2_Cardiovascular-Histology_Spring-2024.pdf

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HISTOLOGY OF THE
CARDIOVASCULAR SYSTEM
SPRING 2024
María José Navarrete Talloni, DVM, MPVM, PhD
Department of Biomedical Sciences, RUSVM

Disclaimer: Images and information in this presentation come from different sources including Drs. I. Irimescu, O. Illanes, M. Smith, M. Zibrin, P. Hanna and H. Bogdanovic‘s
notes. Dellmann’s and Junqueira’s histology books, P. Hyttel et al. and K. Moore embryology books. This presentation is for teaching purposes only, please do not distribute.
 Overview
1. Background and functions of the CVS

2. The Heart:
Endocardium
Myocardium
Epicardium ossifies
3. Vessels
Arteries (elastic a., muscular a., arterioles)
Capillaries (continuous, fenestrated,
discontinuous /sinusoids)
Venules & veins
CVS = Cardiovascular system
Lymphatics
 1. Background

“The circulatory system consist of blood, a central pump
(the heart), blood distribution (arterial) and collection
(venous) networks, and a system for exchange of nutrient
and waste products between blood and extravascular
tissue (microcirculation)”.
“A network of vessels (lymphatics) that parallel the veins
also contribute to circulation by draining fluid from the
extravascular spaces into the blood vascular system”.
McGavin, 2007
 Functions of the
Cardiovascular System

Maintenance of adequate blood flow (cardiac output)
Delivery of oxygen, nutrients, hormones, electrolytes
and water to peripheral tissues
Removal of carbon dioxide (CO2) and other metabolic
waste products
Maintenance of normal thermoregulation
Maintenance of normal glomerular filtration rate
(GFR) and urine output
have A and vein all hesler and
 1 to
Y open

The right heart propels unoxygenated blood through the
pulmonary circulation, and the left heart propels oxygenated blood
through the systemic circulation. RA, Right atrium; RV, right ventricle;
LA,left atrium,LV, left ventricle.
FYI: Relationship between blood pressure, vascular permeability and
structural characteristics of different types of blood vessels (bottom)

Pressure

Histology, a text atlas, 3rd
edition, Ross, Romrell, and
Permeability Kaye, 1995

Elastic substance +
Thickness of the wall

Smooth muscle

Total cross-sectional area
 Microcirculation

Normal vascular pattern T 1

biggest
Artery
Metarteriole Capillaries
Venule Vein

Source: Junqueria’s Basic Histology, 2010
 2. Heart
First organ to form in the embryo
Mammalian and bird hearts have 4 chambers:
RA
Left & right atria (LA, RA)
Left & right ventricles (LV, RV)
LA

RV

LV
 Apt
Heart tunics
RLIIiigi
IB.EE
The heart is composed of 3 layers -
Myocardium

from inside to outside:
1. Endocardium (includes valves)
2. Myocardium (heart muscle)thicklayer Endocardium

3. Epicardium (visceral pericardium)
thin layer

Epicardium
Heart tunics
Myocardium

Epicardial
Epicardium adipose tissue

Purkinje fibers Endocardium
Right Right atrium
ventricle

Aorta

Endocardium

Left ventricle
Myocardium Epicardium
Interventricular
septum 5x
 Endocardium

Forms the inner lining and the valves
Equivalent to the tunica intima of BV
Endothelial cells on the inner most Endocardium

surface
Direct contact with blood
Important in hemostasis
 Endocardium
blood
3 layers: contactwth
1. Endothelium Endocardium
2. Basal lamina
3. Subendothelial
connective tissue
Purkinje Fiber

Also contains part of
the conductive system
and Purkinje fibers

Myocardium
 Conduction system
SEn

E
M P
0

Heart, sheep. Purkinje fibers. The endocardium (E) is a thin layer of connective tissue lined by endothelium. Between the endocardium and
myocardium (M) is a layer of variable thickness called the subendocardial layer (SEn) containing small nerves and in the ventricles the Purkinje
fibers (P) of the subendocardial conducting network. These fibers are cardiac muscle cells joined by intercalated disks but specialized for
impulse conduction rather than contraction. Purkinje fibers are usually larger than contractile cardiac muscle fibers with large amounts of lightly
stained glycogen filling most of the cytoplasm and displacing sparse myofibrils to the periphery.
 Conduction system
The Purkinje fibers are found in the
I
subendocardium. pepanfovconcuctinofimp.is
Modified cardiomyocytes that function in
conduction.
Larger than cardiac muscle cells
Fewer myofibrils
Lots of glycogen and mitochondria
No T-tubules.
Connected by desmosomes and gap
junctions
Intercalated discs are variable in appearance
and number depending on their location
compared to myocardiocytes
a
They are specialized conducting fibers, which extend from the interventricular septum,
to the papillary muscles, and up the lateral walls of the ventricles.
Conduction system - FYI

