CARDIOLOGY Chapter 11 - Guyton

Question 1

P wave

Answer 1

< 2.5 mm tall and < 0.12 sec long, immediately precedes atrial contraction (wider would signify longer duration for atria to depolarize)

Question 2

PR interval

Answer 2

0.12 - 0.20 sec long (normal value of 0.16 sec), this time is needed for the ventricles to fill with blood!

Question 3

QRS complex

Answer 3

up to 0.10 sec, immediately precedes ventricular contraction

Question 4

T wave

Answer 4

positive when QRS positive, ventricles recover from depolarization (.25-.35 seconds after depolarization), ventricular repolarization

Question 5

Why can atrial repolarization not be seen on the ECG?

Answer 5

masked by the QRS complex

Question 6

QT interval

Answer 6

0.37 sec for men and 0.40 for women, this represents the time of ventricular contraction, heart rate can be determined with the reciprocal of the time interval between each heartbeat

Question 7

How can you calculate HR with the ECG?

Answer 7

HR = 60 sec / R-R interval = BPM, usually take average from 3 cycles

Question 8

Explain the flow of electrical current in the heart?

Answer 8

ventricular depolarization starts at the ventricular septum and the endocardial surfaces of the heart, average current flows positively from the base of the heart to the apex, at the end of depolarization the current reverses from 1/100 of a second and flows toward the outer walls of the ventricles near the base (S wave)

Question 9

Lead I of Bipolar Limb Leads

Answer 9

negative terminal of the ECG is connected to the right arm and the positive terminal is connected to the left arm

Question 10

Lead II of the Bipolar Limb Lead

Answer 10

negative terminal of the ECG is connected to the right arm and the positive terminal is connected to the left leg

Question 11

Lead III of the Bipolar Limb Lead

Answer 11

negative terminal of the ECG is connected to the left arm and the positive terminal is connected to the left leg

Question 12

Q wave

Answer 12

when initial inflection is negative

Question 13

R wave

Answer 13

first positive deflection

Question 14

S wave

Answer 14

negative deflection following the R wave

Question 15

QS

Answer 15

all negative

Question 16

R prime

Answer 16

second positive inflection that occurs after the S wave, only in abnormal ECGs

Question 17

Use of lower case in ECG?

Answer 17

to notate an inflection that is not as strong

Question 18

Einthoven’s Law

Answer 18

electrical potential of any limb equals the sum of the other two (I + III = II)

Question 19

Chest (Precordial) Leads

Answer 19

V1 - V6, very sensitive to electrical potential changes underneath the skin

Question 20

Augmented Unipolar Limb Leads

Answer 20

aVR (+ electrode right arm, - electrode left arm), aVL (+ electrode left arm), aVF (+ electrode left leg)

Question 21

P pulmonale

Answer 21

Right atrial enlargement/abnormality - we would expect a large P wave > or = 2.5mm tall (no change in duration) in II, III, AVF, V1

Question 22

P mitrale

Answer 22

Left Atrial Enlargement, wide P wave > 0.12 sec, amplitude normal or increased

Question 23

Right Ventricular Hypertrophy

Answer 23

R wave > S wave in right Chest Leads (V1 or V2), Right Axis Deviation, Right Ventricular Strain Pattern, T wave inversions, Main characteristic: too much voltage to the right hand side

Question 24

T wave inversions

Answer 24

T waves usually tend to go in same direction as QRS complex, If not, it is considered a strain pattern (or T wave inversion)

Question 25

Left Ventricular Hypertrophy

Answer 25

Horizontal or Left Axis Deviation; This criteria tends not to be universally used; Person who can run a sub 5 min mile may present with this type of EKG

Question 26

Right Bundle Branch Block (RBBB)

Answer 26

Wide QRS Complex, RSR’ in V1 and V2 often with ST-T changes

Question 27

Left Bundle Branch Block (LBBB)

Answer 27

Wide QRS complex with broad or notched R wave in V5, V6, I, Loss of normal septal R wave in V1, Loss of normal septal Q wave in V6

Question 28

Left Anterior Hemiblock (LAHB)

