Anatomy of the
Heart
The
heart is located in the thoracic cavity between the lungs within the
mediastinum.
1. Keeps O2 – poor blood separate from o2- rich
blood.
2. Keeps the blood flowing in one direction blood flows
away from the then back to the heart in each circuit.
3. Creates blood pressure, which moves the blood through
the circuits
4. Regulates the blood supply based on the current needs
of the body.
The Cardiovascular System of the body
The
Systemic Circuit to the body
The
right side of the Heart pumps blood through vessels of the pulmonary circuit.
The left side of the heart pumps blood through vessels of the systemic circuit.
Gas exchange occurs as blood passes through lung (pulmonary) capillaries. Gas
exchange and nutrient-for-waste exchange occur as blood passes through tissue
(systemic) capillaries. In this illustration, red vessels carry O2 – rich
blood, and bule vessels carry o2- poor blood.
Good
Cardiovascular health is important in maintaining overall health and wellness.
Cardiovascular Health is a new section, which will teach you how your heart and
cardiovascular system work when healthy, and what happens when diseased. We
will also explore disease prevention, therapeutic drug treatment, minimally
invasive surgical procedures and open surgical procedures for treating
diseases, which affect the heart and cardiovascular system.
The average adult has
between 5 to 6 liters of blood or blood volume. The blood carries oxygen and
essential nutrients to all of the living cells in the body, and also carries
waste products to systems that eliminate them. Most of the blood is made up of
a watery, protein-laden fluid called plasma. A little less than half of this
blood volume is composed of red and white blood cells, and other solid elements
called platelets.
Platelets are
responsible for coagulation of blood at the point of an injury to a blood
vessel.
Without
platelets, our blood would not be able to clot and hemorrhaging or uncontrolled
bleeding would result. Hemophilia is a genetic condition, which results in
individuals with no ability to clot. Also called bleeders, these individuals
must periodically administer a clotting factor to their blood to prevent the
constant bleeding, which occurs.
Examine how platelets
work to form clots. Here's a cut section of a small artery. The traffic going
by includes red blood cells carrying oxygen; platelets, which come from white
blood cell fragments; and clotting factors, which help the blood to clot. When
a blood vessel becomes damaged, as shown here, the blood cells and plasma begin
oozing out into the surrounding tissue. This begins the clotting process.
Platelets immediately begin to adhere to the cut edges of the artery; they
release chemicals to attract even more platelets. Eventually a platelet plug is
formed, and the external bleeding stops.
Inside, the clotting
factors take a much more active role by creating a cascade of clotting
activity. The clotting factors cause strands of blood-borne material, called
fibrin, to stick together and seal the inside of the wound. Eventually, the cut
blood vessel heals, and the blood clot dissolves after several days.
While
platelets play an important role in clotting, red blood cells carry on the
important job of carrying oxygen and other nutrients to all the tissues of the
body and carrying waste products to the organs, which remove them from the body.
How Red Blood Cells
Carry Oxygen
Red blood cells are
the oxygen carriers. As they travel away from the heart, they traverse smaller
and smaller arteries, finally arriving at the collections of microscopic blood
vessels known as capillaries. Here, they exchange nutrients and oxygen for
cellular waste products. The waste products are eventually eliminated from the
blood stream through the urinary and respiratory systems.
The exchange of oxygen
and nutrients between the red blood cells and the surrounding tissues occurs
through a process called diffusion. In diffusion, when capillaries contain a
high concentration of oxygen and nutrients, while the surrounding tissues
contain a lower concentration, Oxygen and nutrients leave the capillaries and
enter the tissues.
Conversely,
when body tissues contain high concentrations of carbon dioxide and metabolic
waste, while the capillaries contain a lower concentration, the waste products
diffuse from the tissues into the capillaries and from there are carried by the
venous system back toward the heart.
Blood Pressure
The
red blood cells transport oxygen and waste products by flowing through the
blood vessels. What causes blood to flow through the vessels is blood pressure.
Just as water flows through pipes from areas of greater pressure to lesser, so
too the blood flows through the body from areas of higher pressure to areas of
lower pressure. Blood pressure is measured both as the heart contracts, which
is called systole, and as it relaxes, which is called diastole. A systolic
blood pressure of 120 millimeters of mercury is considered right in the middle
of the range of normal blood pressures, as is a diastolic pressure of eighty.
In common terms, this normal measurement would be stated as "120 over
80".
Normal blood pressure
is important for proper blood flow to the body's organs and tissues. Each
heartbeat forces blood to the rest of the body. The force of the blood on the walls
of the arteries is called blood pressure. Blood pressure moves from high
pressure near the heart to low pressure away from the heart. Blood pressure
depends on many factors, including the amount of blood pumped by the heart. The
diameter of the arteries through which blood is pumped is also an important
factor. Generally, blood pressure is higher when more blood is pumped by the
heart, and the diameter of an artery is narrow.
Systolic
pressure is measured when the heart ventricles contract. Diastolic pressure is
measured when the heart ventricles relax. Stressful situations can result in a
temporary increase in blood pressure. If an individual were to have a
consistent blood pressure reading of 140 over 90, he would be evaluated for
having high blood pressure. If left untreated, high blood pressure can damage
important organs, such as the brain and kidneys as well as lead to a stroke.
The Heart (The
Pump)
The pressure and flow
of the blood arise from the beating heart muscle, which is the pump of the cardiovascular
system. To understand how the heart works lets take a brief look at the anatomy
of the beating heart.
The
heart is a four-chambered organ with four main vessels, which either bring
blood to or carry blood away from the heart. The four chambers of the heart
are: the right atrium, the right ventricle, the 
The great vessels that
you see include the superior and inferior vena cava, which bring blood from the
body to the right atrium. The pulmonary artery, which transports blood from the
right ventricle to the lungs, and the aorta, the body's largest artery, which
transports oxygen-rich blood from the left ventricle to the rest of the body.
If
you look carefully, you can see a series of one-way valves that keep the blood
flowing in one direction. The blood first enters the heart into the right
atrium. A contraction of the right atrium then forces blood through the
tricuspid valve and into the right ventricle. When the right ventricle
contracts, the muscular force pushes blood through the pulmonary semilunar
valve into the pulmonary artery.
The
blood then travels to the lungs, where it receives oxygen. Next, it drains out
of the lungs via the pulmonary veins, and travels to the left atrium. From the
left atrium, the blood is forced through the bicuspid valve into the critically
important left ventricle. The left ventricle is the major muscular pump that
sends the blood out to the body systems. When the left ventricle contracts, it
forces the blood through the aortic semilunar valves and into the aorta. From
here, the aorta and its branches carry blood to all the tissues of the body.
