Introduction to Human Anatomy PDF

Summary

This document provides an introduction to human anatomy. It explains the basic organization and functions of the human body. The document also introduces important terminology used in anatomy, such as anatomical position.

Full Transcript

1 AN INTRODUCTION
TO THE HUMAN BODY

I N T R O D U C T I O N You are about to begin a study of
the human body to learn how it is organized and how
it functions. In order to understand what happens
when the body is injured, diseased, or placed
under stress, you must know how it is put
together and how its different parts work. Just
as an auto mechanic must be familiar with the
details of the structure and function of a car,
health-care professionals and others who
work in human performance and care
professions must have intimate knowledge
of the structures and functions of the human
body. This knowledge can be one of your
most effective tools. Much of what you
study in this chapter will help you under-
stand how anatomists visualize the body, and
the basic anatomical vocabulary presented
here will help you describe the body in
a language common to both scientists and
professionals.

Did you ever wonder
why an autopsy
is performed?
You can find out on page 19.
Mark Nielsen 1
CONTENTS AT A GLANCE

1.1 Anatomy Defined 2 1.5 Body Cavities 14
1.2 Levels of Body Organization and Body Systems 3 Thoracic and Abdominal Cavity Membranes 15

1.3 Life Processes 9 1.6 Abdominopelvic Regions and Quadrants 18

1.4 Basic Anatomical Terminology 9 1.7 The Human Body and Disease 19
Anatomical Position 9 1.8 Aging 20
Regional Names 9 1.9 Medical Imaging 20
Planes and Sections 10
1.10 Measuring the Human Body 23
Exhibit 1.A Directional Terms 12

1.1 ANATOMY DEFINED structure, you will learn how the structure of the body often
reflects its functions. Some of the structure–function relation-
OBJECTIVE ships are visibly obvious, such as the tight connections between the
Define anatomy and physiology, and name several bones of the skull, which protect the brain. In contrast, the bones
branches of anatomy. of the fingers are more loosely joined to permit movements such as
playing an instrument, grasping a baseball bat, or retrieving a small
Anatomy (a-NAT-ō-mē; ana-=up; =-tomy=process of cutting)
object from the floor. The shape of the external ear assists in the
is primarily the study of structure and the relationships among
collection and localization of sound waves, which facilitates hear-
structures. It was first studied by dissection (dis-SEK-shun; dis-=
ing. Other relationships are not as visibly obvious; for example, the
apart; -section=act of cutting), the careful cutting apart of body
passageways that carry air into the lungs branch extensively when
structures to study their relationships. Today, a variety of imag-
they reach the lungs. Tiny air sacs—about 300 million—cluster at
ing techniques also contribute to the advancement of anatomical
the ends of the large number of airway branches. Similarly, the ves-
knowledge. We will describe and compare some common imag-
sels carrying blood into the lungs branch extensively to form tiny
ing techniques in Table 1.3, which appears later in this chapter
tubes that surround the small air sacs. Because of these anatomical
(see Section 1.8). The anatomy of the human body can be studied
features, the total surface area within the lungs is about the size of
at various levels of structural organization, ranging from micro-
a handball court. This large surface area is the key to the primary
scopic (visible only with the aid of a microscope) to macroscopic
function of the lungs: the efficient exchange of oxygen and carbon
(visible without the use of a microscope). These levels and the
dioxide between the air and the blood.
different methods used to study them provide the basis for the
branches of anatomy, several of which are described in Table 1.1. CHECKPOINT
Anatomy deals mostly with structures of the body. A related 1. Which branches of anatomy would be used when
discipline, physiology (fiz′-e-OL-o-je; physio-=nature; -logy= dissecting a cadaver?
study of), deals with functions of body parts—that is, how they 2. Give several examples of connections between structure
work. Because function cannot be separated completely from and function in the human body.

TABLE 1.1

Selected Branches of Anatomy
BRANCH STUDY OF

Embryology (em′-brē-OL-ō-jē; In humans, the first eight weeks of development after fertilization of the egg
embry-=embryo; -logy=study of)

Developmental biology The complete developmental history of an individual from fertilization to death
Cell biology Cellular structure and function
Histology Microscopic structure of tissues
(his′-TOL-ō-jē-; hist-=tissue)

Sectional anatomy Internal structure and relationships of the body through the use of sections
Gross anatomy Structures that can be examined without using a microscope
Systemic anatomy Structure of specific systems of the body such as the nervous or respiratory systems
Regional anatomy Specific regions of the body such as the head or chest
Surface anatomy Surface markings of the body to understand the relationships of deep or internal anatomy
through visualization and palpation (gentle touch)
Imaging anatomy Internal body structures that can be visualized with x-rays, CT scans, MRI, and other technologies
Pathological anatomy Structural changes (from gross to microscopic) associated with disease
(path′-ō-LOJ-i-kal; path-=disease)

