Cardiovascular System F2024 PDF

Summary

This document is a set of lecture notes covering the cardiovascular system, including information about the heart, blood vessels, and circulatory system. The notes include diagrams, and explanations. The document appears to be from a medical school course at European University Cyprus.

Full Transcript

Cardiovascular System

S. THEMISTOCLEOUS, MSc. BSc
Medicine Program
Medical School
https://www.britannica.com/science/atherosclerosis#ref921978
A. Ishii, F. Viñuela, Y. Murayama, I. Yuki, Y.L.
Nien, D.T. Yeh and H.V. Vinters
American Journal of Neuroradiology October
2006, 27 (9) 1893-1899;
 Heart

Cardiovascular
Veins System
Arteries

Capillaries
 Lecture Outline
Cardiovascular System Basics
Heart
Vessels
Cases
 Cardiovascular System

Components:
Heart- muscular organ that pumps blood the system
Arteries- multiple vessels efferent from the heart. They
become smaller as they branch our into organs carrying
blood to the tissues
Capillaries- smallest vessels. Site of O2 exchange, CO2,
nutrient and waste products
Veins- from venules to larger veins that continue to get
bigger as you move closer to the heart

Function: to carry oxygen, nutrients, waste products and
hormones
 Circulatory system

Systemic Circulation – part of the circulatory system
that carries nutrients and 02 (oxygenated) to tissues
and organs. blood leaving tissues carrying waste
away. Simultaneously it carries deoxygenated blood,
along with waste products, back to the heart.

Pulmonary Circulation - arteries, veins and
microvasculature. It is responsible for carrying
deoxygenated blood from the heart to the lungs and
returning oxygenated blood back to the heart
 Cardiovascular System Basics

Blood flows through the
Cardiovascular System:

Heart → elastic (large) arteries → muscular
(medium-sized) arteries → small arteries →
arterioles → capillaries → venules → small
veins → medium veins → large veins →
heart

https://en.wikipedia.org/wiki/File:Sankey_diagram_human_circulatory_system.svg
Lymphatic Vascular System
Network of vessels, nodes and organs:

Lymphatic vessels- network of thin-walled tubes
that run parallel to blood vessels throughout the
body transferring a clear, colourless fluid=lymph

Lymph- water, proteins, lymphocytes, lipids,
wastes etc.

Immune response
Transport of White Blood Cells
Maintains fluid balance
Lymphatic Organs- Spleen, tonsils, thymus
Simple Squamous Epithelium
Endothelium
Imagine you are a
red blood cell
running through
the cardiovascular
system.
What would you
see??
 Endothelium

https://doi.org/10.1016/j.transci.2022.103368
 Endothelium

The lumen of all blood and lymphatic vessels are lined with a
simple squamous epithelium known as the endothelium. This
epithelium creates a barrier between blood or lymph, control
relaxation and contraction, releases molecules that attract
WBC to the site of injury or infection promoting the immune
response and prevent excessive bleeding.

Endothelium is involved in angiogenesis

Endothelium inside the heart chambers is known as
endocardium
 Endothelium
Epithelial lining of the cardiovascular system
Simple squamous epithelium
Non-thrombogenic surface
Role in inflammation & local immune response
Acts as a semipermeable barrier
Secrete growth factors

Vascular endothelial cells in contact with blood in the lumen of blood vessels
Lymphatic endothelial cells are in contact with the lymph

14
 Lecture Outline
Cardiovascular System Basics
Heart
Vessels
Cases
 Three layers of
the Heart

Endocardium

Myocardium

Epicardium

https://florida.theorangegrove.org/og/file/2d684c74-16c7-54be-f3cf-
1a380b19e4d1/1/bbtraining.zip/instructional_design/12Leads/05.htm
Heart Structure
Endocardium- inner squamous endothelium
with a middle layer of connective tissue &
smooth muscle and a deeper layer of
connective tissue (subendocardial layer).
Conducting system found here and well as
lining the valves

Myocardium- cardiac muscle tissue with
intercalated discs. thinner in atria than
ventricles due to excessice force required by
ventricles to push blood out of the heart

Epicardium- single layer of mesothelial cells
an underlying connective & adipose tissue.
The coronary circulation vessels lay here
Endocardium Epicardium
Thin endocardium and supporting Simple squamous mesothelium
connective tissue. Follows by supported by loose connective tissue
myoelastic muscle fibers and containing blood vessels and nerves
connective tissue & fibers of nerve
impulse
Epicardium(visceralpericardium) Thecoronaryvessels
arelocated here!
 Myocardium
Muscle fibers arranged in a spiral manner. Walls are
thicker in ventricles than in atria.
 Myocardium
Middle layer of the heart (analogous to the
media in vessels)
Mainly composed of cardiac muscle cells
(striated muscle cells due to
sarcomeres); it also contains a very rich
network of blood vessels
Cardiac muscle cells (fibers) are branched and
arranged around the heart chambers
Intercalated discs: composed of several
types of cell junctions that glue adjacent
cells together
Myocardium: notice thebranching ofthe
cardiac muscle cells
 Intercalated Disks
Aid the conduction system of
the heart
Electrical→ Contain gap
junctions allowing for rapid
exchange of ions ( Na+, K+
and Ca2+ and others).
Coordinated unit
Mechanical→ as a cardiac
muscle cell contracts the
desmosomes distribute this
force and transmit it to
neughbouring cells

