L1+2- Cardiovascular system (C.Nutrition 2024).pdf

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The Cardiovascular System

Dr. Eman Alsultan
Department of Physiology
College of Medicine
Imam Abdulrahman Bin Faisal University
Lecture-1
 The 3
Components
of the
circulatory
system
 The Heart
A hollow muscular organ
Located in the thoracic cavity midline between sternum anteriorly and
vertebrae posteriorly
Divided into two halves
Each half has 2 chambers : an atrium and a ventricle
Right & Left Atrium
Right & left Ventricle
Atria receive blood returning to the heart
Right Atrium receives deoxygenated blood from all of the body
Left Atrium receives oxygenated blood from the Lungs
Ventricles pump the blood from the heart.
Right ventricle to the lungs (deoxygenated blood)
Left ventricle to all the rest of the body (oxygenated blood)
Oxygenated & Unoxygenated blood
 The Two major divisions of the Circulation
Systemic Circulation Pulmonary Circulation
Deoxygenated

Right atrium.
Oxygenated
Left ventricle Left Atrium→ Right ventricle
→ →

Veins → Pulmonary
superior & Aortic valve
Pulmonary valve →
inferior vena → aorta→ Pulmonary
Veins →
cava→ Artery→

Arteries → Lungs
Arterioles →
Capillaries → Pulmonary
venules → Capillaries→
Technically heart is a dual
(double) pump

The Right Pump & The Left Pump
 The function of the heart is to Pump
Heart pumps all the blood coming into it, with sufficient pressure, around the body, in cycles.
 The Cardiac Cycle

The cardiac events that occur from the beginning of one heartbeat to
the beginning of the next.
Transport
(The function of circulation)

Blood cells (RBC , WBC,
Platelets)
O2 & CO2
Nutrients delivery
Metabolic wastes removal
Water & electrolytes balance
Hormones, enzymes and other
proteins
Immune defense
Thicker left ventricular wall

Both sides of the heart simultaneously
pump equal amounts of blood.
The left side of the heart performs more
work because it pumps blood at a higher
pressure against higher resistance.
The heart muscle on the left side is
therefore much thicker than the muscle on
the right side.
 Blood must flow through the heart in a fixed direction

Presence of 4 one-way
heart valves ensure
this unidirectional flow
 Mechanism of working of one-way valves

When pressure is greater behind When pressure is greater in front
the valve, it opens. of the valve, it closes
The Heart is made up of Cardiac Muscle Cells
 Cardiac muscle cells

There are two specialized types of cardiac muscle cells:
Contractile cells (99 %): they do mechanical work of pumping
(contraction)

Autorhythmic cells (1 %): they are specialized for initiating and
conducting the action potentials responsible for contraction of
the contractile cells.
 Adjacent cardiac muscle cells join end-to-
end by intercalated discs.
Intercalated discs have desmosomes &
gap junctions.
Desmosomes mechanically hold cardiac
cells together and convey the force of
contraction.
Gap junctions are the areas of low
electrical resistance that allow the action
potential to spread from cell to cell
atria and ventricles
are separate pumps

There are no gap junctions between
atria and ventricles

They communicate only through the
specialized junctional tissue (AV node)
 Heart is a functional
syncytium
Syncytium is an arrangement of muscle fibers in
which the fibers fuse to form an interconnected
mass of fibers.
This leads to all fibers contracting and relaxing
together.
Both the atria contract (systole) together first,
after a little while both the ventricles contract
together while atria are relaxing (diastole). This is
followed by relaxation of ventricles
Both the gap junctions and the fast-conducting
system between the atria and ventricles make the
heart a functional syncytium
 Origin & spread
of cardiac impulse
SA NODE TO
BOTH ATRIA Origin & spread of
cardiac impulse
INTERNODAL
PATHWAYS

AV NODE

AV BUNDLE

BUNDLE
BRANCHES

PURKINJE
FIBRES
 The cells with
the fastest rate
of action potential
are located in the SA node

SA node is therefore the pacemaker of the heart
Rate of action potential discharge / minute

SA node 70-80

AV node 40-60

Bundle of His 20-40

Purkinje fibers 20-40
Conduction velocity (m/Sec)

(AV node) nodal fibers 0.02 - 0.1 (Slowest)

Bundle of His 0.3 - 1

Purkinje fibers 4.0 (Fastest)
 AV node has the
slowest conduction
velocity

The impulse in the
AV node is delayed
for about 0.1 second

This is called
AV nodal
delay
AV nodal
delay

To allow 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

The fastest conducting
cells

To ensure rapid and simultaneous
excitation and contraction of both
the ventricles
 ECG (also called EKG)- Electrocardiogram

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 (contraction) and
repolarization (relaxation) of different regions of
the heart.
 A typical ECG tracing

Waves
P, Q, R, S, T

P wave: Atrial Depolarization
QRS complex: Ventricular Depolarization
T wave: Ventricular Repolarization
A normal
heart always
beats in a
Rhythm

An abnormal rhythm of the heart is called
Arrhythmia
 Cardiac Output &

Lecture-2 Autonomic Regulation
of Heart
DIASTOLE &
SYSTOLE
 Diastole vs Systole

The blood is
The blood is
received by
pumped out
the heart
by the heart
during
in systole
diastole
 End Diastolic The volume of blood in the ventricle at the end
of diastole i.e., ventricular relaxation and filling
Volume (EDV): (135 ml).

End Systolic The volume of blood remaining in the ventricles
after ejection of blood is completed at the end
Volume (ESV): of systole i.e., ventricular contraction (65 ml)
 It is the amount of blood pumped out of each
ventricle in one heart-beat (one systole).

Stroke Volume SV is usually 70 ml/ beat.

(SV) SV = End Diastolic Volume – End Systolic Volume
SV = 135 ml – 65 ml = 70 ml/ beat
 It is the number of heart beats per minute (BPM)
It is established by the SA node
HR = 70–75 BPM on the average (Range is 60–100 )
Heart Rate
(HR) HR is greater in females than males
HR is greater in children than in adults
HR is greater in sedentary people than in athletes
 Tachycardia
HR greater than Normal (100 BPM)

Examples
Fever, anemia, hyperthyroidism, sympathetic
Heart Rate stimulation

(HR) Bradycardia
HR less than Normal (60 BPM)

Examples
Athletes, hypothyroidism, parasympathetic
stimulation
 It is the volume of blood pumped through the circulatory
system by each ventricle per minute.
The CO of the left ventricle = CO of the right ventricle.
Cardiac output It is an important medical indicator of how efficiently the
heart can meet the demands of the body.
(CO) HR and SV are two key factors which contribute to CO

CO = HR X SV
 Example
What would be the Cardiac output (CO) if Heart Rate (HR) is 70 BPM & Stroke
Volume is 70 ml/beat

CO = HR x SV
= 70 beats / min x 70 ml / beat
= 4900 ml / min (about 5 liters)

Normal resting cardiac output (5L) equals to the normal blood volume in an individual
Factors that control heart rate & stroke volume
also control cardiac output
 Regulation of Cardiac Output

Cardiac output has to be regulated to meet the body needs under various
conditions.

This is achieved by regulation of:
Heart rate
Stroke volume
 Heart rate can be regulated by regulating SA node
activity since it is the pacemaker of the heart.

Factors Increasing heart rate

Sympathetic stimulation on SA node

Regulation of Presence of circulating epinephrine hormone
Increased body temperature

Heart rate Anxiety
Young children

Factors decreasing heart rate

Parasympathetic stimulation on SA node
Decreased body temperature
Advanced age
During rest (parasympathetic discharge is dominant)
 Regulation of Stroke Volume
The stroke volume can be increased by increasing the force of contraction of heart.

Force of contraction increased by:
Autonomic nervous system (Sympathetic stimulation)
Increased venous return “Frank Starling mechanism”
 Primary control of
stroke volume

Intrinsic Control Extrinsic Control
(venous return) (Autonomic nervous system)
 Intrinsic Control
(venous return)

Frank-Starling’s law of heart states that “ increased venous return to the
heart will result in an increased stroke volume’’.

Frank-Starling’s
law of heart
 Intrinsic control

venous return results

Greater
More the
theblood
initial returns
length of
Frank-Starling’s law cardiac
to themuscle
heart, greater
fiber greater
is
itsthe
force
stroke
of contraction
volume

↑ EDV causes ↑ pressure in ventricle
↑ pressure stretches heart muscle fibers
↑ length in muscle fibers allows ↑ force of contraction
Which results in an  Stroke volume
 Extrinsic control

(Sympathetic and parasympathetic activity)
AUTONOMIC REGULATION

▪ The autonomic nervous system DOES NOT initiate the heart beat
▪ SA-node does this spontaneously, but it does modulate it.
 Heart Strength of Cardiac

Autonomic Rate pumping Output

Sympathetic Increase Increase Increase
Regulation of Parasympathetic
Decrease Decrease Decrease

the heart for atria
No effect
on
ventricles.
 Control of the radius of the arterioles

Sympathetic nervous system can affect vascular tone.

Sympathetic stimulation → vasoconstriction.

Sympathetic inhibition→ vasodilation.
 Control of
Blood Pressure

Short-term Long-term
(within seconds) (within minutes-days)

Renal compensation
Baroreceptor Ref lex
(by controlling urine output)
(by controlling CO & TPR)
 Hypertension
BP > 140/90 mmHg

Primary hypertension (essential hypertension): the cause of this type of hypertension is not known.

Secondary hypertension: means that hypertension is secondary to some other factor.

Hyperlipidemia: narrowing of vessels ➔ increased total peripheral resistance ➔ increased blood
pressure.

Increased blood glucose levels: hyperlipidemia ➔ increased blood pressure.

Renal problems: increased release of angiotensin and aldosterone (kidneys) ➔ increased retention of salt
and water ➔ hypertension

Hypotension: BP < 100/60 mmHg
 Heart Failure
Is the inability of the heart to supply adequate blood flow and therefore
oxygen delivery to peripheral tissues and organs.

Under perfusion of organs leads to reduced exercise capacity, fatigue, and
shortness of breath. It can also lead to organ dysfunction (e.g., renal failure)
in some patients.
Reference
Human Physiology, 9th Edition Lauralee Sherwood
Thank you