Cardiovascular System PDF

Summary

This document describes the cardiovascular system, its composition (blood, heart, blood vessels), functions (transportation, regulation, protection), and the structure of blood vessels (tunica interna, tunica media, tunica externa). It also outlines different types of blood vessels (arteries, veins, capillaries).

Full Transcript

Cardiovascular
system

KRISTLE ANN JUDAVAR
DMD-1A
What is Cardiovascular system?
The cardiovascular system is one of the most
important processes in the body. Also referred to as the
circulatory system or vascular system, the
cardiovascular system is an essential component of
maintaining homeostasis, a state of balance among
systems of the body, by circulating blood. When it
comes to understanding your heart health, it’s
important to be familiar with the parts of the
cardiovascular system and how the system works.

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Cardiovascular system

The cardiovascular system (cardio- = heart;
vascular = blood or blood vessels) consists of
three interrelated components: blood, the
heart, and blood vessels. The branch of science
concerned with the study of blood, blood-
forming tissues, and the disorders associated
with them is hematology (hema- or hemato- =
blood; -logy = study of).

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 Blood
Blood contributes to homeostasis by transporting oxygen,
carbon dioxide, nutrients, and hormones to and from your
body’s cells. It also helps regulate body pH and temperature,
and provides protection against disease through
phagocytosis and the production of antibodies.

Blood transports various substances, helps regulate several
life processes, and affords protection against disease. For all
of its similarities in origin, composition, and functions, blood is
as unique from one person to another as are skin, bone, and
hair. Health-care professionals routinely examine and
analyze its differences through various blood tests when
trying to determine the cause of different diseases.

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Functions of Blood
Blood has three general functions:
1. Transportation. As you just learned, blood transports oxygen from the lungs to the cells of the body and carbon
dioxide from the body cells to the lungs for exhalation. It carries nutrients from the gastrointestinal tract to body
cells and hormones from endocrine glands to other body cells. Blood also transports heat and waste products to
various organs for elimination from the body.

2. Regulation. Circulating blood helps maintain homeostasis of all body fluids. Blood helps regulate pH through the
use of buffers (chemicals that convert strong acids or bases into weak ones). It also helps adjust body temperature
through the heat-absorbing and coolant properties of the water (see Section 2.4) in blood plasma and its variable
rate of flow through the skin, where excess heat can be lost from the blood to the environment. In addition, blood
osmotic pressure influences the water content of cells, mainly through interactions of dissolved ions and proteins.

3. Protection. Blood can clot (become gel-like), which protects against its excessive loss from the cardiovascular
system aft er an injury. In addition, its white blood cells protect against disease by carrying on phagocytosis.
Several types of blood proteins, including antibodies, interferons, and complement, help protect against disease in
a variety of ways.

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Components of Blood
Whole blood has two components:
(1) blood plasma, a watery liquid extracellular matrix that contains dissolved substances, and
(2) formed elements, which are cells and cell fragments. If a sample of blood is centrifuged (spun) in a small glass
tube, the cells (which are more dense) sink to the bottom of the tube while the plasma (which is less dense) forms
a layer on top.. Blood is about 45% formed elements and 55% blood plasma. Normally, more than 99% of the formed
elements are cells named for their red color—red blood cells (RBCs). Pale, colorless white blood cells (WBCs) and
platelets occupy less than 1% of the formed elements. Because they are less dense than red blood cells but more
dense than blood plasma, they form a very thin buff y coat layer between the packed RBCs and plasma in
centrifuged blood. Figure 19.1b shows the composition of blood plasma and the numbers of the various types of
formed elements in blood.

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 Blood Vessels
Another essential part of the cardiovascular system is
the blood vessels, which are tubes that transport
blood throughout the body. There are so many blood
vessels in the body that if you laid the average adult’s
out in a line, the line would be close to 100,000 miles
long.
Based on their function, blood vessels are classified
as either arteries, veins, or capillaries. Arteries carry
blood from the heart to the body, and veins carry
blood from the body to the heart. Capillaries are
extremely narrow, microscopic blood vessels that
connect arteries and veins.

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 Structure and Function of Blood Vessels

The five main types of blood vessels are arteries, arterioles, capillaries, venules, and veins. Arteries
carry blood away from the heart to other organs. Large, elastic arteries leave the heart and divide
into medium-sized, muscular arteries that branch out into the various regions of the body. Medium-
sized arteries then divide into small arteries, which in turn divide into still smaller arteries called
arterioles. As the arterioles enter a tissue, they branch into numerous tiny vessels called
blood capillaries or simply capillaries. The thin walls of capillaries allow the exchange of substances
between the blood and body tissues. Groups of capillaries within a tissue reunite to form small veins
called venules. These in turn merge to form progressively larger blood vessels called veins. Veins are
the blood vessels that convey blood from the tissues back to the heart.

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Basic Structure of a Blood Vessel

The wall of a blood vessel consists of three layers, or tunics, of different tissues: an epithelial inner
lining, a middle layer consisting of smooth muscle and elastic connective tissue, and a connective
tissue outer covering. The three structural layers of a generalized blood vessel from innermost to
outermost are the tunica interna (intima), tunica media, and tunica externa (adventitia).
Modifications of this basic design account for the five types of blood vessels and the structural and
functional differences among the various vessel types. Always remember that structural variations
correlate to the differences in function that occur throughout the cardiovascular system.

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The tunica interna forms the inner lining of a blood vessel and is in direct contact with the blood as it flows
through the lumen, or interior opening, of the vessel (Figure 21.1a, b). Although this layer has multiple parts, these
tissue components contribute minimally to the thickness of the vessel wall. Its innermost layer is called
endothelium, which is continuous with the endocardial lining of the heart. The endothelium is a thin layer of
flattened cells that lines the inner surface of the entire cardiovascular system (heart and blood vessels).

The tunica media is a muscular and connective
tissue layer that displays the greatest variation
among the different vessel types. In most vessels, it
is a relatively thick layer comprising mainly smooth
muscle cells and substantial amounts of elastic
fibers. The primary role of the smooth muscle cells,
which extend circularly around the lumen like a ring
encircles your finger, is to regulate the diameter of
the lumen. An increase in sympathetic stimulation
typically stimulates the smooth muscle to contract,
squeezing the vessel wall and narrowing the lumen.
Such a decrease in the diameter of the lumen of a
blood vessel is called vasoconstriction.

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 Tunica Externa The outer covering of a blood vessel, the tunica externa (externa = outermost), consists of elastic
and collagen fibers. The tunica externa contains numerous nerves and, especially in larger vessels, tiny blood
vessels that supply the tissue of the vessel wall. These small vessels that supply blood to the tissues of the vessel
are called vasa vasorum, or vessels to the vessels. They are easily seen on large vessels such as the aorta. In
addition to the important role of supplying the vessel wall with nerves and self-vessels, the tunica externa helps
anchor the vessels to surrounding tissues. major initial branches, such as the brachiocephalic, subclavian,
common carotid, and common iliac arteries. Elastic arteries perform an important function: They help propel
blood onward while the ventricles are relaxing. As blood is ejected from the heart into elastic arteries, their walls
stretch, easily accommodating the surge of blood. As they stretch, the elastic fibers momentarily store
mechanical energy, functioning as a pressure reservoir. Then, the elastic fibers recoil and convert stored
(potential) energy in the vessel into kinetic energy of the blood. Thus, blood continues to move through the
arteries even while the ventricles are relaxed. Because they conduct blood from the heart to medium sized, more
muscular arteries, elastic arteries also are called conducting arteries.

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Arteries

Because arteries were found empty at death, in ancient times they were thought to contain only air.
The wall of an artery has the three layers of a typical blood vessel, but has a thick muscular-to-
elastic tunica media (Figure 21.1a). Due to their plentiful elastic fibers, ar teries normally have high
compliance, which means that their walls stretch easily or expand without tearing in response to a
small increase in pressure.

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Elastic Arteries Elastic arteries are the largest arteries in the body, ranging
from the garden hose–sized aorta and pulmonary trunk to the finger-sized
branches of the aorta. They have the largest diameter among arteries, but
their vessel walls (approximately one-tenth of the vessel’s total diameter)
are relatively thin compared with the overall size of the vessel. These
vessels are characterized by well-defined internal and external elastic
laminae, along with a thick tunica media that is dominated by elastic fibers,
called the elastic lamellae. Elastic arteries include the two major trunks that
exit the heart (the aorta and the pulmonary trunk), along with the aorta’s
major initial branches, such as the brachiocephalic, subclavian, common
carotid, and common iliac arteries (see Figure 21.20a). Elastic arteries
perform an important function: They help propel blood onward while the
ventricles are relaxing. As blood is ejected from the heart into elastic
arteries, their walls stretch, easily accommodating the surge of blood. As
they stretch, the elastic fibers momentarily store mechanical energy,
functioning as a pressure reservoir(Figure 21.2a). Then, the elastic fibers
recoil and convert stored (potential) energy in the vessel into kinetic energy
of the blood. Thus, blood continues to move through the arteries even while
the ventricles are relaxed (Figure 21.2b). Because they conduct blood from
the heart to medium sized, more muscular arteries, elastic arteries also are
called conducting arteries.

