• Precordial (Chest)

* Unipolar (Augmented)

Question 13

Where do the precordial (Chest) leads go?

Answer 13

• V1: 4th IC space to the right of the sternum (Septal)
• V2: Forth IC space to the left of the sternum (Septal)
• V3: between V2 and V4 (Anterior wall)
• V4: midclavicular line, 5th IC space (Anterior Wall)
• V5: anterior axillary line @ level of V4 (Lateral Wall)
• V6: midaxillary line @ level of V4 (Lateral Wall)

Primarily on the left side

Question 14

Why are augmented leads termed as unipolar leads?

Answer 14

Because there is a single positive electrode that is referenced against a combination of the other limb electrodes.

Question 15

What portion of the heart does augmented lead: aVF(augmented vector foot) look at?

Answer 15

The inferior portion of the heart

Question 16

What portion of the heart does augmented lead: aVL(augmented vector lateral/left arm) look at?

Answer 16

The lateral wall of the heart

Question 17

What portion of the heart does augmented lead: aVR(augmented vector right arm) look at?

Answer 17

It looks at the heart backwards, so its signal is flipped.

Called the orphan lead

Question 18

What is the most basic ECG?

Answer 18

The 3 lead ECG. It uses 3 electrodes. (RA, LA and LL)

Question 19

The 3 lead ECG is able to obtain a signal for the ____ leads

Answer 19

The 3 lead ECG is able to obtain a signal for the bipolar limb leads

Question 20

What is the 3 lead ECG used for?

Answer 20

Basic monitoring and Research

purposes

Question 21

Where are the lead placements for the 5 lead ECG?

Answer 21

RA, RL, LA, LL and Chest

Question 22

What is displayed on the monitor of the 5 lead ECG?

Answer 22

The bipolar leads (I, II and III) AND a single chest/precordial lead
- (depending on position of the brown chest lead (positions V1–6)

Question 23

In what setting is the 5 lead ECG commonly used?

Answer 23

In Acute Care

Question 24

What are the characteristics of the 12 lead ECG?

Answer 24

• 10 electrodes.
• Electrodes on all 4 limbs
  - (RA, LL, LA, RL)
• Electrodes on precordium
  - (V1–V6)
• Monitors 12 leads
  - (V1–V6), (I, II, III) and (aVR, aVF, aVL)

Question 25

What does a 12 lead ECG allow?

Answer 25

Allows interpretation of specific areas of the heart

Question 26

What is a 12 lead ECG used for?

Answer 26

Diagnostics, stress testing

Question 27

What is the location and coronary artery of a V1, V2 lead?

Answer 27

Location: Anterior

Coronary artery: LAD

Question 28

What is the location and coronary artery of a V3, V4 lead?

Answer 28

Location: Apical- septal

Coronary artery: LAD

Question 29

What is the location and coronary artery of a II, III, and avF lead?

Answer 29

Location: Interior

Coronary artery: PDA( 80% RCA, 20% LCx)

Question 30

What is the location and coronary artery of a I, V5, V6, and avL lead?

Answer 30

Location: lateral

Coronary artery: LCx

Question 31

What do the thin lines on an ECG paper mean?

Answer 31

1 mm intervals or 0.04 sec

Question 32

What do the thick lines on an ECG paper mean?

Answer 32

5 mm intervals or .2sec

Question 33

What do the 1 thick lined box (5 boxes) on an ECG paper mean?

Answer 33

.20 sec or 5mm

Question 34

What do the 5 thick lined box (25 boxes) on an ECG paper mean?

Answer 34

= 1 second

Question 35

What do the tick marks on rhythm strip on an ECG paper mean?

Answer 35

3 secs

Question 36

10 mm on an ECG paper is equal to ___

Answer 36

1 mV

Question 37

What does the P wave on an ECG represent?

Answer 37

Atrial Depolarization

Question 38

What are the normal ranges for a P wave on an ECG?

Answer 38

• Duration: < 0.12s OR 3 small boxes)

* Amplitude: < 2.5mm OR 2.5 small boxes)

Question 39

What does the P-R interval on an ECG represent?

Answer 39

The propagation of the cardiac

action potential from the atria through the AV node into the ventricles.

Question 40

What are the normal ranges for a P-R interval on an ECG?

