Cardiovascular Physiology PDF

Summary

This document provides an overview of cardiovascular physiology, focusing on the rhythmical excitation of the heart and abnormal heart rhythms. It details the specialized excitatory and conductive system of the heart, including the sinus node and its function as the heart's pacemaker.

Full Transcript

CARDIOVASCULAR PHYSIOLOGY

Rhythmical Excitation of the Heart
And Abnormal Rythms

PROF. DR. BARLAS N. AYTAÇOĞLU
CARDIOVASCULAR SURGEON
GAU FACULTY OF MEDICINE
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
The heart is endowed with a special system for
– (1) generating rhythmical electrical impulses to cause
rhythmical contraction of the heart muscle and
– (2) conducting these impulses rapidly
through the heart.

When this system functions normally, the atria contract
about one sixth of a second ahead of ventricular
contraction, which allows filling of the ventricles before
they pump the blood through the lungs and peripheral
circulation.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Another special importance of the system is that it allows
all portions of the ventricles to contract almost
simultaneously, which is essential for most effective
pressure generation in the ventricular chambers.

This rhythmical and conductive system of the heart is
susceptible to damage by heart disease, especially by
ischemia of the heart tissues resulting from poor coronary
blood flow.

The effect is often a bizarre heart rhythm or abnormal
sequence of contraction of the heart chambers, and the
pumping effectiveness of the heart often is affected
severely, even to the extent of causing death.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Specialized Excitatory and Conductive System of the
Heart
Figure 1 shows the specialized excitatory and conductive
system of the heart that controls cardiac contractions.

FIGURE 1
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Specialized Excitatory and Conductive System of the
Heart

The figure shows the sinus node (also called sinoatrial or
S-A node), in which the normal rhythmical impulses are
generated; the internodal pathways that conduct impulses
from the sinus node to the atrioventricular (A-V) node; the
A-V node, in which impulses from the atria are delayed
before passing into the ventricles; the A-V bundle, which
conducts impulses from the atria into the ventricles; and
the left and right bundle branches of Purkinje fibers,
which conduct the cardiac impulses to all parts of the
ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Specialized Excitatory and Conductive System of the
Heart
– Sinus (Sinoatrial) Node

The sinus node (also called sinoatrial node [In short
SA or SAN]) is a small, flattened, ellipsoid strip of
specialized cardiac muscle about 3 millimeters wide,
15 millimeters long, and 1 millimeter thick.

It is located in the superior posterolateral wall of the
right atrium immediately below and slightly lateral to
the opening of the superior vena cava.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Specialized Excitatory and Conductive System of the
Heart
– Sinus (Sinoatrial) Node
The fibers of this node have almost no contractile
muscle filaments and are each only 3 to 5
micrometers in diameter, in contrast to a diameter of
10 to 15 micrometers for the surrounding atrial
muscle fibers.

However, the sinus nodal fibers connect directly with
the atrial muscle fibers so that any action potential
that begins in the sinus node spreads immediately
into the atrial muscle wall.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms
Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Some cardiac fibers have the capability of self-
excitation, a process that can cause automatic
rhythmical discharge and contraction.

This is especially true of the fibers of the heart’s
specialized conducting system, including the fibers
of the sinus node.

For this reason, the sinus node ordinarily controls
the rate of beat of the entire heart.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Automatic Electrical
Rhythmicity of the Sinus
Fibers
FIGURE 2
Mechanism of Sinus
Nodal Rhythmicity.
– Figure 2 shows action
potentials recorded from
inside a sinus nodal fiber for
three heartbeats and, by
comparison, a single
ventricular muscle fiber action
potential.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Automatic Electrical
Rhythmicity of the Sinus
Fibers
FIGURE 2
Mechanism of Sinus
Nodal Rhythmicity.
– Note that the “resting
membrane potential” of the
sinus nodal fiber between
discharges has a negativity of
about −55 to −60 millivolts, in
comparison with −85 to −90
millivolts for the ventricular
muscle fiber.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Automatic Electrical
Rhythmicity of the Sinus
Fibers
FIGURE 2
Mechanism of Sinus
Nodal Rhythmicity.
– The cause of this lesser
negativity is that the cell
membranes of the sinus fibers
are naturally leaky to sodium
and calcium ions, and positive
charges of the entering
sodium and calcium ions
neutralize some of the
intracellular negativity.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Mechanism of Sinus Nodal Rhythmicity.

