Physiologic Basis for ECG - Steve Flashcards Preview

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1
Q

What does the ECG measure?

A

Potential differences between recording electrodes generated by electrical currents projecting from the heart to body surface during depolarization and repolarization

2
Q

What 3 things contribute to the reproducible rate and rythm observed on the ECG?

A

(1)Automaticity

Cyclic depolarization of autorhythmic cells

(2) Conduction System

Order and timing of electrical events

(3) Functional Syncytium

Current conducted cell-to-cell via gap junctions

3
Q

Detail the following aspects of this ECG…

P wave = ?

QRS complex = ?

T wave = ?

A

P wave = atrial depolarization

QRS complex = ventricular depolarization (atria repolarizing simultaneously)

T Wave = Ventricular repolarization

4
Q

Where does the P wave begin? Where does it go?

A

Begins at SA node, spreads towards AV node

5
Q

Describe the QRS sequence of ventricular depolarization!

A

Depolarization starts at the interventricular septum (Q wave) and endocardial surfaces.

At the end of depolarization phase, current reverses, flows toward the outer walls of the ventricles near the base (S wave).

Average (vector) of current flow: Base à Apex (R wave)

6
Q

Why does left ventricular electrical activity dominate the R wave?

What is the average vector of current in ventricular depolarization?

A

Because there are many more myocytes associated with the left ventricle vs. the right ventricle.

•Average vector of current is R à L and inferiorly oriented (Base à Apex)

7
Q

Why is the normal Mean QRS Vector oriented in the Normal Quadrant in the frontal plane?

A

–Muscle mass of left ventricle
–Normal sequence and distribution of conduction system
–Anatomical position of the heart in the chest

8
Q

If the first deflection is downward =

A

Q wave

9
Q

The first upward deflection =

A

R wave

10
Q

If there is a second upward deflection =

A

R’ wave

11
Q

The first downward deflection following an upward deflection =

A

S Wave

12
Q

If the first wave of the complex is an R wave, the following downward deflection =

A

–S wave, not Q wave

13
Q

A downward deflection only =

A

–a Q wave if it is the first wave of the complex

14
Q

If the entire configuration consists solely of one downward deflection =

A

QS wave

15
Q

What are the arrows indicating?

A

S.A. Node

Atrial Muscle

AV node

Common Bundle

Bundle branches

purkinje fibers

ventricular muscle

16
Q

What is the normal range for the vector of ventricular depolarization?

What range might you see in some individuals?

A

–Normally, between 0° to +90°

(May range from -30° to +110°, depending on source/person)
17
Q

Name the waves

A

QS

R

18
Q

Name the waves

A

RS

QR

19
Q

Name the waves

A

QRS

RSR’

20
Q

What is the average vector of the T wave?

A

•Average vector of current is L -> R and superiorly oriented (Apex -> Base)

21
Q

What is the PR interval?

A

Atrial depolarization and AV nodal delay

22
Q

What is the QT interval? How about the ST segment?

A

•QT interval = Ventricular

depolarization/repolarization

•ST segment = Ventricular contraction & ejection (isoelectric line)

23
Q
  • RR interval =
  • TP interval =
A
  • RR interval = Heart rate
  • TP interval = Ventricular relaxation & filling
24
Q

•Horizontal: Time
5 large squares = ?

A

–5 large squares = 1 second (5 × 0.2 seconds/large square)

25
Q

•Vertical: Relative Voltage
2 large squares = ?

A

•Vertical: Relative Voltage
–2 large squares = 1 mV (2 x 0.5 mV/large square)

26
Q

What is the normal PR interval?

Must know this!

What is this important for?

A

•Normally: 0.12 - 0.2 seconds

(3 to 5 mm on the EKG paper)

•Important for identifying

conduction blocks
•AV blocks: 1°, 2° (Mobitz type I and II), 3°

27
Q

•Deviation from isoelectric line indicates…

A

•Deviation from isoelectric line indicates myocardial ischemia or injury

28
Q

What are the mechanisms behind the two congenital Long QT syndromes and the acquired Long QT syndrome?

A

Congenital:

Mutant Na+, Ca2+ channels (improper inactivation)

Mutant K+ channels (defective repolarization)

Acquired

 Electrolyte imbalances, pharmacologic, etc.
29
Q

What are the two methods of determining heart rate?