Answer 40

• Duration: 0.12- 0.2s OR 3-5 small boxes

* Will shorten during exercise as heart rate increases

Question 41

What does the QRS complex on an ECG represent?

Answer 41

Ventricular Depolarization

Question 42

What are the normal ranges for a QRS complex on an ECG?

Answer 42

• Duration: 0.06- 0.10s OR 1.5-2.5 small boxes,

* Some healthy patients may have wider QRS (0.10-0.12s), but the absolute cut off is 0.12s

Question 43

What is the amplitude for a QRS complex on an ECG?

Answer 43

• >0.5 mV in at least one standard lead (5 small
boxes)
• >1.0 mV in at least one precordial lead (10 small boxes)
• Upper limit 2.5 – 3.0 mV (25 small boxes)

Question 44

What does the S-T segment on an ECG represent?

Answer 44

The interval between ventricular depolarization and repolarization.

Question 45

What are the normal ranges for a S-T segment on an ECG?

Answer 45

• A discrete ST segment distinct from the T wave is usually absent.
• Often at higher heart rates (exercise) the ST-T segment is a smooth, continuous line
beginning at the J-point (end of QRS), slowly rising to the peak of the T-wave

Question 46

What does the T wave on an ECG represent?

Answer 46

Ventricular repolarization

Question 47

What are the normal ranges for a T wave on an ECG?

Answer 47

• It’s deflection should be the same direction as the largest component of the QRS wave complex (usually the R wave

• Ie, if the R wave is positive the T wave should be positive.
• Ex; in lead aVR it is normal for the T wave to be negative, since the QRS is also negative

Question 48

What does the R-R Interval on an ECG represent?

Answer 48

• The duration between subsequent “heart beats”.

* This is duration is used to calculate heart rate.

Question 49

What are the normal ranges for the R-R Interval on an ECG?

Answer 49

• Should be regular and consistent,
- Especially at rest.
• Will shorten during exercise as heart rate increases.

Question 50

What does the Q-T Interval on an ECG represent?

Answer 50

• It represents the time taken for ventricular depolarization and repolarization.
• Shortens during faster heart rates, lengthens during slower heart rates

Question 51

What are the normal ranges for the Q-T Interval on an ECG?

Answer 51

• Duration:

• Men 0.4- 0.44s OR 10-11 small boxes
• Women: 0.44- 0.46s OR 11-11.5 small boxes.

Question 52

Why is the corrected QT (QTc) interval more often used?

Answer 52

Since the duration of QT varies inversely with the heart rate, the raw QT interval is often not used

Question 53

How is the corrected QT (QTc) calculated?

Answer 53

QTc = measured QT interval
divided by
square root of R-R interval

Question 54

What is the normal value for the corrected QT (QTc)?

Answer 54

< 0.44 sec

Question 55

What does the J point on an ECG represent?

Answer 55

• The initiation of ventricular
repolarization
• Junction between the termination of the QRS complex and the beginning of the ST segment

Question 56

What are the normal ranges for the J point on an ECG?

Answer 56

Should be in line with the isoelectric line

Question 57

What is the R wave progression?

Answer 57

Small R waves begin in V1/V2 and progress in size to V4/V5.

• The R in V6 is usually smaller than R in V5.

Question 58

What occurs at leads V3 or V4?

Answer 58

The transition from S>R to R>S

Question 59

Where do s-waves begin when in reverse?

Answer 59

In reverse, the s-waves begin in V6 or V5 and progress in size to V2.
• The S in V1 is usually smaller than the S V2.

Question 60

What is the QRS axis?

Answer 60

The direction of the mean QRS vector in the frontal plane

Question 61

Normally all QRS segments are positive, except for ___

Answer 61

aVR

Question 62

What are the characteristics of the Left Axis Deviation LAD of the QRS axis?

Answer 62

• QRS is positive (dominant R wave) in leads I and aVL

* QRS is negative (dominant S wave) in leads II and aVF

Question 63

What are the characteristics of the Right Axis Deviation LAD of the QRS axis?

Answer 63

• QRS is negative (dominant R wave) in leads I and aVL

* QRS is positive (dominant S wave) in leads II or III and aVF

Question 64

What are the components of the systematic analysis of an ECG?