– Opening of the fast sodium channels for a few 10,000 ths of
a second is responsible for the rapid upstroke spike of the
action potential observed in ventricular muscle, because of
rapid influx of positive sodium ions to the interior of the
fiber.

– Then the “plateau” of the ventricular action potential is
caused primarily by slower opening of the slow sodium-
calcium channels, which lasts for about 0.3 second.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Mechanism of Sinus Nodal Rhythmicity.

– Finally, opening of potassium channels allows diffusion of
large amounts of positive potassium ions in the outward
direction through the fiber membrane and returns the
membrane potential to its resting level.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Mechanism of Sinus Nodal Rhythmicity.

– There is a difference in the function of these channels in the
sinus nodal fiber because the “resting” potential is much
less negative—only −55 millivolts in the nodal fiber instead
of the −90 millivolts in the ventricular muscle fiber.

– At this level of −55 millivolts, the fast sodium channels
mainly have already become “inactivated,” which means
that they have become blocked.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Mechanism of Sinus Nodal Rhythmicity.

– The cause of this is that any time the membrane potential
remains less negative than about −55 millivolts for more
than a few milliseconds, the inactivation gates on the inside
of the cell membrane that close the fast sodium channels
become closed and remain so.

– Therefore, only the slow sodium-calcium channels can
open (i.e., can become “activated”) and thereby cause the
action potential.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Mechanism of Sinus Nodal Rhythmicity.

– As a result, the atrial nodal action potential is slower to
develop than the action potential of the ventricular
muscle.

– Also, after the action potential does occur, return of
the potential to its negative state occurs slowly as well,
rather than the abrupt return that occurs for the
ventricular fiber.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.

– Because of the high sodium ion concentration in the
extracellular fluid outside the nodal fiber, as well as a
moderate number of already open sodium channels,
positive sodium ions from outside the fibers normally
tend to leak to the inside.

– Therefore, between heartbeats, influx of positively
charged sodium ions causes a slow rise in the resting
membrane potential in the positive direction.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.
– The “resting” potential gradually rises and becomes
less negative between each two heartbeats.

FIGURE 2
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.
– When the potential reaches a threshold voltage of
about −40 millivolts, the sodium-calcium channels
become “activated,” thus causing the action potential.

FIGURE 2
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.

– Therefore, basically, the inherent leakiness of the
sinus nodal fibers to sodium and calcium ions causes
their self-excitation.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.
– Why does this leakiness to sodium and calcium ions
not cause the sinus nodal fibers to remain depolarized
all the time?
– The answer is that two events occur during the course
of the action potential to prevent this.
» First, the sodium-calcium channels become
inactivated (i.e., they close) within about 100 to 150
milliseconds after opening, and
» Second, at about the same time, greatly increased
numbers of potassium channels open.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.
– Therefore, influx of positive calcium and sodium ions
through the sodium-calcium channels ceases, while at
the same time large quantities of positive potassium
ions diffuse out of the fiber.

– Both of these effects reduce the intracellular potential
back to its negative resting level and therefore
terminate the action potential.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.
– Furthermore, the potassium channels remain open for
another few tenths of a second, temporarily continuing
movement of positive charges out of the cell, with
resultant excess negativity inside the fiber; this is
called hyperpolarization.

– The hyperpolarization state initially carries the
“resting” membrane potential down to about −55 to
−60 millivolts at the termination of the action potential.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.

– Why is this new state of hyperpolarization not maintained forever?

