Cardiac Electrophysiology

Question 1

What are the three electrophysiologc types of cardiac cells?

Answer 1

• pacemaker cells (SA node, AV node)
• specialized rapidly conducting tissues (Purkinje fibers)
• ventricular and atrial muscle cells

Question 2

[Na+] and [Ca++] are normally {higher/lower} outside the cell and [K+] is {higher/lower} inside the cell?

Answer 2

[Na+] and [Ca++] are normally higher outside the cell and [K+] is **lower **inside the cell

Extracellular Na+ concentration in myocytes is 145mM, and 15 mM inside

Extracellular [K+] is 5 mM and internal is [K+] 150 mM

Extracellular [Ca++] is 2mM, internal is 10^-7 M

External [Cl-] is 120mM, internal is 5 mM

Question 3

What is the resting potential of the cardiac muscle cell?

Answer 3

About -90mV

Question 4

What happens during Phase 0 of the cardiac action potential?

Answer 4

At rest, Na and Ca channels closed.

Stimulation -> Na channels open and Na+ enters the cell -> depolarization (cell less negative) -> even more Na+ channels open -> membrane potential becomes positive

Question 5

What happens during Phase 1 of cardiac action potential?

Answer 5

small repolarization - K+ leak channels move K+ out of the cell, membrane potential reaches about 0 mV

Question 6

What happens during Phase 2 of cardiac action potential?

Answer 6

K+ continues to “leak” outside the cell

Ca++ channels open and Ca++ enters the cell

K+ out balances Ca++ in, so no net change in charge is observed (hence plateau)

Ca++ is slower to open then Na+, hence it is in Step 2 (but remains open longer).

This is the crucial step in which Ca++ enters the cell to start myocardial contraction.

K+ outward rate slowly starts exceeding Ca++ in rate, leading to Phase 3

Question 7

What happens in Phase 3 of cardiac action potential?

Answer 7

K+ outward rate slowly starts exceeding Ca++ in rate, leading to Phase 3, repolarization (action potential more -ve).

K+ continues to move out of the cell, all other channels become relatively inactive - > cell becomes negative again .

Ca++ is moved out of the cell via Na+ /Ca++ exchanger and ATP-linked Ca pump (less)

Na+/K+ is corrected via Na+/K+ ATPase

Question 8

What happens during Phase 4 of cardiac action potential?

Answer 8

Phase 4 is known as resting phase - depolarization starts with phase 0.

Question 9

What cardiac cells do not need external signal to initiate action potential?

Answer 9

Pacemaker cells are automatic - they spontaneously depolarize during phase 4. As they depolarize, threshold is eventually reached and action potential begins.

Pacemaker cells include: SA node and AV node. Atrial and ventricular myocytes can show automaticity when under stress, ex. ishemia.

Question 10

What is a refractory period?

Answer 10

Absolute refractory period - time during which muscle cells are not responsive to any new stimulus.

Relative refractory period - stimulus can trigger action potential, but the rate of action potential is much slower then usual, since some of the Na+ channels are still inactivated, while some leak K+ channels are activated - less charge travelling.

Question 11

Which cells have shorter refractory periods, ventricular or atrial?

Answer 11

Atrial cells have shorter refractory periods than ventricualr muscle cells, so during bad arrhythmias, atrial compression rates can be faster.

Question 12

Where does cardiac depolarization start in the heart? Outline the sequence of tissues involved in propagation?

Answer 12

Electrical action potential initiated at the SA node -> spreads through atria via gap junctions -> AV node -> bundle of His, Purkinje fibers -> ventricular muscle cells

Question 13

What are myosin, actin and troponin?

Answer 13

Myosin = thick filaments, contains heads

Actin = thin filament, double helix, covered with double helix of tropomyosin and dots of troponin. Think actin ~ active = thin

Tropomyosin = double helix that covers actin, inhibits direct contact between actin and myosin “tripping myosin”

Troponin = three circular subunits

TnT = links troponin to actin and tropomyosin

TnI = inhibits ATPase of actin-myosin

TnC = binds calcium

Question 14

What links electical to mechanical contractility in cardiac muscle?

Answer 14

Ca++ links electrical and chemical contraction in myocardium. During phase 2 of the action potential, Ca++ flows into the cell . This [Ca++] is not enough to start cardiac contraction, but this increase in [Ca++] triggers sarcoplasmic reticulum (SR) of muscle cells to release more [Ca++].

Question 15

How does mechanical contractility happen in cardiac cells?

Answer 15

Electrical action potential -> some Ca++ flows into the cell during Phase 2 ->

[Ca++] increase inside the cell stimulates ryanodine receptors in sarcoplasmic reticulum, which undergo conformational change - > more [Ca++] released, this time from SR->

now [Ca++] in cytosol is high enough to generate contraction

initial inflow of Ca++ via travelling action potential is amplified via activation of ryanodine receptors in SR, which lead to more Ca++ flow, stimulating contraction. This Ca++ amplyfing signal to increase [Ca++] in the cytosol is known as calcium-induced calcium release.

Ca++ binds to TnC (troponin), activity of TnI is inhibited, this induces conformational change in tropomyosin -> active site of actin is exponsed -> myosin heads bind to actin and “flex”, causing the move between thin and thick filaments (ATP-dependent)

Question 16

What is calcium-induced calcium release?

