Electrical Activity of the Heart Lecture II PDF

Summary

This document is a lecture presentation on the electrical activity of the heart. It covers the conduction system, pacemaker potentials, and action potentials in autorhythmic cells. The content includes diagrams and explanations related to cardiac physiology.

Full Transcript

ELECTRICAL ACTIVITY
OF
THE HEART
LECTURE II

Prof. Ahmed A Alsunni
Dr. Nazish Rafique

Department of Physiology
College of Medicine, IAU
 Objectives

Describe
The conducting system of the heart.

Understand The role of SA Node as a pacemaker.

Describe
SA Nodal action potential.

Pathophysiological basis of Cardiac
Undrstand
arrhythmias.

Tuesday, October 29, 2024 Presentation title
 Cardiac Muscle Cells

1% Autorhythmic Contractile 99%
Cells Cells

Initiate Do the
and conduct mechanical
action work of
potentials pumping
 Types of cardiac muscle cells

Contractile Cells
99% of Cardiac Muscle
Do mechanical work of contraction
Do not generate action Potential in normal
conditions
(Can generate Action Potential in abnormal
conditions)

Autorhythmic cells (1%)
Initiate Action Potential
Conduct Action Potential
Do not contract

Tuesday, October 29, 2024 Presentation title
 Route/ pathway of impulse transmission from SA node to the
ventricular contractile cells

Impulse is generated in the Sinoatrial (SA)
node by the process of autorhytmicity.

Is transmitted through the Internodal
pathway to the Atrioventricular (AV) node.

Is transmitted from atria to ventricles via
bundle of His( AV bundle)

Is transmitted to the ventricles through
the Purkinje fibers.

The action potentials are than rapidly
distributed to the cardiac contractile cells
through the gap junctions.
 Gap junction

Cardiac cell 1 Cardiac cell 2

Gap junctions are the areas of low electrical
resistance that allow the action potential
to spread from cell to cell.
Are there gap junctions between
atria and ventricular contractile
muscle cells?
Why?
Atria and ventricles
are separate pumps

There are no gap junctions between
atria and ventricle

They communicate only through the
specialized junctional tissue
 Spread of action potentials from the autorhythamic
to the contractile cells

Once the SA node
generates action potential,
it quickly passes to all
parts of the heart as a
wave of excitation.

This spread of cardiac
excitation occurs via
junctional tissue (through
AV Bundle) and gap
junctions.

Tuesday, October 29, 2024
 Both the gap junctions
and the fast conducting system
between the atria and ventricles
make the heart a:

Functional syncytium
 Generation of
pacemaker
potential

AND

Action potential
in autorhythmic
cells

Tuesday, October 29, 2024 Presentation title
 Pacemaker potential

In contrast to the nerve and muscle cells, in
which the membrane potential remains at
constant resting membrane potential (RMP)
unless the cell is stimulated, the cardiac
autorhythmic cells do not have a resting
membrane potential.

Instead, Cardiac autorhytmic cells display
pacemaker activity.

Their membrane potential slowly depolarizes
between the action potentials until the threshold
is achieved, at which time the membrane fires.

An autorhythmic cell’s drift to the threshold is
called as pacemaker potential.

Tuesday, October 29, 2024 Presentation title
 SA nodal Pacemaker potential
The first half of the pacemaker potential is
caused by:
1: The opening of funny Na channels(which
causes inward Na+ current).
2: The Closure of K+ channels ( which reduces
outward K current).

The second half of the pacemaker Potential is
caused by:
The opening of T-Type Ca+ channels( Which
causes inward Calcium+ current).

All these factors make the inside of the
membrane more positive, which helps to drift the
potential towards the threshold.

Tuesday, October 29, 2024
 ‘Fire’

DRIFT to
threshold

‘f ’ channels: ‘ f ’ from funny
T-Type Calcium Channels : “Transient” Calcium Channel
L-Type Calcium Channel : Longer Lasting Calcium Channel
P: Permeability
Tuesday, October 29, 2024 Presentation title
 SA nodal action potential

The rising phase of SA nodal action
potential is due to rapid influx of calcium.