– The reason is that during the next few tenths of a second after the
action potential is over, progressively more and more potassium
channels close.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.

– The inward-leaking sodium and calcium ions once
again overbalance the outward flux of potassium ions,
and this causes the “resting” potential to drift upward
once more, finally reaching the threshold level for
discharge at a potential of about −40 millivolts.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Automatic Electrical Rhythmicity of the Sinus Fibers
Self-Excitation of Sinus Nodal Fibers.

– Then the entire process begins again: self-excitation to
cause the action potential, recovery from the action
potential, hyperpolarization after the action potential is
over, drift of the “resting” potential to threshold, and
finally re-excitation to elicit another cycle.

– This process continues indefinitely throughout a
person’s life.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Internodal Pathways and Transmission of the Cardiac
Impulse Through the Atria
The ends of the sinus nodal fibers connect directly with
surrounding atrial muscle fibers.

Therefore, action potentials originating in the sinus node
travel outward into these atrial muscle fibers.

In this way, the action potential
spreads through the entire atrial
muscle mass and, eventually,
to the A-V node.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Internodal Pathways and Transmission of the Cardiac
Impulse Through the Atria
The velocity of conduction in most atrial muscle is about
0.3 m/sec, but conduction is more rapid, about 1 m/sec,
in several small bands of atrial fibers.

One of these, called the anterior inter-atrial band, passes
through the anterior walls of the atria to the left atrium.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Internodal Pathways and
Transmission of the
Cardiac Impulse
Through the Atria
In addition, three other small
bands curve through the
anterior, lateral, and posterior
atrial walls and terminate in
the A-V node; shown in
Figure 3, these are called,
respectively, the anterior,
middle, and posterior
internodal pathways.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Atrioventricular Node and Delay of Impulse Conduction
from the Atria to the Ventricles
The atrial conductive system is organized so that the cardiac
impulse does not travel from the atria into the ventricles too
rapidly; this delay allows time for the atria to empty their blood
into the ventricles before ventricular contraction begins.

It is primarily the A-V node and its adjacent conductive fibers
that delay this transmission into the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Atrioventricular Node and Delay of Impulse Conduction
from the Atria to the Ventricles
The A-V node is located in the posterior wall of the
right atrium immediately behind the tricuspid valve,
as shown in Figure 2.

FIGURE 2
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
Figure 3 shows
diagrammatically the
different parts of this
node, plus its connections
with the entering atrial
internodal pathway fibers
and the exiting A-V
bundle.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
The figure also shows the
approximate intervals of
time in fractions of a
second between initial
onset of the cardiac
impulse in the sinus node
and its subsequent
appearance in the A-V
nodal system.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
Note that the impulse,
after traveling through the
internodal pathways,
reaches the A-V node
about 0.03 second after its
origin in the sinus node.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
Then there is a delay of
another 0.09 second in
the A-V node itself before
the impulse enters the
penetrating portion of the
A-V bundle, where it
passes into the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
A final delay of another
0.04 second occurs
mainly in this penetrating
A-V bundle, which is
composed of multiple
small fascicles passing
through the fibrous tissue
separating the atria from
the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
Thus, the total delay in the
A-V nodal and A-V bundle
system is about 0.13
second.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
FIGURE 3
Conductive System of the
Heart
– Atrioventricular Node
and Delay of Impulse
Conduction from the
Atria to the Ventricles
This, in addition to the
initial conduction delay of
0.03 second from the
sinus node to the A-V
node, makes a total delay
of 0.16 second before the
excitatory signal finally
reaches the contracting
muscle of the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Atrioventricular Node and Delay of Impulse Conduction
from the Atria to the Ventricles
Cause of the Slow Conduction.
– The slow conduction in the transitional, nodal, and
penetrating A-V bundle fibers is caused mainly by
diminished numbers of gap junctions between
successive cells in the conducting pathways, so there
is great resistance to conduction of excitatory ions
from one conducting fiber to the next.