Answer 64

• Rate
- Is the rate fast or slow
• Rhythm
- Regular or irregular
• Are a P wave and QRS complex with each cycle
• Do the P waves look alike
• Is there a P wave preceding every QRS
• Is the PR interval within normal limits
• Is the QRS duration within normal limits
• Does the rhythm come from the SA Node, AV node, or the ventricles
• Does the atrial rate = ventricular rate

Question 65

What should the atrial rate to ventricular rate of an ECG be?

Answer 65

Should be 1:1

Question 66

What does it mean when the rhythm of an ECG comes from the AV Node or above (SA, AV, atria, nodal tracts)?

Answer 66

The QRS is narrow

Question 67

What does it mean when the rhythm of an ECG comes from below the AV node?

Answer 67

Wide QRS

Question 68

What does it mean when the rhythm of an ECG has no p wave but normal QRS?

Answer 68

AV node

Question 69

What is normal heart rate at rest?

Answer 69

60- 100 bpm

Question 70

What is tachycardia?

Answer 70

HR above normal

Question 71

What is bradycardia?

Answer 71

HR below normal

Question 72

How is the rhythm of an ECG analyzed?

Answer 72

Whether or not it is regular looking at the distance from each R interval to the other

Question 73

How are P wave and QRS complex with each cycle analyzed?

Answer 73

Is there a P wave preceding each QRS complex?

Question 74

How is the P wave analyzed?

Answer 74

• Do the P waves look alike?
• Are the distances similar?
• Do we see multiple P waves?

Question 75

How do we analyze the PR interval?

Answer 75

Is it within normal limits of 0.12- 0.2

Question 76

How do we determine if the QRS duration is within normal limits?

Answer 76

The cutoff is 0.12 secs/ 3 small boxes

Question 77

When can we assume that the rhythm of the ECG is sinus?

Answer 77

If we see a normal looking P wave prior to a narrow QRS

Question 78

When can we assume that the rhythm of the ECG is supraventricular?

Answer 78

It indicates that somewhere above the ventricles is controlling the HR. The QRS will be narrow, without a P wave

Question 79

When can we assume that the rhythm of the ECG is ventricular?

Answer 79

When the rhythm/impulse generated is below the atria., Below AV node (ventricles). The QRS will be wide

Question 80

How do we calculate HR?

Answer 80

Using the ECG paper, after the 1st QRS complex, divide 60/.2, then add (0.2) for every other thick line you hit. (60/.4), (60/0.6)……

Question 81

What happens if the QRS doesn’t fall on a thick line?

Answer 81

Use the distance between the two intervals the QRS lies between. Subtract the little number from the big number,, then divide it by 5, because there are 5 thin boxes that equals 3 bpm

Question 82

What method is used when the R to R interval is invariable?

Answer 82

• Count number of QRS complexes in a six second interval and multiply by 10
• 30 thick lined boxes

Question 83

What is a regular rhythm in an ECG?

Answer 83

• 1 P wave per QRS complex

* RR interval constant

Question 84

What is a regularly irregular rhythm in an ECG?

Answer 84

• RR interval variable but with a pattern.
• Normal and ectopic beats grouped together and
repeating over and over.

Question 85

What is a irregularly irregular rhythm in an ECG?

Answer 85

RR interval and ectopy variable with no pattern, totally irregular

Question 86

Why do children have a faster HR?

Answer 86

Because their heart doesn’t fully develop until 12

Question 87

What does sinus bradycardia look like?

Answer 87

R to R interval is consistent, everything looks good. However the rate is 60 bpm

Question 88

What does sinus tachycardia look like?

Answer 88

Normal P wave, followed by a normal QRS, R to R interval is consistent, but the rate is faster than 100 bpm

Question 89

What does sinus arrythmia look like?

Answer 89

Normal sinus signals, morphology, normal P wave,, everything else is normal, but the R to R interval isvery variable

Question 90

What is an ectopic pacemakers/foci?

Answer 90

Abnormal pacemaker sites located outside of the

SA node that display automaticity.

Question 91

How is the activity of an ectopic pacemaker normally suppressed?

Answer 91

Via overdrive suppression. by

the higher rate of the SA node.

Question 92

Where can an ectopic foci occur?

Answer 92

Within the atria or ventricles.

