L4 Cardiac Muscle & Electrical Activity I PDF

Summary

These lecture notes detail cardiac muscle and electrical activity, covering components of the cardiovascular system, the heart's location, pulmonary and systemic circulations, and the cardiac cycle. The notes also discuss cardiac muscle structure, myocardial cells, and excitation-contraction coupling.

Full Transcript

Lecture 04

Cardiac Muscle & Electrical Activity I

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 Components of Cardiovascular System

Heart
– Muscular pump which creates pressure head to push blood
through blood vessels

Blood vessels
– Conduits which permit blood flow from heart to cells and back to
the heart
– Arteries, arterioles, capillaries, venules, veins

Blood

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 Location of the Heart

Located in thoracic cavity
– Diaphragm separates
abdominal cavity
from thoracic cavity

Size of fist

Weighs approximately 250 –
350 g

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 Pulmonary and Systemic Circulations

Pulmonary capillaries
– Blood entering lungs =
deoxygenated blood
– Oxygen diffuses from tissue to
blood
– Blood leaving lungs =
oxygenated blood
Systemic capillaries
– Blood entering tissues =
oxygenated blood
– Oxygen diffuses from blood to
tissue
– Blood leaving tissues =
deoxygenated blood

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5
 Cardiac Cycle/Heartbeat

Rhythmic contraction and relaxation generates heart
pumping action
– Contraction pushes blood out of heart into vasculature
– Relaxation allows heart to fill with blood

Wave of contraction spreads through cardiac muscle

1. Both atria contract as a unit
2. Both ventricles contract as a unit

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 Cardiac Cycle

Contraction increases pressure while relaxation decreases
pressure
– Pressure difference drives blood flow (pressure gradient). Blood
moves from area of higher pressure to area of lower pressure

Pressure within chambers of heart varies during cardiac
cycle
– Atrial contraction precedes ventricle contraction
– Atrial pressure > ventricular pressure
– Blood flows simultaneously from both atria into both ventricles
– When ventricles contract, blood flows from ventricles to arteries

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 Cardiac Muscle

Contain actin and myosin
arranged in sarcomeres similar
to skeletal muscle cells
– Contract via sliding-filament
mechanism
Myocardial cells are short,
branched and join neighbouring
cells to create a complex
network
Adjacent myocardial cells
joined by intercalated discs
containing gap junctions

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 Myocardial Cells

Gap junctions are fluid filled channels that allow action
potentials spread rapidly from cell to cell

Therefore, myocardial cells contract almost simultaneously
– Cardiac muscle is a syncytium
– “All or nothing” property

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 Cardiac Muscle Contraction

Contraction of skeletal muscle requires external
stimulation by somatic motor nerves

Specialized noncontractile myocardial cells, autorhythmic
or pacemaker cells are responsible for triggering the
contraction of cardiac muscle

Cell membranes spontaneously depolarize and generate
APs which spread into surrounding contractile myocardial
cells
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 Sinoatrial Node
Autorhythmic cells are
concentrated in the sinoatrial
node located in the right atrium
near the opening of the superior
vena cava

Spontaneous depolarizations
generated here pass into
surrounding myocardial cells
and generate contraction as
follows:
– Atrial myocardial cells
– Pause (fibrous layer)
– Ventricular myocardial cells
– Atrial syncytium & ventricular
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syncytium
 Cardiac Conduction System

Spontaneous APs generated by
the autorhythmic cells in the SA
node spread to surrounding atrial
contractile myocytes and then
spread to the ventricles through
the cardiac conduction system

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 Atrial Conduction

Impulses spread through atrial fibres at rate of 1 m/sec

Specialized fibres, known as Bachmann’s bundle, conduct
the impulse from right into left atrium

Impulses then spread to the atrioventricular (AV) node

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 Atrioventricular Conduction

AV node is located on the base of the right atrium near the
interatrial septum
– Normally the only route of conduction from atria to ventricles

Conduction velocity slows to 0.05 m/sec
– This results in a delay between atrial and ventricular
excitation/contraction
– Permits optimal ventricular filling during atrial contraction

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 Ventricular Conduction

AV node conducts to the bundle
of His, then to the bundle
branches. The bundle branches
subdivide into a complex
network called the Purkinje
fibres. These conduct impulses
into both ventricles
Conduction velocity is of the
range 1 – 4 m/sec in Purkinje
fibres. This is due to their large
cell size (diameter: 80 mM)
compared to myocytes
(diameter: 15 mM)
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 Autorhythmic Cells

Location of these cells:
– 1 Sinoatrial (SA) node in right atrium. Most important location,
APs generated here spread over entire cardiac tissue. 70-80
APs/min

– 2 Atrioventricular (AV node). Are only generated if SA node is
destroyed as rate of firing is slower, 40-60 APs/min

– 3 Pacemaker cells are also located in the Purkinje fibres, 30-40
AP/min. Again, APs generated by SA node will normally inhibit
autorhythmic activity of these cells
 Cardiac Action Potentials

Two types of action potentials in individual cells in cardiac
tissue

– Fast response
Atrial and ventricular myocytes (contractile and conductive cells)

– Slow response
autorhythmic cells in sinoatrial (SA) node and atrioventricular (AV)
node

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Cardiac Action Potentials

Phase 0: Upstroke
Phase 1: Early repolarization
Phase 2: Plateau
Phase 3: Repolarization
Phase 4: Final repolarization

ERP: Effective refractory period
RRP: Relative refractory period

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 Myocardial Contractile Cells

Arrival of AP at a contractile
myocardial cell opens voltage-
gated Na+ channels (rapid
depolarization)
Voltage-gated Ca2+ channels
also open more slowly
At +20 mV, Na+ channels close
and K+ channels open;
repolarization begins
Slow inward diffusion of Ca2+
then balances outward
diffusion of K+ plateau phase
Ca2+ channels close and K+
channels complete
repolarization
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Fast Response Action Potential

K+ K+ K+
 Myocardial Cell Contraction

Inward movement of extracellular Ca2+ during depolarization
also opens Ca2+ channels on the sacroplasmic reticulum
– Extracellular Ca2+ is used to initiate contraction in myocardial cells
rather than intracellular stores

Increase in intracellular [Ca2+] triggers contraction in an
identical mechanism to skeletal muscle

During repolarization, Ca2+ is transported out of the cell and
relaxation occurs
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Excitation-Contraction Coupling

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Cardiac Muscle Contraction

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 Skeletal Muscle Contraction

A.P. in skeletal muscle cell is
fast (20 msec)
– No plateau phase

Cell has repolarised before
associated contraction has
begun

Cell is responsive to further
stimuli during contraction
– Summation of contraction (B)
– Tetany (C & D)

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 Myocardial Cell Contraction

The length of an AP in a
myocardial cell (250 msec) is
much longer than an AP in a
skeletal muscle cell (20 msec)
due to plateau phase
The duration of the AP is
almost as long as the associated
contraction
Myocardial cells are
refractory during almost their
entire contraction
Summation of contraction
cannot occur so tetany in
cardiac muscle is also prevented 25
 Ca2+ Channels

Number of different types in cardiac muscle but the
predominant are L-type Ca2+ channels (long-lasting)

Opening these channels increases conductance
– The large concentration gradient drives the influx of Ca2+

As well as prolonging the action potential, the Ca2+
influx also triggers the contraction of muscle fibres
– The greater the influx of Ca2+, the stronger the contraction

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 In the Clinic

Ca2+ channel antagonists such as
verapamil and diltiazem decrease
the duration of the action potential
and also diminish the contractility
of the myocardial cells

Increasing concentrations of
diltiazem diminish contractile
strength of the heart
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