What Is Anatomy PDF

Summary

This document is an introductory guide to the study of human anatomy. It explains the concept of gross and microscopic anatomy and the different approaches to studying it. It also describes the importance of anatomy in various medical specialties and explains some key anatomical terms and planes.

Full Transcript

What is anatomy?

Anatomy includes those structures that can be seen grossly

(without the aid of magnification) and microscopically

(with the aid of magnification). Typically, when used by

itself, the term anatomy tends to mean gross or macroscopic

anatomy---that is, the study of structures that can be seen

without using a microscopic. Microscopic anatomy, also

called histology, is the study of cells and tissues using a

microscope.

Anatomy forms the basis for the practice of medicine.

Anatomy leads the physician toward an understanding of

a patient's disease, whether he or she is carrying out a

physical examination or using the most advanced imaging

techniques. Anatomy is also important for dentists, chiro-

practors, physical therapists, and all others involved in any

aspect of patient treatment that begins with an analysis of

clinical signs. The ability to interpret a clinical observation

correctly is therefore the endpoint of a sound anatomical

understanding.

Observation and visualization are the primary tech-

niques a student should use to learn anatomy. Anatomy is

much more than just memorization of lists of names.

Although the language of anatomy is important, the

network of information needed to visualize the position of

physical structures in a patient goes far beyond simple

memorization. Knowing the names of the various branches

of the external carotid artery is not the same as being able

to visualize the course of the lingual artery from its origin

in the neck to its termination in the tongue. Similarly,

understanding the organization of the soft palate, how it is

related to the oral and nasal cavities, and how it moves

during swallowing is very different from being able to recite

the names of its individual muscles and nerves. An under-

standing of anatomy requires an understanding of the

context in which the terminology can be remembered.

2

How can gross anatomy be studied?

The term anatomy is derived from the Greek word temnein,

meaning "to cut." Clearly, therefore, the study of anatomy

is linked, at its root, to dissection, although dissection of

cadavers by students is now augmented, or even in some

cases replaced, by viewing prosected (previously dissected)

material and plastic models, or using computer teaching

modules and other learning aids.

Anatomy can be studied following either a regional or a

systemic approach.

With a regional approach, each region of the body

is studied separately and all aspects of that region

are studied at the same time. For example, if the thorax

is to be studied, all of its structures are examined.

This includes the vasculature, the nerves, the bones,

the muscles, and all other structures and organs

located in the region of the body defined as the

thorax. After studying this region, the other regions of

the body (i.e., the abdomen, pelvis, lower limb, upper

limb, back, head, and neck) are studied in a similar

fashion.

In contrast, in a systemic approach, each system of

the body is studied and followed throughout the entire

body. For example, a study of the cardiovascular system

looks at the heart and all of the blood vessels in the body.

When this is completed, the nervous system (brain,

spinal cord, and all the nerves) might be examined in

detail. This approach continues for the whole body until

every system, including the nervous, skeletal, muscular,

gastrointestinal, respiratory, lymphatic, and reproduc-

tive systems, has been studied.

Each of these approaches has benefits and deficiencies.

The regional approach works very well if the anatomy

course involves cadaver dissection but falls short when

it comes to understanding the continuity of an entire

system throughout the body. Similarly, the systemic

approach fosters an understanding of an entire system

throughout the body, but it is very difficult to coordinate

this directly with a cadaver dissection or to acquire suffi-

cient detail.

Important anatomical terms

The anatomical position

The anatomical position is the standard reference position

of the body used to describe the location of structures (Fig.

1.1). The body is in the anatomical position when standing

upright with feet together, hands by the side and face

looking forward. The mouth is closed and the facial expres-

sion is neutral. The rim of bone under the eyes is in the

same horizontal plane as the top of the opening to the

ear, and the eyes are open and focused on something in

the distance. The palms of the hands face forward with the

fingers straight and together and with the pad of the thumb

turned 90° to the pads of the fingers. The toes point

forward.

Anatomical planes

Three major groups of planes pass through the body in the

anatomical position (Fig. 1.1).What Is Anatomy Important Anatomical
Terms

1

*Superior*

**Coronal plane**

Inferior margin of orbit level with

top of external auditory meatus

Face looking forward

**Sagittal plane**

*Anterior Posterior*

*Medial*

**Transverse, horizontal,**

**or axial plane**

Hands by sides

palms forward

*Lateral*

Feet together

toes forward

*Inferior*

Fig. 1.1 The anatomical position, planes, and terms of location and
orientation.

