Electrophysiology

Question 1

Depolarization

Answer 1

Stimulates contraction

Question 2

Repolarization

Answer 2

Resting cell, recovery from depolarization

Question 3

Sodium (Na+) electrolyte roll in cardiac function

Answer 3

Flows into cell to initiate depolarization

Question 4

Potassium (K+) electrolyte roll in cardiac function

Answer 4

Flows out of cell to initiate repolarization

Question 5

Calcium (Ca++) electrolyte roll in cardiac function

Answer 5

Moves slowly into the cell, depolarization of pacemakers, maintains depolarization and myocardial contractility

Question 6

Magnesium (Mg++) electrolyte roll in cardiac function

Answer 6

Stabilizes cell (works with K+), opposes Ca++

Question 7

Hypercalcemia

Answer 7

High Ca++
High contractility

Question 8

Hypocalcemia

Answer 8

Low Ca++
Low contractility
High myocardial irritability

Question 9

Hypermagnesemia

Answer 9

High Mg++
High myocardial irritability

Question 10

Hypagnesemia

Answer 10

Low Mg++
Decreased conduction

Question 11

Hyperkalemia

Answer 11

High K+
High myocardial irritability

Question 12

Hypokalemia

Answer 12

Low K+
Decreased automaticity/conduction

Question 13

Cardiac Action Potential Phase 0

Answer 13

Cell depolarizes & begins to contract
Cells receive impulse
Na+ enters cell (positive change in TMP to meet threshold of -70 mV)
More sodium rapidly shoots up to +30 mV
Calcium start to enter slowly
QRS complex (really RQ segment)

Question 14

Cardiac Action Potential Phase 1

Answer 14

Repolarization starts
Inward Na+ channels close
Negative chloride ions enter cell
Outward K+ channels open briefly (slight decrease in TMP, negative charge)
QS segment

Question 15

Cardiac Action Potential Phase 2

Answer 15

Plateau phase (longest phase)
Na+ & Ca++ slowly enters cell while K+ flows out of cell (prolongs depolarization, creating plateau
Ends when outward flow of K+ exceeds Na+ & Ca++
ST segment

Question 16

Cardiac Action Potential Phase 3

Answer 16

Final phase
Slowly Ca++/Na+ channels close
K+ rapidly leaves cell (causing TMP to drop and go negative)
T wave

Question 17

Cardiac Action Potential Phase 4

Answer 17

Resting phase
Membrane potential of -90 mV

Question 18

Transmembrane potential (TMP)

Answer 18

Change in the charge of a myocardial cell (-90 mV at rest)

Question 19

Absolute refractory period (ARP)

Answer 19

Cardiac cells are unable to respond to any stimulus
Phase 0-3 of cardiac action potential
“If you flush a toilet, it needs time to refill”

Question 20

Relative refractory period (RRP)

Answer 20

Enough cells have repolarized sufficiently to depolarize again
Mid phase 3 to beginning of phase 4

Question 21

Time AV node delays pulse

Answer 21

0.12 seconds
Allows atria to empty blood into ventricles

Question 22

AV junction includes:

Answer 22

AV node, surrounding tissue, non-branching portion of bundle of His

Question 23

Time for pulse to spread across ventricles?

Answer 23

0.08 seconds

Question 24

Ischemia definition

Answer 24

Tissue injury caused by hypoxia

Question 25

Secondary pacemaker (bpm): AV node

Answer 25

40-60 bpm

Question 26

Secondary pacemaker (bpm): Purkinje fibers

Answer 26

20-40 bpm

Question 27

Bundle of Kent

Answer 27

Between left atrium and left ventricle
Triggers early depolarization in L. Ventricles
ECG - Delta waves

Question 28

Sympathetic nervous system on heart, enzyme,

Answer 28

Accelerator
Norepi to SA node, AV node, ventricles

Question 29

Parasympathetic nervous system on heart, nerve, enzyme,

Answer 29

Inhibitory, vagus nerve, acetylcholine

Question 30

Vagus nerve stimulation, cause on heart

Answer 30

Increases corotid sinus pressure, straining/forced exhalation (valsalva maneuver), distention of hollow organ (bladder/stomach)
Bradycardia

Question 31

Common drug to fight parasympathetic nervous system/bradycardia

Answer 31

Atropine

Question 32

Baroreceptor

Answer 32

Detects changes in blood pressure in blood
creates CNS response

Question 33

Chemoreceptor

Answer 33

Detects change in hydrogen ions (pH), O2, CO in blood
Creates CNS response