A
  1. How many large boxes between QRS
  2. Tic marks are 3 seconds
30
Q

An 86 y/o female presents with complaint of chest pain. She rates her pain as a 4 on a scale of 0 to 10. Her BP is 142/72. What is her HR?

A

60

31
Q

An 83 y/o male complains of chest pain. He had a pacemaker implanted 5 days earlier. His BP is 148/60. What is his HR? What is this arythmia?

A

•75 – 80 bpm

Atrial fibrillation

32
Q

•A 1-month-old infant has a 3-minute seizure. What is the HR?

A

130 - 140 bpm,

33
Q

Wave of depolarization traveling toward a positive electrode records a

A

positive voltage

34
Q

Wave of depolarization traveling away from a positive electrode records a

A

negative voltage

35
Q

1.Wave of repolarization traveling away from a positive electrode records a…

a) Wave of repolarization traveling toward a positive electrode records a

A

positive voltage

negative voltage

36
Q

1.Waves traveling perpendicular to the lead axis record…

A

no net voltage (isoelectric)

37
Q

What does the electrode record?

A

Positive deflection

38
Q

What does the electrode record?

A

Negative deflection

39
Q

2) Wave of repolarization moving away from a positive electrode records a…
2a) Wave of repolarization moving toward a positive electrode records a…
3) Wave of repolarization perpendicular to positive electrode records a…

A

positive deflection

negative deflection

biphasic wave

40
Q

Describe the leads of a 12 lead ECG.

Is a lead an electrode?

A

•Bipolar Standard Limb Leads (1 +, 1 - )
–Leads I, II, III

•Unipolar Augmented Leads (1 +, 2 - )
–Leads aVL, aVR, aVF

•Unipolar Chest Leads
–V1 – V6

  Leads ≠ Electrodes
41
Q

How many limb leads?

How many precordial leads?

A

6 Limb Leads

•3 standard leads

3 augmented leads

•Arms: 2 electrodes

Legs: 2 electrodes

6 Precordial Leads

•Chest: 6 electrodes

42
Q

What do limb leads record?

A

•Record electrical activity moving up/down and left/right in the coronal plane

43
Q

What is meant by angle of orientation?

How is it expressed?

(Critical concept)

A
  • Lead’s unique view of the heart
  • Line from negative electrode(s) → positive electrode(s)

•Expressed in degrees, superimposed on a 360° circle of the frontal plane

44
Q

What is this known as?

A

Einthoven’s Triangle

45
Q

What is the angle of orientation for limb lead one?

A

•Lead I: LA (+) RA (-); Angle of orientation = 0°

46
Q

What is the angle of orientation for limb lead 2?

A

•Lead II: LL (+) RA (-); Angle of orientation = 60°

47
Q

What is the angle of orientation for limb lead 3?

A

•Lead III: LL (+) LA (-); Angle of orientation = 120°

48
Q

For each aVL…

A

1 (+) limb electrode

2 (-) electrodes

49
Q

Angle of orientation for aVL?

A

•Lead aVL: LA (+) RA, LL (-); Angle of orientation = −30°

50
Q

Angle of orientation for aVR

A

•Lead aVR: RA (+) LA, LL (-); Angle of orientation = −150°

51
Q

What is the angle of orientation for aVF?

A

•Lead aVF: LL (+) RA, LA (-); Angle of orientation = +90°

52
Q

What leads have an anterior view of the heart?

A

V2,3,4

53
Q

What leads have left lateral view of heart?

A

I, aVL, V5, V6

54
Q

What leads have an inferior view of the heart?

A

II, III, aVF

55
Q

What leads have a right ventricular view of the heart?

A

aVR, V1

56
Q

Which leads in the frontal plane likely record a positive deflection for the P wave?

A

•Left lateral leads
–I and aVL

•Inferior leads
–II, III and aVF

57
Q

•What does Lead aVR record for the P wave?

A

–Most rightward (−150°) of all the frontal leads
–Atrial depolarization moves away from aVR
–Records a negative deflection

58
Q

Which leads in the horizontal plane would the wave of atrial depolarization be moving towards?

A

•Left lateral leads
–V5 and V6

•Anterior leads

V2-V4 are variable

59
Q

P wave amplitude is generally most positive in _______ and most negative in lead _______

A

P wave amplitude is generally most positive in lead II and most negative in lead aVR

60
Q

•What does V1 record for the P wave?