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Muscular Arteries Medium-sized arteries are called muscular arteries because their tunica media
contains more smooth muscle and fewer elastic fibers than elastic arteries. The large amount of
smooth muscle, approximately three quarters of the total mass, makes the walls of muscular arteries
relatively thick. Thus, muscular arteries are capable of greater vasoconstriction and vasodilation to
adjust the rate of blood flow. Muscular arteries have a well-defined internal elastic lamina but a thin
external elastic lamina. These two elastic laminae form the inner and outer boundaries of the
muscular tunica media. In large arteries, the thick tunica media can have as many as 40 layers of
circumferentially arranged smooth muscle cells; in smaller arteries there are as few as three layers.

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Anastomoses
Most tissues of the body receive blood from more than one artery. The union of the branches of two or more
arteries supplying the same body region is called an anastomosis. Anastomoses between arteries provide
alternative routes for blood to reach a tissue or organ. If blood flow stops for a short time when normal
movements compress a vessel, or if a vessel is blocked by disease, injury, or surgery, then circulation to a
part of the body is not necessarily stopped. The alternative route of blood flow to a body part through an
anastomosis is known as collateral circulation. Anastomoses may also occur between veins and between
arterioles and venules. Arteries that do not anastomose are known as end arteries. Obstruction of an end
artery interrupts the blood supply to a whole segment of an organ, producing necrosis (death) of that
segment. Alternative blood routes may also be provided by nonanastomosing vessels that supply the same
region of the body.

Arterioles
Literally meaning small arteries, arterioles are abundant microscopic vessels that regulate the flow of blood
into the capillary networks of the body’s tissues (see Figure 21.3). The approximately 400 million arterioles
have diameters that range in size from 15 μm to 300 μm. The wall thickness of arterioles is one-half of the
total vessel diameter.

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Capillaries

Capillaries, the smallest of blood vessels,
have diameters of 5– 10 μm, and form the U-
turns that connect the arterial outflow to the
venous return (Figure 21.3). Since red blood
cells have a diameter of 8 μm, they must
often fold on themselves in order to pass
single file through the lumens of these
vessels. Capillaries form an extensive network,
approximately 20 billion in number, of short
(hundreds of micrometers in length),
branched, interconnecting vessels that
course among the individual cells of the body.
This network forms an enormous surface area
to make contact with the body’s cells.

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Venules

Unlike their thick-walled arterial counterparts, venules and veins have thin walls that do not readily maintain
their shape. Venules drain the capillary blood and begin the return flow of blood back toward the heart. As
noted earlier, venules that initially receive blood from capillaries are called postcapillary venules. They are the
smallest venules, measuring 10 μm to 50 μm in diameter, and have loosely organized intercellular junctions
(the weakest endothelial contacts encountered along the entire vascular tree) and thus are very porous. They
function as significant sites of exchange of nutrients and wastes and white blood cell emigration, and for this
reason form part of the microcirculatory exchange unit along with the capillaries.

Veins
While veins do show structural changes as they increase in size from small to medium to large, the structural
changes are not as distinct as they are in arteries. Veins, in general, have very thin walls relative to their total
diameter (average thickness is less than one-tenth of the vessel diameter). They range in size from 0.5 mm in
diameter for small veins to 3 cm in the large superior and interior venae cavae entering the heart.

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 Heart
The heart acts as the pump that makes the
circulation of blood – and the oxygen and
nutrients blood carries – to all tissues of the body
possible. If the heart stops pumping for even a
few minutes, it cannot deliver blood to the rest of
the body, putting the individual’s life in danger.

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Heart
In terms of structure, the heart has two sides and is divided into four
chambers: the left atrium, the right atrium, the left ventricle, and the right
ventricle. The thin-walled atria receive blood from the veins, and the thick-
walled ventricles pump blood out of the heart. On the left and right sides of
the heart, the atrium and ventricle work together to pump blood through and
out of the heart.
Both sides of the heart work simultaneously to promote blood flow. On the
left, blood flows from the lungs to the atrium and then the ventricle, which
pumps it into the rest of the body. On the right side, blood flows from the rest
of the body into the atrium, then the ventricle, which pumps the blood into
the lungs.
Valves between the chambers of the heart ensure blood flows in the correct
direction. Veins also contain valves to maintain blood flow into the heart.
Arteries don’t need valves, as the pressure of blood flow from the heart is
enough to keep blood flowing in the correct direction.

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For blood to reach body cells and exchange materials with them, it must be pumped continuously by
the heart through the body’s blood vessels. The heart beats about 100,000 times every day, which
adds up to about 35 million beats in a year, and approximately 2.5 billion times in an average
lifetime. The left side of the heart pumps blood through an estimated 100,000 km (60,000 mi) of blood
vessels, which is equivalent to traveling around the earth’s equator about three times. The right side
of the heart pumps blood through the lungs, enabling blood to pick up oxygen and unload carbon
dioxide. Even while you are sleeping, your heart pumps 30 times its own weight each minute, which
amounts to about 5 liters (5.3 qt) to the lungs and the same volume to the rest of the body. At this
rate, your heart pumps more than about 14,000 liters (3600 gal) of blood in a day, or 5 million liters
(1.3 million gal) in a year. You don’t spend all of your time sleeping, however, and your heart pumps
more vigorously when you are active. Thus, the actual blood volume your heart pumps in a single day
is much larger.

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Location of the Heart
The scientific study of the normal heart and the diseases associated with it is known as cardiology (kar-dē-OL-ō-jē; cardio-
= heart; -logy = study of).For all its might, the heart is relatively small, roughly the same size (but not the same shape) as
your closed fist. It is about 12 cm (5 in.) long, 9 cm (3.5 in.) wide at its broadest point, and 6 cm (2.5 in.) thick, with an average
mass of 250 g (8 oz) in adult females and 300 g (10 oz) in adult males. The heart rests on the diaphragm, near the midline of
the thoracic cavity. Recall that the midline is an imaginary vertical line
that divides the body into unequal left and right sides. The heart lies in
the mediastinum, an anatomical region that extends from the sternum
to the vertebral column, from the first rib to the diaphragm, and
between the lungs (Figure 20.1a). About two-thirds of the mass of the
heart lies to the left of the body’s midline (Figure 20.1b). You can
visualize the heart as a cone lying on its side. The pointed apex is
formed by the tip of the left ventricle (a lower chamber of the heart)
and rests on the diaphragm. It is directed anteriorly, inferiorly, and to
the left. The base of the heart is opposite the apex and is its posterior
aspect. It is formed by the atria (upper chambers) of the heart, mostly
the left atrium (see Figure 20.3c). In addition to the apex and base, the
heart has several distinct surfaces. The anterior surface is deep to the
sternum and ribs. The inferior surface is the part of the heart between
the apex and right surface and rests mostly on the diaphragm
(Figure 20.1b). The right surface faces the right lung and extends from
the inferior surface to the base. The left surface faces the left lung and
extends from the base to the apex.

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Pericardium
The membrane that surrounds and protects the heart is the pericardium. It
confines the heart to its position in the mediastinum, while allowing suffcient
freedom of movement for vigorous and rapid contraction. The pericardium
consists of two main parts: (1) the fibrous pericardium and (2) the serous
pericardium (Figure 20.2a). The superficial fibrous pericardium is composed
of tough, inelastic, dense irregular connective tissue. It resembles a bag that
rests on and attaches to the diaphragm; its open end is fused to the
connective tissues of the blood vessels entering and leaving the heart. The
fibrous pericardium prevents overstretching of the heart, provides
protection, and anchors the heart in the mediastinum. The fibrous
pericardium near the apex of the heart is partially fused to the central
tendon of the diaphragm and therefore movement of the diaphragm, as in
deep breathing, facilitates the movement of blood by the heart.
The deeper serous pericardium is a thinner, more delicate membrane that
forms a double layer around the heart (Figure 20.2a). The outer parietal layer
of the serous pericardium is fused to the fibrous pericardium. The inner
visceral layer of the serous pericardium, which is also called the epicardium,
is one of the layers of the heart wall and adheres tightly to the surface of the
heart. Between the parietal and visceral layers of the serous pericardium is a
thin film of lubricating serous fluid. This slippery secretion of the pericardial
cells, known as pericardial fluid, reduces friction between the layers of the
serous pericardium as the heart moves. The space that contains the few
milliliters of pericardial fluid is called the pericardial cavity.
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Chambers of the Heart