– Therefore, it is easy to see why each succeeding cell
is slow to be excited.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System
Special Purkinje fibers lead from the A-V node through the A-V
bundle into the ventricles.

They are very large fibers, even
muscle fibers, and they transmit
action potentials at a velocity of
1.5 to 4.0 m/sec, a velocity about
6 times that in the usual ventricular
muscle and 150 times that in some
of the A-V nodal fibers.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System

This allows almost instantaneous transmission of the
cardiac impulse throughout the entire remainder of
the ventricular muscle.

The rapid transmission of action potentials by
Purkinje fibers is believed to be caused by a very
high level of permeability of the gap junctions at the
intercalated discs between the successive cells that
make up the Purkinje fibers.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System

Therefore, ions are transmitted easily from one cell
to the next, thus enhancing the velocity of
transmission.

The Purkinje fibers also have very few myofibrils,
which means that they contract little or not at all
during the course of impulse transmission.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System
One-Way Conduction Through the A-V Bundle.
– A special characteristic of the A-V bundle is the
inability, except in abnormal states, of action
potentials to travel backward from the ventricles to
the atria.

– This prevents re-entry of cardiac impulses by this
route from the ventricles to the atria, allowing only
forward conduction from the atria to the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System
One-Way Conduction Through the A-V Bundle.
– Furthermore, it should be recalled that
everywhere, except at the A-V bundle, the atrial
muscle is separated from the ventricular muscle
by a continuous fibrous barrier.

– This barrier normally acts as an insulator to
prevent passage of the cardiac impulse between
atrial and ventricular muscle through any other
route besides forward conduction through the A-V
bundle itself.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Rapid Transmission in the
Ventricular Purkinje System
Distribution of the Purkinje Fibers FIGURE 1
in the Ventricles— The Left and
Right Bundle Branches.
– After penetrating the fibrous
tissue between the atrial and
ventricular muscle, the distal
portion of the A-V bundle passes
downward in the ventricular
septum for 5 to 15 millimeters
toward the apex of the heart, as
shown in Figure 1.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Rapid Transmission in the
Ventricular Purkinje System
Distribution of the Purkinje Fibers FIGURE 1
in the Ventricles— The Left and
Right Bundle Branches.

– Then the bundle divides into
left and right bundle
branches that lie beneath the
endocardium on the two
respective sides of the
ventricular septum.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Rapid Transmission in the
Ventricular Purkinje System
Distribution of the Purkinje Fibers FIGURE 1
in the Ventricles— The Left and
Right Bundle Branches.
– Each branch spreads downward
toward the apex of the ventricle,
progressively dividing into
smaller branches.

– These branches in turn course
sidewise around each ventricular
chamber and back toward the
base of the heart.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the
Heart
– Rapid Transmission in the
Ventricular Purkinje System
Distribution of the Purkinje Fibers FIGURE 1
in the Ventricles— The Left and
Right Bundle Branches.

– The ends of the Purkinje
fibers penetrate about one
third of the way into the
muscle mass and finally
become continuous with
the cardiac muscle fibers.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Rapid Transmission in the Ventricular Purkinje System
Distribution of the Purkinje Fibers in the Ventricles—
The Left and Right Bundle Branches.
– From the time the cardiac impulse enters the bundle
branches in the ventricular septum until it reaches the
terminations of the Purkinje fibers, the total elapsed
time averages only 0.03 second.

– Therefore, once the cardiac impulse enters the
ventricular Purkinje conductive system, it spreads
almost immediately to the entire ventricular muscle
mass.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Transmission of the Cardiac Impulse in the Ventricular
Muscle

Once the impulse reaches the ends of the Purkinje
fibers, it is transmitted through the ventricular muscle
mass by the ventricular muscle fibers themselves.