The falling phase of SA nodal action
potential is due to the efflux of potassium.

Tuesday, October 29, 2024
 Autorhythmicity

Action Potential is generated within the specialized
heart cells(SA Node).

This generation of the action potential is rhythmic (60-
100/Min).

It spreads to the whole heart by specialized cardiac
muscle cells.

Which leads to Rhythmic Contraction of the Heart
(Heart Beat).

Tuesday, October 29, 2024 Presentation title
 Draw, label, and Compare the
“SA Nodal pacemaker potential”
with the
“Neuronal action potential”.

Tuesday, October 29, 2024 Presentation title
 Compare and contrast the action potentials of the neuron and autorhythmic cells.

Tuesday, October 29, 2024 28th 4
 Transmission of the
cardiac impulse
through the heart.

Tuesday, October 29, 2024 Presentation title
Rate of action potential discharge in the cardiac
autorhytmic cells.

SA Node= 70-80/Minute

AV Node= 60-70/Minute

Bundle of His= 20-
40/Minute

Purkinje Fibers= 20-40/
Minute
 Conduction velocity

AV Node = 0.02-0.1

Bundle Of His= 0.3-1

Purkinje fibers=4
 SA node as a pacemaker
SA Node is the pacemaker of the heart
because:

The cells with the fastest action potential Are
located in SA Node.
These fastest cells drive the rest of the heart.

Other autorhythmic cells, therefore, cannot
generate their own action potentials,
because before they can reach to the
threshold of their own they are activated by
the potentials originating in the SA node.

Tuesday, October 29, 2024
 Importance of AV Nodal delay
AV NODE HAS THE SLOWEST
CONDUCTION VELOCITY.
WHICH CAUSES AV NODAL DELAY.

It allows the atria to be excited and to
contract completely before the impulse
reaches His bundle.
Meanwhile, the ventricles get enough time
to be completely filled.

PURKINJE FIBERS ARE THE FASTEST
CONDUCTING CELLS.

This fast transmission ensures rapid and
simultaneous excitation and contraction of
both the ventricles.

Tuesday, October 29, 2024
 Generation and transmission of the cardiac
impulse through the heart

What is the physiological importance of slow
conduction of impulses through the AV node?

Why SA node is the pacemaker of the heart?

What is the physiological importance of fast
conduction of impulses through the purkinje
fibers?

Tuesday, October 29, 2024
 Abnormal cardiac
rhythms
(cardiac arrhythmias)

Tuesday, October 29, 2024 Presentation title
 ARRHYTHMIA
(Any Variation from the normal rhythm)

Major causes:
Shift of the pacemaker from the sinoatrial
node to other pacemaking regions.
Abnormal impulse formation in the
sinoatrial node.
Blocking or delay of conduction of the
impulse through the heart.
Spontaneous generation of abnormal
impulses in any region of the heart
through ectopic foci (e.g. atrial fibrillation,
atrial flutter ventricular fibrillation).

Tuesday, October 29, 2024 Presentation title
 Do you know what is the relationship between
ECG and
Action potentials?

ECG is a composite (combinad) recording
of all of the
action potentials produced by
the nodal and myocardial cells.

Tuesday, October 29, 2024 Presentation title
 ECG and action potentials

Tuesday, October 29, 2024 Presentation title
 The electrocardiogram (ECG):
It is the record of the heart’s
electrical activity, recorded
from the surface of the body.

Because the body is a very
good conductor therefore the
small currents generated in the
heart can be detected at the
body surface.

The ECG is a recording of these
small currents and reflects the
depolarization and
repolarization of different
regions of the heart.

Tuesday, October 29, 2024
 Normal ECG = 3 Phases
P WAVE = Atrial
activation
(atrial
depolarization)

QRS COMPLEX =
Activation of the
ventricles
(ventricular
depolarization)

T WAVE =
Recovery of the
ventricles
(ventricular
repolarization)

Tuesday, October 29, 2024
Reference to standard books

Page numbers 309-311
9th edition
Lauralee Sherwood.
Human Physiology form cells to systems.