A

–Right ventricular lead; perpendicular to the atrial current
–May record a biphasic P wave

61
Q

•Which leads in the frontal plane can record large positive deflections (R waves)? (-30° - +90°)

A

–Left lateral (I, aVL) and inferior leads (II, aVF, III)

62
Q

•Which lead in the frontal plane will normally record a deep negative deflection (S wave)?

A

aVR

63
Q

Which leads in the horizontal plane are expected to record tall positive deflections during ventricular depolarization (R waves)?

A

–V5 and V6 (over left ventricle)

64
Q

•Which leads in both the frontal & horizontal plans would be expected to record positive T waves?

A

–Inferior & Left Lateral Leads (I, II, III, aVF, aVL, V5, V6)
–Depends on axis

65
Q

Which lead in the horizontal plane is expected to record a negative deflection (S wave) ?

A

–V1 (over right ventricle)

66
Q

•Which precordial lead and which limb lead would be expected to record negative T waves?

A

–V1 and aVR

67
Q

If the vector representing the mean current flow in the ventricles is:
•Perpendicular to the axis of a limb lead, there will be

A

an isoelectric voltage recorded for that lead.

68
Q

If the vector representing the mean current flow in the ventricles is:

•Parallel and in the same direction as the axis of a limb lead, there will be

A

a large positive voltage recorded for that lead.

69
Q

If the vector representing the mean current flow in the ventricles is:

•Parallel and in the opposite direction as the axis of a limb lead, there will be

A

a large negative voltage recorded for that lead.

70
Q

•Normal:

AVF mostly ?

LL I mostly ?

A

+, +

71
Q

•LAD:

AVF mostly ?

LL I mostly ?

A

-

+

72
Q

•RAD:

AVF mostly ?

LL I mostly ?

A

+

-

73
Q

•Extreme RAD:

AVF mostly ?

LL I mostly ?

A

-

-

74
Q

What is the mean QRS axis?

A

0 degrees

75
Q

•What kind of general changes might cause a MEA deviation?

A

–Physical position of the heart
–Hypertrophy
–Infarction
–Conduction

76
Q

What three primary things might drive a LAD?

What could be the cause for each of these three things?

A

–Physical Shift
•Pregnancy
•Obesity
•End of deep expiration
•Recumbent position

–Left Ventricular hypertrophy* (maybe)
•Chronic systemic hypertension
•Aortic valve stenosis, regurgitation
•Athlete

–Infarction of Right Ventricle

77
Q

What might cause a RAD?

A

–Physical Shift
•Tall and lean
•End of deep inspiration
•Standing position

–Right Ventricular hypertrophy*
•Pulmonary valve stenosis, regurgitation
•Pulmonary hypertension

–Infarction of Left Ventricle

78
Q

Pregnancy, obesity, end of deep expiration or recumbant position could result in what impact to MEA?

A

LAD

79
Q

What impact might these have on MEA?
•Pulmonary valve stenosis, regurgitation
•Pulmonary hypertension

A

RAD - due to right ventricular hypertrophy

80
Q

What impact on MEA might these have?

  • Tall and lean
  • End of deep inspiration
  • Standing position
A

RAD

81
Q

What impact might the following have on MEA?

  • Chronic systemic hypertension
  • Aortic valve stenosis, regurgitation
  • Athlete
A

LAD - due to left ventricular hypertrophy

82
Q

Axis rotation refers to a…

How does the rotation tend to occur?

A

shift in the horizontal plane.

“Rotate toward hypertrophy and away from infarction”

83
Q

Right ventricular hypertrophy will show what on the precordial leads?

A

Large positive deflection in V1

–Followed by progressive decrease in amplitude towards the left chest leads (vs. normal “R-wave progression”)

84
Q

What two lead recordings do you sum to determine left ventricular hypertrophy?

What is the cut-off?

A

V1 and V5

More than 35 mm = LVH

85
Q

Tricuspid stenosis would likely drive?

A

dilation or hypertrophy, right atrium

86
Q

Mitral stenosis would drive?

A

Dilation or hypertrophy, left atrial

87
Q

What are the 9 steps of ECG interpretation?

A
  1. Calibration
  2. Rythm
  3. Heart rate
  4. Intervals
  5. Mean QRS axis
  6. P wave abnormalities
  7. QRS wave abnormalities
  8. ST segment or T wave abnormalities
  9. Compare with patient’s previous ECG’s
88
Q
A