2
 1.2 LEVELS OF BODY ORGANIZATION AND BODY SYSTEMS 3

C L INIC AL C ON N E C T ION | Noninvasive Diagnostic Techniques
Several noninvasive diagnostic techniques are commonly used by stethoscope to amplify the sounds (Figure C). An example is auscul-
health-care professionals and students to assess certain aspects tation of the lungs during breathing to check for crackling sounds
of body structure and function. A noninvasive diagnostic associated with abnormal fluid accumulation in the air spaces of the
technique is one that does not involve insertion of an instrument lungs. In percussion (pur-KUSH-un; percus-=to beat) the examiner
or device through the skin or into a body opening. In inspection, taps on the body surface with the fingertips and listens to the result-
the first noninvasive diagnostic technique, the examiner observes ing sound. Hollow cavities or spaces produce a different sound than
the body for any changes that deviate from normal (Figure A). For solid organs do (Figure D). For example, percussion may reveal the ab-
example, a physician may examine the mouth cavity for evidence of normal presence of fluid in the lungs or air in the intestines. It is also
disease. In palpation (pal-PĀ-shun; palpa-=to touch) the examiner used to reveal the size, consistency, and position of an underlying
feels body surfaces with the hands (Figure B). An example is palpating structure. An understanding of anatomy is important for the effec-
the neck to detect enlarged or tender lymph nodes. In auscultation tive application of most of these techniques. Also, clinicians use these
(aus′-cul-TĀ-shun; ausculta-=to listen to) the examiner listens to body terms and others covered in this chapter to annotate their findings
sounds to evaluate the functioning of certain organs, often using a following a clinical examination.

Gary Conner/Phototake ©La/Bc.Aigo/Phototake Jose Luis Pelaez/Getty Images, Inc. Malvina Mendil/Science Source Inc
(A) Inspection of oral (mouth) cavity (B) Palpation of lymph nodes in neck (C) Auscultation of lungs (D) Percussion of lungs

1.2 LEVELS smallest building blocks of language, cells are the smallest
living units in the human body. Among the many kinds of
OF BODY ORGANIZATION cells in your body are muscle cells, nerve cells, and blood
AND BODY SYSTEMS cells. Figure 1.1 shows a smooth muscle cell, one of three
types of muscle cells in the body. The cellular level of organi-
OBJECTIVES zation is the focus of Chapter 2.
Describe the levels of structural organization that make
➌ The next level of structural organization is the tissue level.
up the human body. Tissues are groups of cells and the materials surrounding
Outline the 11 systems of the human body, list the organs them that work together to perform a particular function,
present in each, and explain their general functions. similar to the way words are put together to form sentences.
The levels of organization of a language—letters of the alphabet, There are just four basic types of tissue in your body: epithe-
words, sentences, paragraphs, and so on—can be compared to the lial tissue, connective tissue, muscular tissue, and nervous tis-
levels of organization of the human body. Your exploration of the sue. Epithelial tissue covers body surfaces, lines hollow organs
human body will extend from some of the smallest body structures and cavities, and forms glands. Connective tissue connects,
and their functions to the largest structure—an entire person. Or- supports, and protects body organs while distributing blood
ganized from smallest to largest, six levels of organization will help vessels to other tissues. Muscular tissue contracts (shortens)
you to understand anatomy: the chemical, cellular, tissue, organ, to make body parts move and generates heat. Nervous tissue
system, and organismal levels of organization (Figure 1.1). carries information from one part of the body to another.
Chapter 3 describes the tissue level of organization in greater
➊ The chemical level, which can be compared to the letters of detail. Shown in Figure 1.1 is smooth muscle tissue, which
the alphabet, includes atoms, the smallest units of matter that consists of tightly packed smooth muscle cells.
participate in chemical reactions, and molecules, two or ➍ At the organ level, different types of tissues are joined together.
more atoms joined together. Certain atoms, such as carbon Similar to the relationship between sentences and paragraphs,
(C), hydrogen (H), oxygen (O), nitrogen (N), phosphorus organs are structures that are composed of two or more dif-
(P), and calcium (Ca), are essential for life. Two familiar ferent types of tissues; they have specific functions and usually
molecules found in the body are deoxyribonucleic acid have recognizable shapes. Examples of organs are the stomach,
(DNA), the genetic material passed from one generation to heart, liver, lungs, and brain. Figure 1.1 shows how several tis-
the next, and glucose, commonly known as blood sugar. sues make up the stomach. The stomach’s outer covering is
➋ At the cellular level, molecules combine to form cells, which a layer of epithelial and connective tissues that reduces fric-
can be compared to assembling letters into words. Cells are tion when the stomach moves and rubs against other organs.
structures composed of chemicals and are the basic structural Underneath these layers is a type of muscular tissue called
and functional units of an organism. Just as words are the smooth muscle tissue, which contracts to churn and mix food and
4 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

push it on to the next digestive organ, the small intestine. The ➏ The largest organizational level is the organismal level. An
innermost lining, the epithelial tissue layer, produces fluid and organism (OR-ga-nizm), any living individual, can be com-
chemicals responsible for digestion in the stomach. pared to a book in our analogy. All the parts of the human
➎ The next level of structural organization in the body is the body functioning together constitute the total organism.
system level, also called the organ-system level. A system (or In the following chapters, you will study the anatomy and
chapter in our language analogy) consists of related organs some physiology of the body systems. Table 1.2 introduces the
(paragraphs) with a common function. An example is the components and functions of these systems in the order they are
digestive system, which breaks down and absorbs food. Its discussed in the book.
organs include the mouth, salivary glands, pharynx (throat),
esophagus (tube that carries food from the throat to the stom- CHECKPOINT
ach), stomach, small intestine, large intestine, liver, gallblad- 3. Define the following terms: atom, molecule, cell, tissue,
der, and pancreas. Sometimes an organ is part of more than organ, system, and organism.
one system. For example, the pancreas, which has multiple 4. Which body systems help eliminate wastes? (Hint: Refer
functions, is included in the digestive and endocrine systems. to Table 1.2.)