Question 93

What is the most common type of rhythm caused by an ectopic foci?

Answer 93

Supraventricular Tachycardia (SVT)

Question 94

What are the characteristics of an atrial flutter?

Answer 94

• Regular atrial activity with a saw-tooth apperances
• Ventricular rate usually 60-100bpm
• Conduction ratio usually between 2:1 and 4:1
• Not frequently encountered in clinic

Question 95

An atrial flutter and fibrillation is technically a ____ rhythm

Answer 95

Supraventricular rhythm

Question 96

What is an atrial fibrillation?

Answer 96

Atrial activity is poorly defined; may see course or fine undulations or no atrial activity at all.

Question 97

What causes an atrial fibrillation?

Answer 97

Multiple ectopic pacemakers in the atria

Question 98

What are the characteristics of an atrial fibrillation?

Answer 98

• Ventricular response is irregularly irregular
- Ventricular response can be rapid, moderate or slow
• Adequate Control (HR <110bpm)
• Inadequate Rate Control (HR >110 bpm), need medication modification

Question 99

What are the differences between an atrial fibrillation and atrial flutter?

Answer 99

• The p wave in Aflutter has a distinct saw tooth morphology
• Afib p waves will be variable, heart to detect or not demonstrated at all
• The rhythm of Aflutter is usually fairly regular, limited R-R variability
• The rhythm of Afib is usually very irregular, high R-R variability, with isoelectric
line variability
• Aflutter usually has a fixed or consistent conduction block pattern
• Ie, 4 saw tooth p waves then a QRS = 4:1 block
• Afib p waves are often not discernable and follow no consistent pattern

Question 100

What does a patient with an aflutter feel?

Answer 100

Feel like the heart is fluttering, maybe skipping a beat here or there, HR will generally be faster, not as severe as an afib

Question 101

Patients with an Afib is at a high risk for ____

Answer 101

Patients with an Afib is at a high risk for blood clots, because the atria is quivering, the blood is turbulent, but is not being properly ejected

Question 102

When will an AV node block present?

Answer 102

When the P-R > 0.2 sec

Question 103

What is a 1st degree AV node block?

Answer 103

PR>0.20 sec. Might have a slower HR, fairly benign

Question 104

What is a 2nd degree AV node block?

Answer 104

• Type I (Mobitz I or Wenckeback): increasing PR interval until a QRS complex is dropped. It is usually benign.
• Type 2 (Mobitz II): QRS dropped without any progressive increase in PR interval (i.e., PR interval is constant but still >0.20 sec).

Question 105

What is a 3rd degree AV node block?

Answer 105

• Aka: “Complete Heart Block
• 3rd degree AV Block: atria and ventricles are electrically dissociated.
• P waves and QRS complexes will occur independent of each other.
• As always, use the QRS complexes to determine heart rate.

Question 106

What method is used when calculating the HR of a 2nd degree AV node block?

Answer 106

The second method to calculate HR: count the number of QRS complexes for the 6 sec strip, then multiply it by 10

Question 107

What does a patient with an AV node block feel?

Answer 107

They feel that their heart skips a beat

Question 108

What is a 3 to 1 block?

Answer 108

When you have 3 normal QRS complex in a row, then a missing one. Can be used for any

Question 109

What may change a type 2 2nd degreeAV node block?

Answer 109

Exercise, conduction blocks, and as demand increases on the myocardium

Question 110

Why might a patient with an AV node be symptomatic?

Answer 110

Due to the loss of cardiac output. A “dropped” or “lost” QRS indicates the ventricles did not depolarize, which means they don’t contract to push blood into the systemic circulation for that time period

Question 111

What is observed in a Premature Atrial Contraction (PAC)?

Answer 111

The amplitude of the R wavs is usually a lot smaller, there will be a normal QRS, but then out of the blue, there will be a random bit of ectopy caused by a random ectopic foci. Usually benign

Question 112

What causes a Premature Atrial Contraction (PAC)?

Answer 112

A small random ectopic foci which is caused by irritants to the myocardium, or stress.

Question 113

What happens if a Premature Atrial Contraction (PAC) falls on the relative refractory period?

Answer 113

A more concerning rhythm can be set off, called ventricular fibrillation

Question 114

When is the relative refractory period?