This Photo by Unknown Author is licensed under CC BY-SA-NC
 Endocardium, Myocardium, Epicardium

http://141.214.65.171/Histology/Cardiovascular%20System/098HE_HISTO_40X.svs/view.apml?X=0&Y=0&zoom=0.639868422083343
Endocardium Myocardium

Epicardium
 Fibrous Skeleton

Dense fibrous network connective tissue

Encircle the aorta, bases of the pulmonary Fibrous
trunk and heart valves Skeleton

Isolates atria from ventricles

Electrical insulation- Stops contraction
from continuing and therefore need to
follow the signal by the nodes (electrical
insulation )

Anchor & support the heart valves

Provide firm points for anchoring of cardiac
muscle
 Systemic Right
Circulation ventricle

Left Pulmonary
ventricle artery

Left Capillaries in
Atrium lungs

Pulmonary
veins
 Heart Beat

Sinoatrial node is located in the right atrium
of the heart and once its polarized it generates
electrical impulses almost spontaneously
Electrical impulse travels through the atria
depolarizing them and forcing blood into the
ventricles (Atrial Depolarization)
Rate of depolarization is fastest in the atria
than ventricles due to the atrioventricular node
acting as a delay to ensure the ventricles fill up
The electrical impulse from the AV node is
then transmitted through the bundle of His to
the apex of the heart along the interventricular
septum separating left & right ventricles along
the Purkinje fibers

https://gfycat.com/agonizingselfishbronco-collisions-conduction-particles-physics
Parasympathetic Nervous System:
"rest and digest" system
Primarily responsible for slowing down the heart
rate and promoting relaxation.
The main parasympathetic nerve that innervates the
heart is the vagus nerve (cranial nerve X).
Releases acetylcholine = bradycardia
Decreases force of heart contractions, reducing
cardiac output
Sympathetic Nervous System:
"fight or flight" system
Increases heart rate and cardiac output
Response to stress or physical exertion.
Release norepinephrine, which binds to beta-
adrenergic receptors on the heart's cells.
Increases heart rate (tachycardia) & increases force
of heart contractions, enhancing cardiac output
 Purkinje Fibers
(stain lighter than the classic cardiac muscle fibers)

http://www.histologyguide.com/slide-view/MHS-245-heart/09-slide-1.html?x=4989&y=22266&z=52.2&page=1
 Subendocardium

Subendocardium is the part of the endocardium
attached to the myocardium
It is composed of connective tissue but also contains the
Purkinje fibers (specialized cardiac muscle cells) of the
conducting system
Purkinje fibers are larger and paler than the conventional cardiac
muscle cells (due to intracellular glycogen deposits)
Their main function is to conduct the contraction signal
over both ventricles
https://anatomyinfo.com/purkinje-fibers/
 Tricuspid valve
Atrioventricular valve
Three cusps or leaflets
Connected to the papillary muscles within the right ventricle by
chordae tendineae
Papillary muscles are small, cone-shaped muscles within the
right ventricle
Prevent the backflow of blood from the right ventricle into the
right atrium
 Bicuspid Valve

Location: Between the left
atrium and the left ventricle.
Structure: It has 2 cusps (hence
"bicuspid").
Function: It allows blood to
flow from the left atrium into
the left ventricle and prevents
backflow into the atrium when
the ventricle contracts.

A.K.A Mitral valve
Cusps of the valve are
connected to the papillary
muscles within the left ventricle
by chordae tendineae (fibrous
DOI: 10.1080/01926230213166 cords of connective tissue)
Aortic valve
Location: Between the left ventricle and the
aorta.
Structure: It is a semilunar valve with three
cusps or leaflets.
Function: Prevents the backflow of blood
from the aorta into the left ventricle after the
ventricle contracts.
2 or 4 cusps
Have Chordae Tendineae (fibrous cords of
connective tissue)
The papillary muscles are cone-shaped
muscles located within the left ventricle.
Pulmonary Valve

Typically has 3 cusps or leaflets
These cusps are thin, membranous structures
The three cusps are often referred to as the
anterior, left, and right cusps.
Deoxygenated blood to be pumped from the
right ventricle to the pulmonary circulation.
The cusps of the pulmonary valve are attached to
a fibrous ring called the annulus.
Chordae tendineae connect the cusps of the
pulmonary valve to the papillary muscles within
the right ventricle

https://doi.org/10.3389/fcvm.2022.829120
Heart

https://www.youtube.com/watch?v=SC5fKdrYi6w&t=
987s

https://www.youtube.com/watch?v=ZcCviyMNsPo

https://www.youtube.com/watch?v=oS4XA749GoI