Figure 1.1 Levels of structural organization in the human body.
The levels of structural organization are chemical, cellular, tissue, organ, system, and organismal.
T

2 CELLULAR LEVEL

1 CHEMICAL LEVEL

3 TISSUE LEVEL

Smooth muscle cell

Atoms (C, H, O, N, P)
Smooth muscle tissue
Molecule (DNA)
5 SYSTEM LEVEL
Epithelial
and
connective
tissues
4 ORGAN LEVEL

Salivary glands Mouth
Pharynx (throat)

Smooth muscle
Esophagus tissue layers

Epithelial tissue
Stomach

Stomach
Liver
Pancreas
Gallbladder (behind stomach)

Large intestine Small intestine

Mark Nielsen

6 ORGANISMAL LEVEL
Digestive system

Which level of structural organization is composed of two or more different types of tissues that work together to perform a
specific function?
 1.2 LEVELS OF BODY ORGANIZATION AND BODY SYSTEMS 5

TABLE 1.2

The Eleven Systems of the Human Body

Bone

C rtilage
Ca

Jo
oint

Hair

Skeletal
muscle

Skin and
associated
d T
Tendon
glands

SKELETAL SYSTEM (CHAPTERS 6–9)
Components: Bones and joints of the
body and their associated cartilages.
Fingernails
Functions: Supports and protects the
body; provides a surface area for muscle
attachments; aids body movements;
houses cells that produce blood cells;
stores minerals and lipids (fats).

T
Toenails

INTEGUMENTARY SYSTEM (CHAPTER 5) MUSCULAR SYSTEM (CHAPTERS 10, 11)
Components: Skin, and structures associated with it, Components: Specifically refers to skeletal
such as hair, fingernails and toenails, sweat glands, muscle tissue, which is muscle usually
and oil glands and the subcutaneous layer. attached to bones (other muscle tissues
include smooth and cardiac).
Functions: Protects the body; helps regulate body
temperature; eliminates some wastes; helps make Functions: Participates in bringing about
vitamin D; detects sensations such as touch, body movements, such as walking; maintains
pain, warmth, and cold; stores fat; provides posture; and produces heat.
insulation.
T A B L E 1. 2 C O N T I N U E S
6 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

TABLE 1.2 CONTINUED

The Eleven Systems of the Human Body

Pharyngeal
tonsil
Palatine
tonsil
Thym
mus
Lingual
tonsil
Thoracic
duct

Spleen

Red bone Lymph
marrow n
node

Brain
Lymp
y pha
p atic
vess
sel

Blood
vessels
s:
V
Vein

Heart
Spinal
cord

Artery
r

LYMPHATIC SYSTEM AND IMMUNITY
(CHAPTER 15)
Components: Lymphatic fluid, lymphatic
vessels, spleen, thymus, lymph nodes,
and tonsils; cells that carry out immune
responses (B cells, T cells, and others).
Nerve
Functions: Returns proteins and fluid to
blood; carries lipids from gastrointestinal
tract to blood; contains sites of maturation
and proliferation of B cells and T cells that
protect against disease-causing microbes.

CARDIOVASCULAR SYSTEM NERVOUS SYSTEM
(CHAPTERS 12–14) (CHAPTERS 16–21)
Components: Blood, heart, and blood vessels. Components: Brain, spinal cord, nerves, and
special sense organs, such as the eyes and ears.
Functions: Heart pumps blood through blood
vessels; blood carries oxygen and nutrients to Functions: Generates action potentials (nerve
cells and carbon dioxide and wastes away from impulses) to regulate body activities; detects
cells and helps regulate acid–base balance, changes in the body’s internal and external
temperature, and water content of body fluids; environments, interprets the changes, and
blood components help defend against disease responds by causing muscular contractions or
and repair damaged blood vessels. glandular secretions.
 1.2 LEVELS OF BODY ORGANIZATION AND BODY SYSTEMS 7

RESPIRATORY SYSTEM (CHAPTER 23)
Components: Lungs and air passageways such as the pharynx (throat), larynx (voice
box), trachea (windpipe), and bronchial tubes within the lungs.
Functions: Transfers oxygen from inhaled air to blood and carbon dioxide from
blood to exhaled air; helps regulate acid–base balance of body fluids; air flowing out
of lungs through vocal cords produces sounds.

Nasal cavity
Pharynx
Oral cavity
Larynx
Pharr ynx

Trachea
Lar ynx
x

Bronchus
DIGESTIVE SYSTEM (CHAPTER 24)
ENDOCRINE SYSTEM (CHAPTER 22) Lung
Components: Organs of gastrointestinal
Components: Hormone-producing glands tract—a long tube that includes the
(pineal gland, hypothalamus, pituitary mouth, pharynx (throat), esophagus,
gland, thymus, thyroid gland, parathyroid stomach, small and large intestines,
glands, adrenal glands, pancreas, ovaries, and anus; also includes accessory
and testes) and hormone-producing cells in organs that assist in digestive processes,
several other organs. such as the salivary glands, liver,
Functions: Regulates body activities by gallbladder, and pancreas.
releasing hormones, which are chemical Functions: Achieves physical and
messengers transported in blood from an chemical breakdown of food; absorbs
endocrine gland or tissue to a target organ. nutrients; eliminates solid wastes.

Hyp
pothalam
mus
Saliv
alivar
ary
r Mouth
Pine
eal glan
nd gland
Pitu
uitary gla
and Phar ynxx
Thyroid
d
gland Esophagus

Thyyroid
glan
nd
Parrathyroid
d Adrenaal
glan
nds gland Liver
Posterior view Stomach
Pancreas
Gallbla
adder (behind
Pancreas
e s omach)
st
Small
intestine
Large Rectum
intestine Anus

Testis
T
(male)

Ovary
(female)

T A B L E 1. 2 C O N T I N U E S
8 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

TABLE 1.2 CONTINUED

The Eleven Systems of the Human Body

Ductus
d erens
def

Seminal
vesicle
Penis Prostate
T
Testis

Ductus
deferens

Seminal
vesicle
Prostate
Penis

Epididymis
T
Testis
Mammary
Kidney gland

Ureter
Uterine
tube
Urinary
bladder Ovary

Uterus V
Vagina

Uterine
Urethra
tube

Uterus
Ovary

Vagina

URINARY SYSTEM (CHAPTER 25) REPRODUCTIVE SYSTEMS (CHAPTER 26)
Components: Kidneys, ureters, urinary bladder, Components: Gonads (testes in males and ovaries in females) and associated organs
and urethra. (such as the uterine (fallopian) tubes, uterus, and vagina in females and epididymides,
seminal vesicles, prostate, ductus (vas) deferenses, and penis in males).
Functions: Produces, stores, and eliminates urine;
eliminates wastes and regulates volume and chemical Functions: Gonads produce gametes (sperm or oocytes) that unite to form a new
composition of blood; helps maintain the acid–base organism; gonads also release hormones that regulate reproduction and other body
balance of body fluids; maintains body’s mineral processes; associated organs transport and store gametes; mammary glands produce
balance; helps regulate production of red blood cells. milk.
 1.4 BASIC ANATOMICAL TERMINOLOGY 9

1.3 LIFE PROCESSES This might be true if your upper limbs (described shortly)
are at your sides. But if you held your hands up above your
OBJECTIVE head, your fingers would be above your wrists. To prevent
Define the important life processes of humans. this kind of confusion, anatomists use a standard anatomical
position and a special vocabulary for relating body parts to
All living organisms have certain characteristics that set them
one another.
apart from nonliving things. The following are six important life
processes of humans:
Anatomical Position
1. Metabolism (me-TAB-oˉ-lizm) is the sum of all the chemical
processes that occur in the body. It includes the breakdown In anatomy, the anatomical position (an′-a-TOM-i-kal) is the
of large, complex molecules into smaller, simpler ones and standard position of reference for the description of anatomical
the building up of complex molecules from smaller, simpler structures. In the anatomical position, the subject stands erect
ones. facing the observer, with the head level and the eyes facing
2. Responsiveness is the body’s ability to detect and re- directly forward. The lower limbs are parallel and the feet are
spond to changes in its environment. Nerve cells respond flat on the floor and directed forward. The upper limbs are at the
to changes in the environment by generating electrical sides with the palms facing forward (Figure 1.2). With the body
signals, known as nerve impulses. Muscle cells respond to in the anatomical position, it is easier to visualize and understand
nerve impulses by contracting, which generates force to its organization into various regions and describe relationships
move body parts. of various structures.
3. Movement includes motion of the whole body, individual As just described, in the anatomical position, the body is up-
organs, single cells, and even tiny organelles inside cells. right. There are two terms used to describe a reclining body. If
4. Growth is an increase in body size. It may be due to an in- the body is lying face down, it is in the prone position. If the
crease in (1) the size of existing cells, (2) the number of cells, or body is lying face up, it is in the supine position.
(3) the amount of material surrounding cells.
5. Differentiation (dif′-er-en-sheˉ-A ˉ -shun) is the process whereby
Regional Names
unspecialized cells become specialized cells. Specialized cells
differ in structure and function from the unspecialized cells The human body is divided into several major regions that
that gave rise to them. For example, a single fertilized egg cell can be identified externally. These are the head, neck, trunk,
undergoes tremendous differentiation to develop into a unique upper limbs, and lower limbs. The head consists of the skull
individual who is similar to, yet quite different from, either of and face. The skull encloses and protects the brain, while the
the parents. face is the front portion of the head that includes the eyes,
6. Reproduction (rē-prō-DUK-shun) refers to either (1) the nose, mouth, forehead, cheeks, and chin. The neck, a modi-
formation of new cells for growth, repair, or replacement or fied portion of the trunk, supports the head and attaches it to
(2) the production of a new individual. the remainder of the trunk. The trunk consists of the neck,
thorax, abdomen, and pelvis. Each upper limb (extremity) is
Although not all of these processes are occurring in cells
attached to the trunk and consists of the shoulder, armpit, arm
throughout the body all of the time, when they cease to occur
(portion of the limb from the shoulder to the elbow), forearm
properly cell death may occur. When cell death is extensive and
(portion of the limb from the elbow to the wrist), wrist, and
leads to organ failure, the result is death of the organism.
hand. Each lower limb (extremity) is also attached to the trunk
CHECKPOINT and consists of the buttock, thigh (portion of the limb from the
5. What are the different meanings for growth? buttock to the knee), leg (portion of the limb from the knee to
the ankle), ankle, and foot. The groin is the area on the front
surface of the body marked by a crease on each side, where the
trunk attaches to the thighs. Understanding the precise mean-
ing of arm and forearm in the upper limb and thigh and leg in
1.4 BASIC ANATOMICAL the lower limb is very important when reading or describing a
TERMINOLOGY clinical assessment.
Figure 1.2 shows the anatomical and common names of
OBJECTIVES
major parts of the body. The anatomical term appears first
Describe the orientation of the human body in the
followed by the corresponding common name (in parentheses).
anatomical position.
For example, if you receive a tetanus shot in your gluteal region,
Relate the common names to the corresponding
it is in the buttock. Why is the anatomical term for a body part
anatomical descriptive terms for various regions of the
different from its common name? The anatomical term is based
human body.
on a Greek or Latin word or “root.” For example, the Latin
Define the anatomical planes, the anatomical sections, and
word axilla (ak-SIL-a) is the armpit region. Thus, the axillary
the directional terms used to describe the human body.
nerve is one of the nerves passing within the armpit region.
Scientists and health-care professionals use a common language Understanding the word roots of anatomical terms can help
of special terms when referring to body structures and their you learn the terms more easily. The word roots will become
functions. The language of anatomy has precisely defined mean- more familiar as you read this book, so by the time you finish
ings that allow us to communicate clearly and unambiguously. the course you’ll be able to tell your roommate with confidence
For example, take the statement “The wrist is above the fingers.” that the funnybone she just hit on the door jamb is the olecranon
10 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

Figure 1.2 The anatomical position. The anatomical names and corresponding common names (in parentheses) are
indicated for specific body regions. For example, the cephalic region is the head.

In the anatomical position, the subject stands erect facing the observer with the head level and the eyes facing forward.
The lower limbs are parallel and the feet are flat on the floor and directed forward, and the upper limbs are at the sides with the
T
palms facing forward.

Frontal (forehead)
Temporal (temple)
Cranial Orbital or ocular (eye)
Cephalic (skull)
Otic (ear)
(Head)
Facial Buccal (cheek)
(face) Cephalic
Nasal (nose) (Head)
Cervical Occipital
Oral (mouth) (base of skull)
(Neck)
Mental (chin) Cervical
(Neck)
Axillary Thoracic Sternal (breastbone)
(armpit) (chest)
Scapular
Brachial Mammary (breast) (shoulder blade)
(arm)
Umbilical Vertebral
Abdominal (spinal column)
Antecubital (navel)
(abdomen)
Dorsal
Trunk

(front of elbow) Coxal (hip)
Olecranal or (back)
Inguinal
Antebrachial (groin) cubital
Upper
(forearm) (back of elbow)
limb
Pelvic Sacral Lumbar (loin)
Carpal (pelvis) (between
(wrist) hips)
Pollex
Palmar (thumb)
or volar
(palm) Gluteal
Manual (buttock)
Digital or (hand)
Perineal (region
phalangeal of anus and
(fingers) Femoral external genitals)
Pubic Dorsum
(thigh) (pubis) (back of
hand)
Patellar
Popliteal Lower
(anterior surface of knee)
(hollow behind knee) limb
Crural
(leg)
Sural
Tarsal (calf)
(ankle)
Pedal
(foot) Digital or
phalangeal
Dorsum
(toes) Plantar
(top of foot)
(sole)
Hallux Calcaneal
(a) Anterior view (great toe) (b) Posterior view (heel)

Why is it important to define one standard anatomical position?

region (elbow) of her brachium (arm) (not that it will help pass through the body (Figure 1.3). A sagittal plane (SAJ-i-
much with the pain). tal; sagitta-=arrow) is a vertical plane that divides the body or
organ into right and left sides. More specifically, when such
a plane passes through the midline of the body and divides it
Planes and Sections into equal right and left sides, it is called a midsagittal plane,
As you have just seen, referencing various body regions enables or a median plane. The midline is an imaginary vertical line that
you to study the surface anatomy of the body. It is also possible divides the body into equal left and right sides. If the sagittal
to study the internal structure of the body by slicing the body plane does not pass through the midline but instead divides the
in different ways and examining the sections. The terms that body into unequal right and left sides, it is called a parasagittal
follow describe the different planes and sections you will en- plane (para-=beside, near). A frontal, or coronal, plane (kō-
counter in your anatomical studies; they are also used in many RŌ-nal; corona=crown) divides the body or an organ into front
medical procedures. Planes are imaginary flat surfaces that and back portions. A transverse plane divides the body or an
 1.4 BASIC ANATOMICAL TERMINOLOGY 11

Figure 1.3 Planes through the human body. Figure 1.4 Planes and sections through different parts of
the brain. The diagrams (left) show the planes,
M
Midsagittal, parasagittal, frontal, transverse, and oblique and the photographs (right) show the resulting
planes divide the body in specific ways.
p sections. Note: The “view” arrows in the diagrams
indicate the direction from which each section is
viewed. This aid is used throughout the book to
indicate viewing perspective.
Frontal P
Planes divide the body in various ways and the resulting
plane
ccuts made along a plane are called sections.

Midsagittal plane
Parasagittal
plane

View
Midsagittal section
Transverse (a)
plane Midsagittal
plane
(through
Frontal plane
midline)

Oblique
plane

View

Frontal section

(b)

Anterolateral view View
Transverse
plane

Which plane divides the heart into anterior and
posterior portions?
Posterior Anterior

Transverse section
organ into upper and lower portions. A transverse plane may
also be termed a cross-sectional plane or horizontal plane. Sag- (c)
ittal, frontal, and transverse planes are all at right angles to
one another. An oblique plane (ō-BLĒK), by contrast, passes
Which plane divides the brain into equal right and left
through the body or organ at an oblique angle (any angle other sides?
than a 90° angle).
When you study a body region, you often view it in section.
Sections are cuts of the body or one of its organs made along
one of the planes just described. A section produces a flat two- CHECKPOINT
dimensional surface of the original three-dimensional struc- 6. Describe the anatomical position and explain why it is used.
ture. It is important to know the plane of the section so you 7. Locate each region shown in Figure 1.2 on your own
can understand the anatomical relationship of one part to body, and then identify it by its anatomical descriptive
another. Figure 1.4 indicates how three different sections— form and corresponding common name.
a midsagittal section, a frontal section, and a transverse (cross) 8. Which of the planes that divide the body are vertical?
section—provide different views of the brain. 9. What is the difference between a plane and a section?
12 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