3The Body

Coronal planes are oriented vertically and divide the

body into anterior and posterior parts.

Sagittal planes also are oriented vertically but are at

right angles to the coronal planes and divide the body

into right and left parts. The plane that passes through

the center of the body dividing it into equal right and

left halves is termed the median sagittal plane.

Transverse, horizontal, or axial planes divide the

body into superior and inferior parts.

Terms to describe location

Anterior (ventral) and posterior (dorsal),

medial and lateral, superior and inferior

Three major pairs of terms are used to describe the location

of structures relative to the body as a whole or to other

structures (Fig. 1.1).

Anterior (or ventral) and posterior (or dorsal)

describe the position of structures relative to the "front"

and "back" of the body. For example, the nose is an

anterior (ventral) structure, whereas the vertebral

column is a posterior (dorsal) structure. Also, the nose

is anterior to the ears and the vertebral column is pos-

terior to the sternum.

Medial and lateral describe the position of structures

relative to the median sagittal plane and the sides of

the body. For example, the thumb is lateral to the little

finger. The nose is in the median sagittal plane and

is medial to the eyes, which are in turn medial to the

external ears.

Superior and inferior describe structures in reference

to the vertical axis of the body. For example, the head is

superior to the shoulders and the knee joint is inferior

to the hip joint.

Proximal and distal, cranial and caudal,

and rostral

Other terms used to describe positions include proximal

and distal, cranial and caudal, and rostral.

4

Proximal and distal are used with reference to being

closer to or farther from a structure's origin, particu-

larly in the limbs. For example, the hand is distal to the

elbow joint. The glenohumeral joint is proximal to

the elbow joint. These terms are also used to describe

the relative positions of branches along the course of

linear structures, such as airways, vessels, and nerves.

For example, distal branches occur farther away toward

the ends of the system, whereas proximal branches

occur closer to and toward the origin of the system.

Cranial (toward the head) and caudal (toward the tail)

are sometimes used instead of superior and inferior,

respectively.

Rostral is used, particularly in the head, to describe the

position of a structure with reference to the nose. For

example, the forebrain is rostral to the hindbrain.

Superficial and deep

Two other terms used to describe the position of structures

in the body are superficial and deep. These terms are

used to describe the relative positions of two structures

with respect to the surface of the body. For example, the

sternum is superficial to the heart, and the stomach is deep

to the abdominal wall.

Superficial and deep can also be used in a more absolute

fashion to define two major regions of the body. The super-

ficial region of the body is external to the outer layer of

deep fascia. Deep structures are enclosed by this layer.

Structures in the superficial region of the body include the

skin, superficial fascia, and mammary glands. Deep struc-

tures include most skeletal muscles and viscera. Superficial

wounds are external to the outer layer of deep fascia,

whereas deep wounds penetrate through it.Imaging

Diagnostic imaging techniques

In 1895 Wilhelm Roentgen used the X-rays from a cathode

ray tube to expose a photographic plate and produce the

first radiographic exposure of his wife's hand. Over the past

35 years there has been a revolution in body imaging,

which has been paralleled by developments in computer

technology.

Plain radiography

X-rays are photons (a type of electromagnetic radiation)

and are generated from a complex X-ray tube, which is a

type of cathode ray tube (Fig. 1.2). The X-rays are then

collimated (i.e., directed through lead-lined shutters to stop

them from fanning out) to the appropriate area of the body.

As the X-rays pass through the body they are attenuated

(reduced in energy) by the tissues. Those X-rays that pass

through the tissues interact with the photographic film.

In the body:

air attenuates X-rays a little;

fat attenuates X-rays more than air but less than

water; and

bone attenuates X-rays the most.

These differences in attenuation result in differences in

the level of exposure of the film. When the photographic

film is developed, bone appears white on the film because

this region of the film has been exposed to the least amount

of X-rays. Air appears dark on the film because these

regions were exposed to the greatest number of X-rays.

Modifications to this X-ray technique allow a continu-

ous stream of X-rays to be produced from the X-ray tube

and collected on an input screen to allow real-time visual-

ization of moving anatomical structures, barium studies,

angiography, and fluoroscopy (Fig. 1.3). Imaging Diagnostic Imaging
Techniques

1

Tungsten targetTungsten filament

Focusing cup Glass X-ray tube

Cathode

Anode

X-rays

Fig. 1.2 Cathode ray tube for the production of X-rays.