Answer 114

After the QRS and before the down slope of the T wave

Question 115

What is observed in a Premature ventricular Contraction (PVC)?

Answer 115

A wide funky looking QRS, which happens spontaneously

Question 116

What causes a Premature ventricular Contraction (PVC)?

Answer 116

Caffeine, or anything that will cause the heart to be irritable

Question 117

What is the cutoff for a Premature ventricular Contraction (PVC)?

Answer 117

6 PVCs/min, anymore is a cause for concern

Question 118

What should be done if a person has more than 6 PVCs/ min?

Answer 118

It will affect cardiac output, so check BP, stop exercise and further assess

Question 119

What are the things to always look for when assessing a PVC?

Answer 119

Always look for the size of the QRS and the morphology, if the PVC is from the same area of the heart, the shape of the wave will be consistent. If the shapes are different, it means the PVCs are originating from different parts of the heart

Question 120

What are PVCs that all look the same called?

Answer 120

Monomorphic

Question 121

What are PVCs that all look different called?

Answer 121

Polymorphic

Question 122

What is a bigeminy PVC?

Answer 122

A PVC that occurs every other beat

Question 123

Why is a bigeminy PVC concerning?

Answer 123

Because if the PVC happens prior to the heart filling sufficiently, that ventricle is not ejecting sufficient amounts of blood. So the more we have,, the more concerned we are that we are not getting an effective cardiac output, hence there is no tissue perfusion

Question 124

What is a trigeminy PVC?

Answer 124

A PVC that occurs every 3 beats

Question 125

What is a quadrigeminy PVC?

Answer 125

A PVC that occurs every 4th beat

Question 126

Why is a trigeminy less concerning than a bigeminy, and a quadrigeminy less concerning than a trigeminy?

Answer 126

Because there are less or them per minute

Question 127

What is a couplet PVC??

Answer 127

2 PVCs in a row

Question 128

What are the implications of a PVC, especially a couplet?

Answer 128

Blood won’t be pumped out properly, hence tissues like the brain and such could get damaged, or can lead to a heart attack

Question 129

What is Ventricular Tachycardia?

Answer 129

When the ventricles are pumping quickly, which may not allow them to fill sufficiently. (4 or more PVCs in a row)

Question 130

What is Non- Sustained Ventricular Tachycardia?

Answer 130

Ventricular tachycardia that lasts less than 30 secs in duration. Patients often go into breif bout of it

Question 131

What do you do when you see a patient with a Non- Sustained Ventricular Tachycardia?

Answer 131

Stop exercise, assess the patient, and make sure they are stable

Question 132

What is Sustained Ventricular Tachycardia?

Answer 132

Anything that doesn’t revert back into normal rhythm after about 30 secs

Question 133

What is a pulseless electrical activity?

Answer 133

When we see an electrical rhythm whose rate is beating out of control and may not be filing

Question 134

What is ventricular fibrillation?

Answer 134

When the ventricles demonstrate a worm like pattern, they are not pumping effectively, hence not moving any blood

Question 135

What is Torsades de pointes?

Answer 135

A pulseless electrical activity that often happens when there is a PVC that falls somewhere from a elongated Q-T interval

Question 136

What is a Aystole (Flat line)?

Answer 136

When the patient is electrically dead in the heart

Question 137

What are ventricular pacemakers used for?

Answer 137

Patients that have abnormal rhythms, specifically type 2 second degree AV node blocks or complete heart blocks, and in patients with a significant A-fib

Question 138

What do we see on a ventricular pacemaker?

Answer 138

We see spikes followed by a ventricular beat

Question 139

What is the general rule of thumb when it comes to the ischemic changes seen in an ECG?

Answer 139

When we start having reduced blood flow to the myocardium, it affects its ability to conduct an action potential and will also drastically begin to change the membrane potential, or inhibit the ability for the myocardium to move electrons, specifically potassium and sodium across the barrier that requires ATP. This will eventually lead to the membrane rupturing and result in troponin and other enzymes in the blood

Question 140

What is a T- wave inversion?

Answer 140

It is a sign of ischemia whose changes is significant only when seen in buddy leads. It is the 1st sign we see of ischemia

Question 141

What does a T wave inversion progress to, in the presence of ischemia?