The velocity of transmission is now only 0.3 to 0.5
m/sec, one sixth that in the Purkinje fibers.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Transmission of the Cardiac Impulse in the Ventricular
Muscle

Because of this, transmission from the endocardial
surface to the epicardial surface of the ventricle
requires as much as another 0.03 second,
approximately equal to the time required for
transmission through the entire ventricular portion of
the Purkinje system.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Transmission of the Cardiac Impulse in the Ventricular
Muscle

Thus, the total time for transmission of the cardiac
impulse from the initial bundle branches to the last of
the ventricular muscle fibers in the normal heart is
about 0.06 second.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the Heart
– Summary of the Spread of the
Cardiac Impulse Through the
Heart
Figure 4 shows in summary form the FIGURE 4
transmission of the cardiac impulse
through the human heart.

The numbers on the figure represent
the intervals of time, in fractions of a
second, that lapse between the origin
of the cardiac impulse in the sinus
node and its appearance at each
respective point in the heart.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and
Conductive System of the Heart
– Summary of the Spread of the
Cardiac Impulse Through the
Heart
Note that the impulse spreads at FIGURE 4
moderate velocity through the atria but
is delayed more than 0.1 second in the
A-V nodal region before appearing in
the ventricular septal A-V bundle.

Once it has entered this bundle, it
spreads very rapidly through the
Purkinje fibers to the entire
endocardial surfaces of the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Specialized Excitatory and Conductive System of the
Heart
– Summary of the Spread of the Cardiac Impulse
Through the Heart

It is important that the student learn in detail the
course of the cardiac impulse through the heart and
the precise times of its appearance in each separate
part of the heart, because a thorough quantitative
knowledge of this process is essential to the
understanding of electrocardiography.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart

In some abnormal conditions, impulses may not
arise from the S-A node.

Other parts of the heart can also exhibit intrinsic
rhythmical excitation in the same way that the sinus
nodal fibers do; this is particularly true of the A-V
nodal and Purkinje fibers.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart

The A-V nodal fibers, when not stimulated from
some outside source, discharge at an intrinsic
rhythmical rate of 40 to 60 times per minute, and the
Purkinje fibers discharge at a rate somewhere
between 15 and 40 times per minute.

These rates are in contrast to the normal rate of the
sinus node of 70 to 80 times per minute.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Why then does the sinus node rather than the A-V node or the
Purkinje fibers control the heart’s rhythmicity?

The answer derives from the fact that the discharge rate of the sinus
node is considerably faster than the natural self-excitatory discharge
rate of either the A-V node or the Purkinje fibers.

Each time the sinus node discharges, its impulse is conducted into
both the A-V node and the Purkinje fibers, also discharging their
excitable membranes.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart

But the sinus node discharges again before either
the A-V node or the Purkinje fibers can reach their
own thresholds for self-excitation.

Therefore, the new impulse from the sinus node
discharges both the A-V node and the Purkinje fibers
before self-excitation can occur in either of these.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart

Thus, the sinus node controls the beat of the heart
because its rate of rhythmical discharge is faster
than that of any other part of the heart.

Therefore, the sinus node is virtually always the
pacemaker of the normal heart.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– Occasionally some other part of the heart
develops a rhythmical discharge rate that is more
rapid than that of the sinus node.

– For instance, this sometimes occurs in the A-V
node or in the Purkinje fibers when one of these
becomes abnormal.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– In either case, the pacemaker of the heart shifts
from the sinus node to the A-V node or to the
excited Purkinje fibers.

– Under rarer conditions, a place in the atrial or
ventricular muscle develops excessive excitability
and becomes the pacemaker.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– A pacemaker elsewhere than the sinus node is
called an “ectopic” pacemaker.

– An ectopic pacemaker causes an abnormal
sequence of contraction of the different parts of
the heart and can cause significant debility of
heart pumping.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– Another cause of shift of the pacemaker is
blockage of transmission of the cardiac impulse
from the sinus node to the other parts of the
heart.