Fig. 1.3 Fluoroscopy unit.

5The Body

Contrast agents

To demonstrate specific structures, such as bowel loops or

arteries, it may be necessary to fill these structures with a

substance that attenuates X-rays more than bowel loops or

arteries do normally. It is, however, extremely important

that these substances are nontoxic. Barium sulfate, an

insoluble salt, is a nontoxic, relatively high-density agent

that is extremely useful in the examination of the gastro-

intestinal tract. When a barium sulfate suspension is

ingested it attenuates X-rays and can therefore be used to

demonstrate the bowel lumen (Fig. 1.4). It is common to

add air to the barium sulfate suspension, by either ingest-

ing "fizzy" granules or directly instilling air into the body

cavity, as in a barium enema. This is known as a double-

contrast (air/barium) study.

For some patients it is necessary to inject contrast agents

directly into arteries or veins. In this case, iodine-based

molecules are suitable contrast agents. Iodine is chosen

because it has a relatively high atomic mass and so mark-

edly attenuates X-rays, but also, importantly, it is naturally

excreted via the urinary system. Intra-arterial and intrave-

nous contrast agents are extremely safe and are well toler-

ated by most patients. Rarely, some patients have an

anaphylactic reaction to intra-arterial or intravenous

injections, so the necessary precautions must be taken.

Intra-arterial and intravenous contrast agents not only

help in visualizing the arteries and veins but because they

are excreted by the urinary system, can also be used to

visualize the kidneys, ureter, and bladder in a process

known as intravenous urography.

Subtraction angiography

During angiography it is often difficult to appreciate the

contrast agent in the vessels through the overlying bony

structures. To circumvent this, the technique of subtrac-

tion angiography has been developed. Simply, one or

two images are obtained before the injection of contrast

media. These images are inverted (such that a negative is

created from the positive image). After injection of the

contrast media into the vessels, a further series of images

are obtained, demonstrating the passage of the contrast

through the arteries into the veins and around the circula-

tion. By adding the "negative precontrast image" to the

positive postcontrast images, the bones and soft tissues

are subtracted to produce a solitary image of contrast

only. Before the advent of digital imaging this was a

challenge, but now the use of computers has made this

technique relatively straightforward and instantaneous

(Fig. 1.5).

6 Fig. 1.4 Barium sulfate follow-through. Fig. 1.5 Digital subtraction
angiogram.Imaging Diagnostic Imaging Techniques

1

Ultrasound

Ultrasonography of the body is widely used for all aspects

of medicine.

Ultrasound is a very high frequency sound wave

(not electromagnetic radiation) generated by piezoelectric

materials, such that a series of sound waves is produced.

Importantly, the piezoelectric material can also receive the

sound waves that bounce back from the internal organs.

The sound waves are then interpreted by a powerful

computer, and a real-time image is produced on the

display panel.

Developments in ultrasound technology, including the

size of the probes and the frequency range, mean that a

broad range of areas can now be scanned.

Traditionally ultrasound is used for assessing the

abdomen (Fig. 1.6) and the fetus in pregnant women.

Ultrasound is also widely used to assess the eyes, neck, soft

tissues, and peripheral musculoskeletal system. Probes

have been placed on endoscopes, and endoluminal ultra-

sound of the esophagus, stomach, and duodenum is now

routine. Endocavity ultrasound is carried out most com-

monly to assess the genital tract in women using a

transvaginal or transrectal route. In men, transrectal

ultrasound is the imaging method of choice to assess the

prostate in those with suspected prostate hypertrophy or

malignancy.

Doppler ultrasound

Doppler ultrasound enables determination of flow, its

direction, and its velocity within a vessel using simple

ultrasound techniques. Sound waves bounce off moving

structures and are returned. The degree of frequency shift

determines whether the object is moving away from or

toward the probe and the speed at which it is traveling.

Precise measurements of blood flow and blood velocity can

therefore be obtained, which in turn can indicate sites of

blockage in blood vessels.

Computed tomography

Computed tomography (CT) was invented in the 1970s by

Sir Godfrey Hounsfield, who was awarded the Nobel Prize

in Medicine in 1979. