Electrical activity of the heart, electromechanical coupling

Question 1

Types of myocytes/excitable tissues in the myocardium

Answer 1

• Pacemaker
• Conductive system
• Working fibers

Additional elements:

• Anulus fibrosus
• AV node

Question 2

What is membrane potential?

Answer 2

electrical differences measured between the outer and inner side of the membrane (sarcolemma)

Question 3

What is Resting membrane potential (RMP)?

Answer 3

electrical differences measured between the outer and inner side of the membrane in resting state

• Ca -90 mV
• In pacemaker cells RMP does not exist.
• In diastole, spontaneous deplarization occurs, followed by an AP.

Question 4

What is Action Potential (AP)?

Answer 4

Following certain stimuli, ion channels of the membrane open and the ion exchange between the two sides lead to electrical changes called Action Potential

Question 5

Pacemaker cells:

Answer 5

• Has no permanent resting membrane potential, but turns into constant depolarization (lifetime pacemaker)
• They are specialized heart muscle cells located in the sinoatrial and atrioventricular node.
• Their main role is the continuous generation of the excitation
• during repolarization the transmembrane potential reaches -55mV an automatic depolarization folloes.

Question 6

Cardiac cells that depolarize spontaneously toward treshold are called?

Answer 6

Pacemaker cells. Becuase they initiate heartbeats and therefore determine the rate, or pace, og the heart.

Question 7

Types of pacemaker cells:

Answer 7

• Round pacemaker cells: sites of the generation of the excitation
• Elongated or slender cells: Conduct and synchronize the excitation generated in the round pacemaker cells

Question 8

explain MDP

- Pacemaker fiber

Answer 8

Maximal Diastolic Potential (virtual resting membrane potential):
- slow Na+ channels open spontaneously - slow depolarization begins

Question 9

explain SDD

- Pacemaker fiber

Answer 9

Spontaneous Diastolic Depolarization:

- there is no RMP, from MDP till treshold potential

Question 10

explain overshoot

- Pacemaker fiber

Answer 10

Much lower positive values (+5/15mV) than in working fibers (+25 mV)

Question 11

Repolarization:

- pacemaker fiber

Answer 11

K+ efflux till MDP

Question 12

What type of calcium channels to the depolarization open in the pacemaker?

Answer 12

Type-T, rianodin sensitive and Type-L, DHP sensitive.

This opening causes calcium to flow from the EC into the cell creating a Transient Ca-influx.

Question 13

The deppolarization of the SA-node is due to?

- pacemaker cells

Answer 13

the long-lasting Ca channels (strong Ca influx)

Question 14

What happens by opening of the K-channels?

- pacemaker cells

Answer 14

It causes the efflux of K ions from the cell, repolarization begins.

Question 15

Natural factors influencing the heart rate:

Answer 15

by altering the activity of round cells in SA:

• Sympathetic effect
• Parasympathetic effect

And the Vagus escape

Question 16

What is the sympathetic effect stimulated by?

Answer 16

Beta-1-rec, which stimulates G-protein mediated IC cAMP increase, consequently non specific Na+ and K+ channels open.

Question 17

What happens when the sympathetic effect is stimulated?

Answer 17

• Non-specific Na? and K+ channel open.
• MDP shifted upwards,
• steepness of SDD increases
• treshold is reduced
  = the heart rate (Fr) is increased!

Question 18

The effect of the sympathetic effect can also be triggered by other signals, like what?

Answer 18

• Norepinephrine (neural signal)

- Epinephrine (endocrinological)

Question 19

What is the Parasympathetic effect stimulated by?

Answer 19

Acetylcholine (from vagal nerve endings) stimulate muscarinic acetylcholine receptors on round cells.

Question 20

What happens when the Parasympathetic effect is stimulated?

Answer 20

• cAMP decreases
• MDP is shifted down
• SDD slope decreases
• Treshold potential elevates
• Hyperpolarization occurs.
  = heart rate is decreased!

Question 21

What is the function of the n.vagus

Answer 21

It continous AP discharge slows down the original activity of the heart.

Question 22

What does chronotrop mean?

Answer 22

frequency, time of contraction

Question 23

What does Dromotrop mean?

Answer 23

speed of contraction

Question 24

What does Bathmotrop mean?

Answer 24

Treshold

Question 25

What does Inotrop mean?

Answer 25

Force of contraction

Question 26

Conduction system in small animals:

Answer 26

Subendocardial conduction = conductive fibers do not go deeply into working muscle

Question 27

Conduction system in Large animals:

Answer 27

Subepicardial conduction = deeply into ventricle

Question 28

what happens in the conduction system if the signal comes from the SA-node?

Answer 28

it results in nomotop excitation

Question 29

what happens in the conduction system if the signal comes from the AV-node?

Answer 29

that results in heterotop excitation

Question 30

What is the role of the Anulus Fibrosus in the conduction system?

Answer 30

it represents electric resistance - it synchronizes te atrio-ventric cooperation

Question 31

What are responsible for fast conduction?