– The new pacemaker then occurs most frequently
at the A-V node or in the penetrating portion of
the A-V bundle on the way to the ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– When A-V block occurs—that is, when the cardiac
impulse fails to pass from the atria into the
ventricles through the A-V nodal and bundle
system—the atria continue to beat at the normal
rate of rhythm of the sinus node, while a new
pacemaker usually develops in the Purkinje
system of the ventricles and drives the ventricular
muscle at a new rate somewhere between 15 and

40 beats per minute.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– After sudden A-V bundle block, the Purkinje
system does not begin to emit its intrinsic
rhythmical impulses until 5 to 20 seconds later
because, before the blockage, the Purkinje fibers
had been “over-driven” by the rapid sinus
impulses and, consequently, are in a suppressed
state.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Sinus Node as the Pacemaker of the Heart
Abnormal Pacemakers—“Ectopic” Pacemaker.

– During these 5 to 20 seconds, the ventricles fail to
pump blood, and the person faints after the first 4
to 5 seconds because of lack of blood flow to the
brain.

– This delayed pickup of the heartbeat is called
Stokes-Adams syndrome. If the delay period is
too long, it can lead to death.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Role of the Purkinje System in Causing Synchronous
Contraction of the Ventricular Muscle Sinus Node as
the Pacemaker of the Heart
The cardiac impulse arrives at almost all portions of
the ventricles within a narrow span of time, exciting
the first ventricular muscle fiber only 0.03 to 0.06
second ahead of excitation of the last ventricular
muscle fiber.

This causes all portions of the ventricular muscle in
both ventricles to begin contracting at almost the
same time and then to continue contracting for about
another 0.3 second.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves

The heart is supplied with both sympathetic and
parasympathetic nerves, as shown in Figure 5.

FIGURE 5
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
The parasympathetic nerves (the vagi) are
distributed mainly to the S-A and A-V nodes, to a
lesser extent to the muscle of the two atria, and very
little directly to the ventricular muscle.

The sympathetic nerves, conversely, are distributed
to all parts of the heart, with strong representation to
the ventricular muscle, as well as to all the other
areas.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
Parasympathetic (Vagal) Stimulation Can Slow or
Even Block Cardiac Rhythm and Conduction
—“Ventricular Escape.”
– Stimulation of the parasympathetic nerves to the heart (the
vagi) causes the hormone acetylcholine to be released at
the vagal endings.

– This hormone has two major effects on the heart.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
Parasympathetic (Vagal) Stimulation Can Slow or
Even Block Cardiac Rhythm and Conduction
—“Ventricular Escape.”
– First, it decreases the rate of rhythm of the sinus node,

– Second, it decreases the excitability of the A-V junctional
fibers between the atrial musculature and the A-V node,
thereby slowing transmission of the cardiac impulse into the
ventricles.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
Parasympathetic (Vagal) Stimulation Can Slow or
Even Block Cardiac Rhythm and Conduction
—“Ventricular Escape.”
– Weak to moderate vagal stimulation slows the rate of heart
pumping, often to as little as one-half normal.

– Strong stimulation of the vagi can stop completely the
rhythmical excitation by the sinus node or block completely
transmission of the cardiac impulse from the atria into the
ventricles through the A-V mode.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
Parasympathetic (Vagal) Stimulation Can Slow or
Even Block Cardiac Rhythm and Conduction
—“Ventricular Escape.”
– In either case, rhythmical excitatory signals are no longer
transmitted into the ventricles.

– The ventricles stop beating for 5 to 20 seconds, but then
some small area in the Purkinje fibers, usually in the
ventricular septal portion of the A-V bundle, develops a
rhythm of its own and causes ventricular contraction at a
rate of 15 to 40 beats per minute.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction
by the Cardiac Nerves: Sympathetic and
Parasympathetic Nerves
Parasympathetic (Vagal) Stimulation Can Slow or Even
Block Cardiac Rhythm and Conduction—“Ventricular
Escape.”

– This phenomenon is called ventricular escape.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Mechanism of the Vagal Effects.