E X HIBIT 1.A Directional Terms (Figure 1.5)
OBJECTIVE lower part of the body. It is important to understand that direc-
Define each directional term used to describe the human tional terms have relative meanings; they make sense only when
body. used to describe the position of one structure relative to another.
For example, your knee is superior to your ankle, even though both
Overview are located in the inferior half of the body. Study the directional
terms below and the example of how each is used. As you read the
To help improve communication when discussing the basic parts
examples, look at Figure 1.5 to see the location of each structure.
of the body and the relationships those parts have to one another,
anatomists and health-care professionals use specific directional
terms, words that describe the position of one body part rela- CHECKPOINT
tive to another. Most of the directional terms used to describe the 10. Which directional terms can be used to specify the
relationship of one part of the body to another can be grouped into relationships between (1) the elbow and the shoulder,
pairs that have opposite meanings. For example, superior means (2) the left and right shoulders, (3) the sternum and the
toward the upper part of the body, and inferior means toward the humerus, and (4) the heart and the diaphragm?

DIRECTIONAL TERM DEFINITION EXAMPLE OF USE

Superior (soo′-PĒR-ē-or) Above or higher in position; toward the head. The heart is superior to the liver.
(Not used in reference to the limbs.)
Cranial (KRĀN-ē-al) or Relating to the skull or head; toward the head. The stomach is more cranial than the urinary
cephalic (se-FAL-ik) (This is a more flexible term than superior because bladder.
it can be applied to all animals, whether they stand
upright on two limbs or on all four limbs.)
Inferior (in′-FĒR-ē-or) Below or lower in position; toward the feet. (Not The stomach is inferior to the lungs.
used in reference to the limbs.)
Rostral (ROS′-tral) Relating to the nose and mouth region; toward The frontal lobe of the brain is rostral to the
the face. (Used only in references within the head). occipital lobe (see Figure 18.12b).
Caudal (KAWD-al) Relating to the tail; at or near the tail or posterior The lumbar vertebrae are caudal to the cervical
part of the body. (Used only in references within the vertebrae (see Figure 7.15a).
trunk).
Anterior (an-TĒR-ē-or) Nearer to or at the front of the body. The sternum (breastbone) is anterior to the heart.
Posterior (pos-TĒR-ē-or) Nearer to or at the back of the body. The esophagus (food tube) is posterior to the
trachea (windpipe).
Ventral (VEN-tral) Relating to the belly side of the body; toward the The intestines are ventral to the vertebral
belly. (Used synonymously with anterior in human column.
anatomy.)
Dorsal (DORS-al) Relating to the back side of the body; toward the The kidneys are dorsal to the stomach.
back. (Used synonymously with posterior in
human anatomy.)
Medial (MĒ-dē-al) Nearer to the midline (an imaginary vertical line The ulna is medial to the radius.
that divides the body into equal right and left sides).
Lateral (LAT-er-al) Farther from the midline. The lungs are lateral to the heart.
Intermediate (in′-ter-MĒ-dē-at) Between two structures. The transverse colon is intermediate to the
ascending colon and descending colon.
Ipsilateral (ip-si-LAT-er-al) On the same side of the body’s midline as another The gallbladder and ascending colon are
structure. ipsilateral.
Contralateral On the opposite side of the body’s midline from The ascending and descending colons are
(CON-tra-lat-er-al) another structure. contralateral.
Proximal (PROK-si-mal) Nearer to the attachment of a limb to the trunk; The humerus (arm bone) is proximal to the
nearer to the origination of a structure. radius.
Distal (DIS-tal) Farther from the attachment of a limb to the trunk; The phalanges (finger bones) are distal to the
farther from the origination of a structure. carpals (wrist bones).
Superficial (soo′-per-FISH-al) Toward or on the surface of the body. The ribs are superficial to the lungs.
Deep Away from the surface of the body. The ribs are deep to the skin of the chest and back.
 1.4 BASIC ANATOMICAL TERMINOLOGY 13

DIRECTIONAL TERM DEFINITION EXAMPLE OF USE

External (ex-STERN-al) Toward the outside of a structure. (Is typically used The visceral pleura is on the external surface of
when describing relationships of individual organs.) the lungs (see Figure 1.7a).
Internal (in-TERN-al) Toward the inside of a structure. (Is typically used The mucosa forms the internal lining of the
when describing relationships of individual organs.) stomach (see Figure 24.11a).

Figure 1.5 Directional terms.
Directional terms precisely locate various parts of the body relative to one another.
D

LATERAL MEDIAL LATERAL
SUPERIOR
Midline

Esophagus (food tube)
Trachea (windpipe)

PROXIMAL

Rib

Right lung
Left lung

Sternum
(breastbone)
Heart
Humerus

Stomach

Liver
Transverse colon

Radius Small intestine

Ulna Gallbladder
Descending colon

Ascending
colon

Carpals

Metacarpals

Phalanges

DISTAL
INFERIOR
Anterior view of trunk and right upper limb

Is the radius proximal to the humerus? Is the esophagus anterior to the trachea? Are the ribs superficial to the lungs? Is the
urinary bladder medial to the ascending colon? Is the sternum lateral to the descending colon?
 1.5 BODY CAVITIES 15