Answer 31

His bundle -> Tawara bundles -> Purkinje fibers

Question 32

What is the role of Working fibers?

Answer 32

Generate unique, elongated AP (plateau), which prevents the heart from early secondary contraction.

Question 33

Ion flow during Action Potential in Working Fibers:

Answer 33

Phase 0: Depolarization: voltage-gated Na+ opens. These channels are inactivated at -25mV (overshoot)
Phase 1: Rapid repolarization: Short Cl- influx and K´efflux (early K+ channels)
Phase 2: Plateau: Slow Ca++ influx, and slow K+ efflux. Plateau phase is shorter closer to the epicardium.
Phase 3: Rapid repolarization: strong K+ (late K+ channels), Na + Ca ++ channels are active
Phase 4: Late hyperpolarization: At the end of the AP, membrane potential sinks below the RMP.

Question 34

what are the electrical properties of the heart?

Answer 34

• RMP

- Ion flow during Action Potential

Question 35

What are the voltage-gated channels?

Answer 35

The potential (voltage)- dependent Na channels open, inactivate and close in function of the actual potential difference. These channels are responsible for the generation of the AP

Question 36

What is the reason for that the Potassium conductance increases until the end of the AP?

Answer 36

In phase 1 of the AP, the early K channels, in phase 2 the slow K channels and in phae 3 the late K channels opens. This is the reason why the K concuctance increases until the end of the AP

Question 37

What is the role of the Plateau phase?

Answer 37

To prevent a premature generation of a new AP

Question 38

refractory phases of Working heart muscle fibers:

Answer 38

• Absolute refractory phase
• Relative refractory phase
• Supernormal phase

Question 39

Explain Abosolute refractory phase:

Answer 39

• No stimulus (independetly of the stregth) can elicit a new AP before the end of phase 2(plateau) in the working fiber of the heart
• rational: in this phase all necessary ion channels that participate in the depolarization are either in use or inactive.

Question 40

Explain Relative refractory phase:

Answer 40

• A stimulus given after the end of the plateau phase but before reaching the treshold potential elicits an answer in function of the strength of the stimulus.
• Strong stimuli can elicit the formation of a new AP. This phase is therefore named Relative Refractory Phase..
• Rational: some ion channels are active again (after inactive state), but not all. Therefore only stronger stimuli can cause enough strong depolarization effect.

Question 41

Explain Supernormal phase:

Answer 41

• from the practical point of view the most important period is the one between the treshold and the RMP
• A slight stimulus can elicit a new AP, and produce a premature new contraction.
• A non-working (sick) fiber generates a small battery and stimulates the normal working fibers, when they go into their SNP. this lead to renewed premature contractions and can be fatal when it happens in the ventricle (fibrillation)

Question 42

Explain Atrial Fibrillation:

Answer 42

• i.e electrical stimulation of the atrium, repeated premature contrctions, the normal atrial stimulus stops.
• The ventricle maintains the normal circulatory pressure
• It is not lethal!

Question 43

Explain Ventricular Fibrillation:

Answer 43

• The normal blood pressure can nt be maintained, it may drop to 0, normal systole and diastole disappear
• this is lethal!

Question 44

Explain defibrillation

Answer 44

With strong electric current, desynchronization is stopped, SA node is synchronized again, and we have normal rythm generation, so nomotop excitation is back

Question 45

Difference between AP and mechanogram of cardiac and skeletal muscle:

Answer 45

• There is no plateau phase of the skeletal AP
• the skeletal AP lasts for millisec in contrast to the 200msec AP of the heart.
• The cardiac mechanogram is almost parallel with the AP
• the mechanogram of the skeletal develops only after the AP has vanished.

Question 46

Definition of Electromechanical coupling

Answer 46

Connection between electric stimulus (excitation) and mechanical signal (contraction)

Question 47

what is the structural unit of the cardiac muscle in electromechanical coupling?

Answer 47

DIAD, (in skeletal muscle: Triad)

Question 48

Steps in electromechanical coupling:

Answer 48

1. AP spreds onto the cell
2. AP reaches the T-tubules and activates the tubular L-type Ca++ channel (voltage-gated, DHP sensitive channels)
3. Conformation changes of L-type channels opens the T-type channels on the SR (rianodin-sensitive channels)
   A large amount of Ca gets into the sarcoplasma from SR.
4. Elevating sarcoplasmic level of Ca++ opens the Ca++ dependent Ca++ channels on the SR.
5. And elevating sarcoplasmic level of Ca++ also opens the Ca++-dependent Ca++ channels on the cell membrane (sarcolemma).
6. RESULT = huge amount of Intra Cytoplasmic Ca++ is around the sarcomers –> CONTRACTION

Question 49

Elimination of Calcium signal in electrochemical coupling

Answer 49

Happens after the contraction (but starts during the contraction).

1. Na+/Ca2+ antiporter into extracellular space.
2. ATP-dependent Ca2+ transporter into SR.

• IC Ca2+ concentration decreases, leading to RELAXATION