Answer 141

ST segment changes, specifically ST depression. Due to the membrane potential being altered, which may eventually progress to ST elevation.

Question 142

What is ST elevation?

Answer 142

When the membrane potential has been completely disrupted and we probably have some infarction or cell death

Question 143

How do we confirm ischemic changes/ heart attack?

Answer 143

If the heart dies, it releases bio- markers, troponin creating kinase lactate dehygrenase, because we are not able to pump ions across the membrane, because we lost blood flow, energy, which will lead to the loss of the NaK pump, which causes the cell to rupture

Question 144

What is an NSTEMI?

Answer 144

When there is no ST elevation, but there was an heart attack because we have positive bio markers

Question 145

What is a STEMI?

Answer 145

A heart attack that is accompanied by ST elevation

Question 146

What can the comment “demand ischemia” and elevated troponin mean on a patient’s chart?

Answer 146

It can be due to poor cardiac output and does not represent an MI. The patient may be at risk for additional ischemia related to activity, so proceed cautiously

Question 147

What is the criteria for ST depression for ischemia?

Answer 147

Greater than 1mm at the J point

Question 148

In what direction should the T wave be?

Answer 148

In the same direction of the greatest QRS

Question 149

What is the most common cause of ST segment

elevation?

Answer 149

Myocardial ischemia and

infarction

Question 150

What are the threshold values for ST segment elevation?

Answer 150

STEMI are Jpoint elevation of >2 mm in leads V2 and V3 or >1 mm in all other leads.

Question 151

ST elevation greater than ____ is concerning

Answer 151

ST elevation greater than one box is concerning

Question 152

In what patient presentation do we see pathologic Q waves?

Answer 152

In people with healed scarred tissue after the tissue has died from a heart attack

Question 153

What is a pathologic Q wave?

Answer 153

A really deep Q wave and an almost absence of the normal QRS

Question 154

What happens in a bundle branch block in ischemia?

Answer 154

Due to some sort of change in the conductive system in the bundle branches, there is some sort of delay in the conductive system. They look like wind peaked QRS waves that are usually a little wider on the left ones and on the right ones, we see twin peaks

Question 155

What are the non- ischemic causes of ST depression?

Answer 155

• RVH (right precordial leads) or LVH (left precordial leads, I, aVL)
• Digoxin effect on ECG
• Hypokalemia
• Mitral valve prolapse (some cases)
• CNS disease
• Secondary ST segment changes with conduction abnormalities (e.g., RBBB,
LBBB, WPW, etc)

Question 156

What are the non- ischemic causes of ST elevation?

Answer 156

• LVH (left precordial leads, I, aVL)
• Conduction abnormalities (such as LBB, WPW and non-specific intracardiac conduction delay)
• Early repolarization pattern
• Aneurysm/old myocardial infarction
• Pericarditis/myocarditis
• Brugada pattern
• Takotsubo (apical ballooning) syndrome
• Hyperkalemia
• Hypercalcema

Question 157

What are the types of ST depression?

Answer 157

• Normal
• Upsloping
• Horizontal
• Downsloping

Question 158

When does the common changes in the ST segment?

Answer 158

During exercise

Question 159

What is a normal ST segment?

Answer 159

When it returns to the isoelectric line

Question 160

What are the types of ischemic ST depression?

Answer 160

Horizontal or downsloping

Question 161

When do we see upsloping ST depression?

Answer 161

It is fairly normal during exercise

Question 162

What is a common cause of a diffuse ST elevation?

Answer 162

Pericarditis

Question 163

What is pericarditis?

Answer 163

Inflammation of the cardiac sac and tissues which causes compression of the myocardium

Question 164

What are the characteristics of pericarditis and ST elevation?

Answer 164

• Concave upwards ST elevation in most leads except aVR
• No reciprocal ST segment depression (except maybe aVR)
• T waves are usually low amplitude, and heart rate is usually increased.
• May see PR segment depression, a manifestation of atrial injury due to compression

Question 165

What are hyperkalemia?

Answer 165

An elevated potassium level

Question 166

What are the non ischemic T wave changes?

Answer 166

Changes that occur as a result of hyperkalemia which affects the membrane potential especially during repolarization, which will be identified with a peaked T wave, which will be much greater than the amplitude of the QRS