system. Organs inside the thoracic and abdominopelvic cavities of the lungs (the part of the balloon touching your fist); the
are termed the viscera (VIS-er-a). parietal pleura lines the chest wall and covers the superior sur-
face of the diaphragm. In between is the serous cavity called
the pleural cavity (analogous to the inside of the balloon). The
Thoracic and Abdominal Cavity Membranes serous membrane of the heart is the pericardium (per′-i-KAR-
A membrane is a thin pliable tissue that covers, lines, partitions, dē-um) (see Figure 1.7a, c, d). The visceral pericardium covers
or connects structures. One example is a slippery double-layered the surface of the heart, and the parietal pericardium lines the
membrane associated with body cavities that does not open directly fibrous pericardium that surrounds the heart. Between them is
to the exterior called a serous membrane. It covers the viscera the serous cavity called the pericardial cavity. The peritoneum
within the thoracic and abdominal cavities and also lines the walls (per′-i-to-NE-um) is the serous membrane of the abdomi-
of the thorax and abdomen. The parts of a serous membrane are nal cavity (see Figure 24.3a). The visceral peritoneum covers
(1) the parietal layer (pa-RĪ-e-tal=wall of a cavity), a thin epithe- the abdominal viscera, and the parietal peritoneum lines the ab-
lium that lines the walls of the body cavities, and (2) the visceral dominal wall and covers the inferior surface of the diaphragm.
layer (VIS-er-al), a thin epithelium that covers and adheres to the Between them is the serous cavity called the peritoneal cavity.
viscera within the body cavities. Because the parietal and visceral Most abdominal organs are surrounded by the peritoneum and
membranes are continuous with one another, they form a serous are referred to as intraperitoneal (in′-tra-per′-i-tō-NĒ-al; intra-
sac. The organs of the body cavity push into this serous sac, simi- =within). These include the stomach, spleen, liver, gallblad-
lar to pushing your hand into a balloon (Figure 1.7e). Between der, jejunum and ileum of the small intestine, and the cecum,
the parietal and visceral layers is a potential space called the serous appendix, and tranverse colon of the large intestine. However,
cavity. It contains a small amount of lubricating fluid called serous some are not surrounded by the peritoneum or are only par-
fluid that reduces friction between the two layers, allowing the tially covered by peritoneum and lie behind the peritoneum.
viscera to slide freely during movements such as the pumping of Such organs are said to be retroperitoneal (re-trō-per′-i-tō-
the heart or the inflation and deflation of your lungs when you NĒ-al; retro=behind). The kidneys, adrenal glands, pancreas,
breathe in and out. duodenum of the small intestine, ascending and descending
The serous membrane associated with the lungs is called the colons of the large intestine, and the abdominal aorta and inferior
pleura (Figure 1.7a, c, d). The visceral pleura clings to the surface vena cava are retroperitoneal organs.

Brain in
cranial
cavity

Spinal cord in
vertebral
canal Lung
Thoracic
Heart in
Heart cavity
thoracic cavity
Diaphragm
Vertebral
column Diaphragm
Liver and
intestines
in abdominal
cavity Liver

Abdominopelvic
cavity

Urinary bladder Intestines
in pelvic cavity

Dissection Shawn Miller; Photograph Mark Nielsen Dissection Shawn Miller; Photograph Mark Nielsen

(c) Sagittal section (d) Anterior view

In which cavities are the following organs located: urinary bladder, stomach, heart, small intestine, lungs, internal female
reproductive organs, thymus, spleen, liver? Use the following symbols for your responses: T = thoracic cavity, A = abdominal
cavity, or P = pelvic cavity.
16 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

In addition to the major body cavities just described, you movable joints and contain synovial fluid (see Figure 9.3a). A
will learn about other regional cavities in later chapters. These summary of the major body cavities and their membranes is
include the oral (mouth) cavity, which contains the tongue presented in the table in Figure 1.6.
and teeth (see Figure 24.4); the nasal cavity in the nose (see
Figure 23.1a); the orbital cavities (orbits), which contain the CHECKPOINT
eyeballs (see Figure 7.2a); the middle ear cavities (middle ears), 11. What structures separate the various body cavities from
which contain small bones and muscles in the middle ear one another?
(Figure 21.11a); and synovial cavities, which are found in freely 12. Describe the contents of the mediastinum.

Figure 1.7 The thoracic cavity. The black dashed lines in (a) and (b) indicate the borders of the mediastinum. Notice
that the pericardium surrounds the heart, and that the pleurae surround the lungs. Note: When transverse
sections such as those shown in (b) and (c) are viewed inferiorly (from below), the anterior aspect of the body
appears on the top of the illustration and the left side of the body appears on the right side of the illustration.

T mediastinum is an anatomical region that is between the lungs and extends from the sternum to the vertebral column
The
and from the first rib to the diaphragm.
a

Mediastinum

Right pleural
cavity Parietal pericardium

Pleura Pericardial cavity Pericardium
Parietal pleura
Visceral pericardium
Visceral pleura
Diaphragm
Left pleural cavity

(a) Anterior view of thoracic cavity

Transverse plane

ANTERIOR
View

Sternum
(breastbone)
Muscle
Thymus
Heart

Pericardial cavity
Left lung
Right lung

Esophagus
Aorta (food tube)

Right pleural Vertebral column
cavity (backbone)

Left pleural
Rib cavity

(b) Inferior view of transverse section of thoracic cavity
 1.5 BODY CAVITIES 17

ANTERIOR
Sternum
Parietal
pericardium
Parietal pleura Pericardial
Pericardium
cavity
Right pleural Visceral
Pleura cavity pericardium

Heart
View
Visceral pleura

Skin
Esophagus
Aorta
Right lung
Vertebral column
(backbone)
Rib Spinal cord

MEDIAL
Mark Nielsen
(c) Inferior view of transverse section of thoracic cavity

Parietal
pericardium
Pericardial
Right Pericardium
cavity
lung
Visceral
pericardium

Heart
Visceral pleura
(covering lung)

Parietal pleura
(covering fibrous
pericardium)
Diaphragm Pleura
Parietal pleura
(lining rib cage)