– The acetylcholine released at the vagal nerve endings
greatly increases the permeability of the fiber membranes
to potassium ions, which allows rapid leakage of potassium
out of the conductive fibers.

– This causes increased negativity inside the fibers, an effect
called hyperpolarization, which makes this excitable tissue
much less excitable.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Mechanism of the Vagal Effects.

– In the sinus node, the state of hyperpolarization decreases
the “resting” membrane potential of the sinus nodal fibers to
a level considerably more negative than usual, to −65 to
−75 millivolts rather than the normal level of −55 to −60
millivolts.

– Therefore, the initial rise of the sinus nodal membrane
potential caused by inward sodium and calcium leakage
requires much longer to reach the threshold potential for
excitation.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Mechanism of the Vagal Effects.

– This greatly slows the rate of rhythmicity of these nodal
fibers.

– If the vagal stimulation is strong enough, it is possible to
stop entirely the rhythmical self-excitation of this node.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
– Mechanism of the Vagal Effects.

– In the A-V node, a state of hyperpolarization caused by
vagal stimulation makes it difficult for the small atrial fibers
entering the node to generate enough electricity to excite
the nodal fibers.

– Therefore, the safety factor for transmission of the cardiac
impulse through the transitional fibers into the A-V nodal
fibers decreases.

– A moderate decrease simply delays conduction of the
impulse, but a large decrease blocks conduction entirely.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Effect of Sympathetic Stimulation on Cardiac Rhythm and
Conduction.
– Sympathetic stimulation causes essentially the opposite
effects on the heart to those caused by vagal stimulation,
as follows:

» First, it increases the rate of sinus nodal discharge.

» Second, it increases the rate of conduction, as well as
the level of excitability in all portions of the heart.

» Third, it increases greatly the force of contraction of all
the cardiac musculature, both atrial and ventricular
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Effect of Sympathetic Stimulation on Cardiac Rhythm and
Conduction.

– In short, sympathetic stimulation increases the overall
activity of the heart. Maximal stimulation can almost triple
the frequency of heartbeat and can increase the strength of
heart contraction as much as twofold.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Effect of Sympathetic Stimulation on Cardiac Rhythm and
Conduction.
– Mechanism of the Sympathetic Effect.
» Stimulation of the sympathetic nerves releases the
hormone norepinephrine at the sympathetic nerve endings.

» Norepinephrine in turn stimulates beta-1 adrenergic
receptors, which mediate the effects on heart rate.

» The precise mechanism by which beta-1 adrenergic
stimulation acts on cardiac muscle fibers is somewhat
unclear, but the belief is that it increases the permeability of
the fiber membrane to sodium and calcium ions.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Effect of Sympathetic Stimulation on Cardiac Rhythm and
Conduction.
– Mechanism of the Sympathetic Effect.

» In the sinus node, an increase of sodium-calcium
permeability causes a more positive resting potential and
also causes increased rate of upward drift of the diastolic
membrane potential toward the threshold level for self-
excitation, thus accelerating self-excitation and, therefore,
increasing the heart rate.
 CARDIOVASCULAR PHYSIOLOGY
Rhythmical Excitation of the Heart And Abnormal Rythms

Control of Excitation and Conduction in the Heart
– Control of Heart Rhythmicity and Impulse Conduction by the
Cardiac Nerves: Sympathetic and Parasympathetic Nerves
Effect of Sympathetic Stimulation on Cardiac Rhythm and
Conduction.
– Mechanism of the Sympathetic Effect.
» In the A-V node and A-V bundles, increased sodium-
calcium permeability makes it easier for the action potential
to excite each succeeding portion of the conducting fiber
bundles, thereby decreasing the conduction time from the
atria to the ventricles.

» The increase in permeability to calcium ions is at least
partially responsible for the increase in contractile strength
of the cardiac muscle under the influence of sympathetic
stimulation, because calcium ions play a powerful role in
exciting the contractile process of the myofibrils.