Answer 16

initial inflow of Ca++ via Ca channels that open during travelling action potential is amplified via [Ca]-sensitive activation of ryanodine receptors in SR, which lead to more Ca++ flow, stimulating contraction. This Ca++ amplyfing signal to increase [Ca++] in the cytosol is known as calcium-induced calcium release.

Question 17

What are the steps of the contractile process?

Answer 17

Ca++ binds to TnC (troponin), activity of TnI is inhibited, this induces conformational change in tropomyosin -> active site of actin is exponsed -> myosin heads bind to actin and “flex”, causing the move between thin and thick filaments (ATP-dependent)

see image for more details

Memory aid: Myosin is a cheat, if ATP is available it would prefer it to actin, but when ATP looses its assets and becomes ADP-P, myosin goes for actin instead. Once ATP becomes available again, myosin leaves actin again.

As cytosol Ca++ falls Ca++ leaves TnC and tropomyosin slides back onto binding sites of actin.

Question 18

How does Ca++ leave cell/cytosol after contraction?

Answer 18

Ca++ that entered cell leaves cell via Na+/Ca++ exchanger (mostly) and Ca++-ATPase pump.

Ca++ that entered cytosol from SR returns to SR primarily through sarco (endo) plasmic reticulum Ca++ ATPase (SERCA).

Question 19

Outline electrolyte concentration and ion channel types in cardiac cell?

Answer 19

Question 20

What is a positive iotropic effect?

Answer 20

As beta-adrenergic receptors are stimulated, heart muscles contract with more force and contract faster = +ve inotropic effect.

Question 21

What is positive lucitrophic effect?

Answer 21

an increase in the rate and duration of muscle relaxation of the cells following beta adrenergic stimulation = +ve lucitrophic effect.

Notice that you’re spending less type in systole now and more on relaxation / dyastole – need time for ventricular filling and flow of blood through coronary capillaries. When heart contracts, it can compress and shut down its vessels, so need to make sure you have enough time in dyastole to get O2 and remove CO2.

Question 22

How do cardiac cells decrease systole and increase dyastole during beta-adrenergic stimulation?

Answer 22

[Ca++] in cytosol is key to regulating force of contraction. beta-adrenergic stimulation is one mechanism to change [Ca++] in the cytosol.

catecholamines (ex. norepinephrine) bind to beta1-adrenergic receptor (G protein coupled) -> ATP-cAMP -> inactive protein kinases -active protein kinases-> go on to phosphorylate:

1. voltage-gated Ca channel within the membrane - increases influx of Ca++ into the cell -> ryanodine responds by coordinating more Ca++ released from SR -> force of contraction increased
2. phospholamban (PL) is a protein in the SR membrane, which inhibits SERCA pump. Phosphorylation of phospholamban stops its inhibition, so SERCA pumps Ca++ back into SR faster -> myocytes relax faster. Notice that Na/Ca pump and Ca ATPases are not phosphorylated, they pump Ca++ out at the same rate, so we’re bringing more Ca++ into the cell, and it is going to SR via SERCA -> more Calcium exits into cytosol during action potential -> more Ca binds to troponin C -> higher force of contraction
3. troponin also gets phosphorylated, which in turn decreases its affinity to Ca, so myosin and actin are more likely to detach from each other -> myocytes relax faster

Question 23

Describe energy usage in cardiomyocyte?

Answer 23

Energy is in the form of ATP
If we shut off all production, all ATP would disappear in 10 seconds.

Sources of ATP are:
• Phosphocreatine (rapidly available) – during systole, your creatine phosphate can be broken down into ATP and creatine; probably enough for 2-3 beats
• Glycolytic pathway – about 20% of energy for cardiomyocyte
• Fatty acid – 70% of energy supply for the heart, mostly C16 and C18 – mitochondria really like those fatty acids. Fatty acids preferred because about 130 ATP/molecule compared to 36/38 via glucose molecule
• Lactate – 10% of energy use

Numbers shift dramatically during initial burst – glucose would rise to 60-70%, then fall back down as fatty acid transport is increased.

Question 24

Describe the order of cells in cardiac excitation?

Answer 24

SA -> atrial cells -> AV -> Bundle of His -> Purkinje -> ventricular cells

DO NOT confuse ventricular cells with bundle of his -> AV-Bundle of His-Purkinje is a highway that must be travelled before ventricular cells are reached

Question 25

What three factors influence conduction velocity in cardiac cells?

Answer 25

1) cell size : the smaller the cell, the more it resists to the workflow of current (think of it as really dense and less willing to let electron current in). pacemaker = nodal cells are really small, Purkinje cells are much bigger, so nodal cells have slower conduction velocity
2) number of gap junctions between cells: the more junctions the faster the current can travel. nodal cells have less junctions, Purkinje have more. nodal cells are slower
3) the rate of rise of action potential (slope of the graph) in phase 0. nodal cells have non-steep slope, Purkinje have really steep slope. nodal cells are slower.

Question 26

Refractory periods: relative vs absolute?

Answer 26

During the absolute refractory period no action potential is possible because the Na+ channels are inactivated. During the relative refractory period the magnitude and rate of rise of the action potential are proportional to the number of Na+ channels that have shifted from an inactivated configuration to closed.