Pleural cavity
Parietal pleura
Dissection Shawn Miller; Photograph Mark Nielsen (covering diaphragm)
(d) Layers of the pericardium and pleura

Parietal layer
(outer wall of
balloon)
Serous cavity
(containing small
Organ amount of
lubricating serous fluid)
Visceral layer
(inner wall of
balloon)

(e) The concept of a serous sac
Which of the following structures are contained in the mediastinum: right lung, heart, esophagus, spinal cord, trachea, rib,
thymus, left pleural cavity?
18 CHAPTER 1 AN INTRODUCTION TO THE HUMAN BODY

1.6 ABDOMINOPELVIC REGIONS dividing the abdominopelvic cavity into smaller areas. In the first
method, two transverse and two vertical lines, aligned like a tick-
AND QUADRANTS tack-toe grid, partition this cavity into nine abdominopelvic
regions (Figure 1.8). The superior horizontal line, the subcostal
OBJECTIVE
line (sub-=below; costal=rib), passes across the lowest level of the
Name and describe the abdominopelvic regions and the
10th costal cartilages (see also Figure 7.23c); the inferior hori-
abdominopelvic quadrants.
zontal line, the transtubercular line (trans-too-BER-kū-lar), passes
To describe the location of the many abdominal and pelvic or- across the superior margins of the iliac crests of the right and left
gans more easily, anatomists and clinicians use two methods of hip bones (see also Figure 8.7). Two vertical lines, the left and

Figure 1.8 Abdominopelvic regions. (a) The nine regions in surface view. (b) The nine regions with the greater omentum
removed. The greater omentum is a double fold of the serous membrane that contains fatty tissue and covers some
of the abdominal organs (see Figure 24.3). (c) Organs or parts of organs in the nine regions. The internal reproductive
organs in the pelvic cavity are shown in Figures 26.1 and 26.11.

The nine-region designation is used for anatomical studies.
T

Clavicles

Midclavicular lines

Right Left

Left
Epigastric hypochondriac
Right region region
hypochondriac
region Subcostal line
Left lumbar
Right Umbilical region
lumbar region
region
Transtubercular line
Pubic
Right inguinal Left inguinal
region
region region

Andy Washnik

(a) Anterior view showing abdominopelvic regions

Clavicles

Midclavicular lines

Right Left

Right Left Right lobe Spleen
Epigastric of liver Left lobe of liver
hypochondriac hypochondriac
region
region region Stomach
Gallbladder
10th costal Transverse colon
cartilage of large intestine
Ascending colon
Right Umbilical Left
of large intestine Descending colon
lumbar region lumbar
region region of large intestine
Small intestine
Cecum
Pubic Appendix
Right inguinal region Left inguinal
region region Urinary
bladder

(b) Anterior view showing location of abdominopelvic regions (c) Anterior superficial view of organs in abdominopelvic regions

In which abdominopelvic region is each of the following found: most of the liver, transverse colon, urinary bladder, spleen?
 1.7 THE HUMAN BODY AND DISEASE 19

right midclavicular lines (mid-kla-VIK-ū-lar), are drawn through
CLIN ICA L CON N ECTI O N | Autopsy
the midpoints of the clavicles (collar bones), just medial to the
nipples. The four lines divide the abdominopelvic cavity into a An autopsy (AW-top-seˉ; auto-=self; -opsy=to see) or necropsy is
larger middle section and smaller left and right sections. The a postmortem (after-death) examination of the body and dissec-
names of the nine abdominopelvic regions are right hypochon- tion of its internal organs to confirm or determine the cause of
driac (hı̄′-pō-KON-drē-ak), epigastric (ep-i-GAS-trik), left death. An autopsy can uncover the existence of diseases not detected
hypochondriac, right lumbar, umbilical (um-BIL-i-kal), left during life, determine the extent of injuries, and explain how those
lumbar, right inguinal (iliac) (IN-gwi-nal), hypogastric (pubic), injuries may have contributed to a person's death. It also may support
and left inguinal (iliac). Note which organs and parts of organs the accuracy of diagnostic tests, establish the beneficial and adverse
are in the different regions by carefully examining Figure 1.8c. effects of drugs, reveal the effects of environmental influences on the
body, provide more information about a disease, assist in the accumu-
The organs of the abdominopelvic cavity will be discussed in de-
lation of statistical data, and educate health-care students. Moreover,
tail in later chapters.
an autopsy can reveal conditions that may affect offspring or siblings
The second method is simpler and divides the abdominopel-
(such as congenital heart defects). An autopsy may be legally required,
vic cavity into quadrants (KWOD-rantz; quad-=one-fourth), as
such as in the course of a criminal investigation, or may be used to re-
shown in Figure 1.9. In this method, a transverse line, the trans- solve disputes between beneficiaries and insurance companies about
umbilical line, and a midsagittal line, the median line, are passed the cause of death. Because it is so important for the clinician perform-
through the umbilicus (um-BIL-i-kus or um-bi-LĪ–kus; umbilic- ing the autopsy to record and detail the findings accurately, complete
=navel) or belly button. The names of the abdominopelvic quad- knowledge of the terms outlined in this chapter is essential.
rants are right upper quadrant (RUQ), left upper quadrant
(LUQ), right lower quadrant (RLQ), and left lower quadrant
(LLQ). The nine-region division is widely used for anatomical
studies to determine organ location; quadrants are more com- CHECKPOINT
monly used by clinicians for describing the site of abdominopel- 13. Locate the abdominopelvic regions and the abdomi-
vic pain, tumor, injury, or other abnormality. nopelvi