Two nodes generate the impulses for myocardial contraction.
Both are small masses of specialized cardiac muscle fibers and
associated connective tissue, supplied by nerve fibers from the
autonomic nervous system that speed up and slow down the
heart rate.
First impulses are generated by the sinoatrial node (SA) (in the
wall of the right atrium) - sending a wave of depolarization
around the atria via gap junctions between the muscle fibers.
Next the atrioventricular node (AV) (located in the interatrial
septum) starts impulse generation around the ventricles.
Impulses are sent from it to the AV bundle (bundle of His), which
branches to form Purkinje fibers, which lie in the deepest layer of
the endocardium and supply the papillary muscles
The apex of the heart contracts 1st then the papillary muscles
then the wave of depolarization spreads up the walls of the
ventricles from the apex upwards, as shown in the diagram.
 Valve cusp
T

Figure 11–6. (Mescher) Valve leaflet and fibrous skeleton. The fibrous skeleton of the heart consists of masses of dense connective tissue in the endocardium which
anchors the valves and surrounds the two atrioventricular canals, maintaining their proper shape. Section through a leaflet of the left atrioventricular valve (arrows)
shows that valves are largely dense connective tissue (C) covered with a thin layer of endothelium. The collagen—rich connective tissue of the valves is stained pale
green here and is continuous with the fibrous ring of connective tissue at the base of the valves, which fills the endocardium (En) of this area between the atrium (A)
and ventricle (V). The chordae tendinae (CT), small strands of connective tissue which bind distal parts of valve leaflets, can also be seen here. The interwoven nature
of the cardiac muscle fibers, with many small fascicles, in the myocardium (M) is also shown. X20. Masson trichrome.
Myocardium

Myocardium
Cardiomyocytes
Cross striated
Central single nucleus
Intercalated disks:
- gap junctions
- anchoring junctions
Lipofuscin
Sarcoplasmic reticulum
Many mitochondria
up to 20% cell volume
FEE requires a lot of O2
Low regeneration
capacity (mitosis)

www.histology.leeds.ac.uk
Myocardium

Left ventricular myocardial thickness is
~ 2 to 4 times thicker than the right in
adults due to higher pressure on the
left side
Involuntary striated muscle
Arranged in sarcomeres
Branched fibers connect via
intercalated discs
Contain nr. mitochondria

Intercalated discs
 Cardiac muscle cells

0

Figure 10–16. (Meshcer) Cardiac muscle. Diagram of cardiac muscle cells indicates characteristic features of this muscle type. The fibers consist of separate cells with
interdigitating processes where they are held together. These regions of contact are called the intercalated discs, which cross an entire fiber between two cells. The
transverse regions of the steplike intercalated disc have abundant desmosomes and other adherent junctions which hold the cells firmly together. Longitudinal regions
of these discs contain abundant gap junctions, which form “electrical synapses” allowing contraction signals to pass from cell to cell as a single wave. Cardiac muscle
cells have central nuclei and myofibrils that are less dense and organized than those of skeletal muscle. Also the cells are often branched, allowing the muscle fibers to
interweave in a more complicated arrangement within fascicles that produces an efficient contraction mechanism for emptying the heart.
Epicardium and Pericardium – Pericardial sac
Visceral Pericardium
= Epicardium

Parietal Pericardium Fudging
heat
The
outside

Lung
 Epicardium
GO.EE Atrium

A/V Valve
Outer surface of the heart visceral
pericardium
Surface is covered by mesothelium
(simple squamous epithelium), a thin
layer of dense connective tissue, and
depending on the location, a variably thick Ventricle
layer adipose tissue with blood vessels
(coronary arteries and veins)
Is contiguous with the endocardium at Epicardium
the level of the endocardial cushion
Epicardium and Pericardium
Epicardium

Myocardium
 Heart Structure - Summary
ENDOCARDIUM (can be compared to the tunica intima of blood vessels):
- endothelial lining of the heart chambers surface and covers the surface of the valves.
- the subendocardium contains a thin layer of connective tissue and the Purkinje fibers.
MYOCARDIUM (can be compared to the tunica media of blood vessels): Cardiac
muscle mass – involuntary striated muscle.

EPICARDIUM (can be compared to the tunica adventitia of blood vessels):
- single layer of flattened epithelial cells the mesothelium (simple squamous
epithelium)
- supported by connective tissue, including fat.
- similar mesothelial layer lines the opposing parietal surface of the pericardial sac.
- mesothelial cells secrete a small amount of serous fluid that lubricates the movement
of the epicardium on the opposite parietal pericardium.
- the epicardium represents the visceral layer of the pericardial sac.
 Cardiac skeleton
4 dense bands of fibrous
connective tissue encircle the
base of the pulmonary trunk,
aorta and the AV valves –
provides structural support to the
heart.

A triangular mass of fibrous
connective tissue – the fibrous
trigon, connects the aortic a. ring
and the L and R atrioventricular
rings. This area undergoes
Fibrous trigon osseous differentiation and
forms the “Os Cordis” – primarily
seen in cattle.
 3. Vessels
Arteries
Elastic arteries
Muscular arteries
Arterioles
Capillaries
Continuous
Fenestrated
Discontinuous /sinusoids
Veins
Venules
Lymphatic vessels
 thehigh
bigger xg of
pressure

m B
agaft
lowpass

Source: Junqueria’s Basic Histology, 2010
 Tunics of vessels
INNERMOST: TUNICA INTIMA Eubank
Endothelium, Internal elastic membrane
Subendothelial connective tissue

MIDDLE: TUNICA MEDIA
Ayoub
Smooth muscle and elastic lamellae/fibers

OUTERMOST: TUNICA ADVENTITIA / EXTERNA
Eggadir
Collagen, may contain blood vessels, nerves, capillaries.
 Vascular Endothelium

Role in hemostasis
Modulates perfusion
Role in inflammation
Fig. 2-6 (McGavin) Structure and function of the
endothelium. Endothelium is both a physical
barrier between intravascular and extravascular
spaces, and it is an important mediator of fluid
distribution, hemostasis, inflammation, and
healing.

Hemostasis
- It is a physiological response to vascular damage.
- Provides a group of mechanisms to seal an injured vessel to prevent blood loss.
- It is the result of a complex and well-regulated process which maintains blood as a flowing fluid
within the cardiovascular system.
ARTERIES
 Elastic Artery (e.g. Aorta)

All 3 tunics exist:
Tunica intima (1) is endothelium +
loose connective tissue.
Tunica media (2) consists largely
of repeating ELASTIC LAMELLAE. D
Tunica adventitia (3) contains vasa
vasorum to assist in supplying
Lelastic
nutritional needs of thick tunica
media.
waves
 Muscular Arteries (e.g. Femoral Artery)

Tunica media is primarily
SMOOTH MUSCLE.
Thickest tunic is tunica
media.
Generally, they have a
round appearance.

40X
Van Giesson stain for elastic fibers
 Tunica media
of smooth muscle
Tunica
adventitia

Tunica intima

Lumen
Tunica intima
 r
Tunica Media
TUNICA MEDIA - Vascular smooth muscle
- Smooth muscle cells are
circumferentially arranged within the
tunica media
- Regulates DIAMETER and TONE
(vasodilation/vasoconstriction)

Tunica Media

o

T.intima
Source: Dellmann’s Texbook of Veterinary Histology, 2006.
 ARTERIOLES

1- 3 layers of smooth muscle cells
Greatest effect on blood pressure
Nuclei bulge into lumen
Round appearance of vessel
No internal elastic membrane in the smallest arterioles with
one smooth muscle cell
Metarteriole is a terminal vessel, has precapillary sphincters that
can regulate flow to the capillary bed
 RBC
s

Arteriole
Smooth muscle
nuclei

1000x
 Arteriole vs. venule

Smooth muscle nuclei

V
A relay

Fibroblasts

Small vessels embedded in loose connective tissue. Nuclei of fibroblasts can be seen along with collagen bundles.
 Arteriole vs. venule haveshithmusle

if

Source: Dellmann’s Texbook of Veterinary Histology, 2006.
 Arteriole in longitudinal section

Smooth muscle cells

Smooth muscle nuclei

cell
Epithelial
 CAPILLARIES
1. Thin walled tubules of mesenchymal origin; in a cross
section they are made of only one endothelial cell rolled
into the tube.

2. Represent the site of exchange between blood and
surrounding
tissue.

3. The diameter is 7–9 µm, the length 0.25 – 1mm, in some
organs
(adrenal cortex, kidney medulla) can be up to 5-10 cm long.
CAPILLARIES

A capillary is composed of
simple squamous cells which

if
roll to produce a tube.
 0
PERICYTES (Roujet cells)

Mesenchymal-like cells that wrap
around the endothelium of
capillaries and venules.
They “communicate” with
endothelial cells by physical contact
and paracrine signaling.
They help to maintain homeostatic
and hemostatic functions in the PERICYTES
brain and also sustain the blood– (TEM)
brain barrier.
Proliferate after injury. Pericyte = p
Stem cell source. Tight junction, capillary endothelial cell = t
Important in angiogenesis new Skeletal muscle = m Capillary = c
vessels formation. Collagen fibers in transverse section = cl
 Classification of capillaries

NN
QDPorff

1. Continuous: Most common. Found in muscle, brain, bone, lung, etc. E.g.
Blood-brain and blood-testis barriers.
2. Fenestrated (gaps 10-100 nm): In tissues with substantial fluid exchange,
e.g.: intestinal villi, choroid plexus, ciliary process, glomerular capillaries.
3. Discontinuous (Sinusoidal): Hepatic and splenic sinusoids > large
molecules can exit (RBC in the spleen). liver bonemarrow
 Classification of capillaries

A. Continuous: Most common. Found in muscle, brain, bone, lung, etc. E.g.
Blood-brain and blood-testis barriers.
B. Fenestrated (gaps 10-100 nm): In tissues with substantial fluid exchange,
e.g.: intestinal villi, choroid plexus, ciliary process, glomerular capillaries.
C. Discontinuous (Sinusoidal): Hepatic and splenic sinusoids > large
molecules can exit (RBC in the spleen).
Continuous capillaries
Very swell
1. Nucleus of endothelial cell
2. Pinocytotic vesicles Capillary
3. Tight junctions (arrowheads)
4. Basement membrane/lamina

2
3 4
3
Consists of a tube
of endothelium
1
4

TEM
Fenestrated capillaries in SEM
P

a b

Glomerular capillary
(a) View from the inside of (b) View from the outside of
fenestrated capillary arrow: capillary covered by pedicels
of podocyte
tight junctions

E - Endothelium of fenestrated capillary B - Basement membrane
P – Podocyte
 RENAL CORPUSCLE
(glomerulus)
The renal glomerulus (a tightly
coiled network of fenestrated
capillaries) is responsible for the
filtration of plasma.
Fenestrated

capillary
In this stained section red blood cells
appear orange.
 PODOCYTES

Lining the Bowman's capsules
(nephrons).
Help prevent proteins and
other large molecules from
being filtered.
Their foot processes
(pedicels) extend and wrap
around the capillaries of the
glomerulus to form the
filtration slits.
The pedicels increase the
Pudo Feet
area of the cells enabling
efficient ultrafiltration.

Source: Junqueria’s Basic Histology, 2010
 Urinary Space PODOCYTE
process

EC Fenestrae
Glomerular Capillary Lumen
Robbins’Pathology
Discontinued capillaries (Sinusoids) liar benarrow spleen

1. Lumen is enlarged and irregular; diameter 20 - 40 m
2. Lining endothelium is discontinuous and fenestrated.
3. Basal lamina may be absent (discontinuous)

Sinusoid - S
Bone marrow
Hepatic sinusoids
VENULES

Called POSTCAPILLARYVENULES
Very ‘leaky’ vessels
NO SMOOTH MUSCLE
LEUKOCYTE diapedesis possible here
5mm Hg pressure in vessel.
VEINS
Thebigonehas
 VEIN VS. ARTERY
Large, wide lumen, thin walls in
comparison to same-size arteries
Valves present
Thin tunica media
The tunica adventitia is the
thickest tunic
Large veins may have vasa
vasorum
May be collapsed in histological
sections the
me faster
collapse
 y

LYMPHATIC VESSELS
Complementary to the cardiovascular system
Transport lymph throughout the lymphatic system
Valves are present
Freely anastomose with one another
Lined by endothelial cells
Thin layer of smooth muscles
Adventitia that bind the lymph
vessels to the surrounding tissue
Circulate the chyle or linguistic fluid
Lymphatic capillary

Anchoring fibrils
(arrows) pull
endothelial cells apart,
fluid enters vessel

Junqueira’s Histology
 LYMPHATIC VESSELS

Very thin wall, very low
pressure, may contain valves.

No RBCs in lymph,
so appear clear.
 at
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Striations
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Tumor Arterioles
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