Answer 28

QRS complex < 0.12 sec + QRS axis > -45 degrees

Question 29

Left Posterior Hemiblock (LPHB)

Answer 29

QRS complex < 0.12 sec + QRS axis > +120 degrees

Question 30

Transmural MI

Answer 30

Q wave MIs, depolarization is completely blocked, damaged cardiac muscle remains partly or completely depolarized the entire time, injured muscles emit negative charges throughout each heartbeat, causes of current of injury:
local ischemia, mechanical trauma, infection

Question 31

Subendocardial MI

Answer 31

Non Q wave MIs, subendocardial layer is vulnerable to ischemia associated with: angina pectoris, subendocardial infarction

Question 32

Common ECG changes.

Answer 32

ST segment depression in the anterior or inferior leads, T-wave inversion, down-sloping into the T-wave is abnormal (“J-point”), up-sloping is normal
changes can be localized in the inferior leads

Question 33

Acute Phase MI

Answer 33

S-T elevation; tall, positive (hyperacute) waves

huge

Question 34

Evolving Phase MI: next day

Answer 34

Deep T wave inversions in leads showing S-T elevation, Development of significant Q-waves

Question 35

Resolving Phase (Old MI)

Answer 35

significant Q waves appear, Partial or complete regression of ST-T changes

Question 36

Sinus Bradycardia

Answer 36

HR < 60bpm, often seen in trained people, SA node is beating slow

Question 37

Sinus Tachycardia

Answer 37

HR > 100 bpm

Question 38

Atrial arrhythmias

Answer 38

PACman (premature atrial conduction), premature beat due to refractory period in SA node, occurs either with or without conduction, usually P wave present, compensatory pause

Question 39

Premature Junctional Beat (PJC)

Answer 39

beat from AV junction, Premature beat usually without P wave, Depolarized by the atria before it reaches its critical threshold

Question 40

Junctional Escape Beat

Answer 40

Beat from AV junction when normal pacemaker (SA node) fails, usually NO P wave, different from PJC in the R-R interval (much longer)

Question 41

PVCs

Answer 41

premature before the next normal beat is expected
QRS wide; T wave and QRS are in opposite directions, compensatory pause, R on T phenomenon, couplets, Bigeminy (PVC-normal cycle-PVC-normal cycle), Trigeminy

Question 42

SVT

Answer 42

3 or more consecutive PACs, no P-wave present

Question 43

Atrial flutter

Answer 43

atrial stimulation rate ~ 300 bpm, flutter waves present, represented by ratio of atrial beats: vent. beats, forces AV junction to become pacemaker for ventricles

Question 44

Atrial fibrillation

Answer 44

stimulated at very rapid rate, up to 600 bpm, presence of f waves or fib. waves, forces AV junction to becomes pacemaker for ventricles

Question 45

Junctional Escape Rhythm

Answer 45

starts with junctional escape beat and continues to be paced by AV junction, 40-60 bpm, QRS and T-wave are normal

Question 46

Accelerated Junctional Rhythm

Answer 46

Accelerated junctional rhythm has 60-100 bpm; Junctional tachycardia has 101-180 bpm

Question 47

Ventricular Tachycardia

Answer 47

3 or more PVCs in a row

Question 48

Ventricular Fibrillation

Answer 48

presence of f waves, fine or coarse fibrillation

Question 49

Asystole

Answer 49

ya dead bro

Question 50

1st Degree AV Heart Block

Answer 50

PR interval is prolonged (>0.2 sec)

Question 51

2nd Degree AV Heart Block

Answer 51

mobitz 1 (Wenkebach): progressive lengthening of the PR interval until a beat is dropped; mobitz 2: nonconducted sinus P wave without progressive prolongation of PR interval

Question 52

3rd Degree AV Heart Block

Answer 52

P waves are present; atrial rate faster than the ventricular rate; P waves bear NO relation to QRS; PR intervals variable

Question 53

Wolff-Parkinson-White Syndrome

Answer 53

QRS complex widened; PR interval shorted; Appearance of delta wave; Often surgically repaired and relatively common