The heart has four chambers. The two superior receiving chambers are the atria, and the two inferior pumping
chambers are the ventricles. The paired atria receive blood from blood vessels returning blood to the heart,
called veins, while the ventricles eject the blood from the heart into blood vessels called arteries. Each auricle
slightly increases the capacity of an atrium so that it can hold a greater volume of blood. Also on the surface of
the heart are a series of grooves, called sulci, that contain coronary blood vessels and a variable amount of fat.
Each sulcus marks the external boundary between two chambers of the heart. The deep coronary sulcus
encircles most of the heart and marks the external boundary between the superior atria and inferior ventricles.
The anterior interventricular sulcus is a shallow groove on the anterior surface of the heart that marks the
external boundary between the right and left ventricles on the anterior aspect of the heart. This sulcus
continues around to the posterior surface of the heart as the posterior interventricular sulcus, which marks the
external boundary between the ventricles on the posterior aspect of the heart (Figure 20.3c).

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Right Atrium
The right atrium forms the right surface of the heart
and receives blood from three veins: the superior
vena cava, inferior vena cava, and coronary sinus
(Figure 20.4a). (Veins always carry blood toward the
heart.) The right atrium is about 2–3 mm (0.08–0.12
in.) in average thickness. The anterior and posterior
walls of the right atrium are very different. The inside
of the posterior wall is smooth; the inside of the
anterior wall is rough due to the presence of
muscular ridges called pectinate muscles, which
also extend into the auricle (Figure 20.4b). Between
the right atrium and left atrium is a thin partition
called the interatrial septum (inter- = between;
septum = a dividing wall or partition). A prominent
feature of this septum is an oval depression called
the fossa ovalis, the remnant of the foramen ovalis,
an opening in the interatrial septum of the fetal
heart that normally closes soon aft er birth (see
Figure 21.31). Blood passes from the right atrium into
the right ventricle through a valve that is called the
tricuspid valve because it consists
of three cusps or leaflets (Figure 20.4a). It is also
called the right atrioventricular valve. The valves of
the heart are composed of dense connective tissue
covered by endocardium.
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Right Ventricle The right ventricle is about 4–5 mm (0.16–0.2 in.) Left Ventricle The left ventricle is the thickest chamber of
in average thickness and forms most of the anterior surface of the heart, averaging 10–15 mm (0.4–0.6 in.), and forms the
the heart. The inside of the right ventricle contains a series of apex of the heart. Like the right ventricle, the left ventricle
ridges formed by raised bundles of cardiac muscle fibers called contains trabeculae carneae and has chordae tendineae
trabeculae carneae. The cusps of the tricuspid valve are that anchor the cusps of the bicuspid valve to papillary
connected to tendon like cords, the chordae tendineae, which in muscles. Blood passes from the left ventricle through the
turn are connected to cone-shaped trabeculae carneae called aortic valve (aortic semilunar valve) into the ascending
papillary muscles. Internally, the right ventricle is separated from aorta (aorte = to suspend, because the aorta once was
the left ventricle by a partition called the interventricular septum. believed to lift up the heart). Some of the blood in the
Blood passes from the right ventricle through the pulmonary aorta flows into the coronary arteries, which branch from
valve (pulmonary semilunar valve) into a large artery called the the ascending aorta and carry blood to the heart wall. The
pulmonary trunk, which divides into right and left pulmonary remainder of the blood passes into the arch of the aorta
arteries and carries blood to the lungs. Arteries always take blood and descending aorta (thoracic aorta and abdominal
away from the heart (a mnemonic to help you: artery = away). aorta). Branches of the arch of the aorta and descending
aorta carry blood throughout the body. During fetal life, a
temporary blood vessel, called the ductus arteriosus,
Left Atrium The left atrium is about the same thickness as the shunts blood from the pulmonary trunk into the aorta.
right atrium and forms most of the base of the heart. It receives Hence, only a small amount of blood enters the
blood from the lungs through four pulmonary veins. Like the right nonfunctioning fetal lungs. The ductus arteriosus normally
atrium, the inside of the left atrium has a smooth posterior wall. closes shortly aft er birth, leaving a remnant known as the
Because pectinate muscles are confined to the auricle of the left ligamentum arteriosum, which connects the arch of the
atrium, the anterior wall of the left atrium also is smooth. Blood aorta and pulmonary trunk.
passes from the left atrium into the left ventricle through the
bicuspid (mitral) valve (bi- = two), which, as its name implies,
has two cusps.

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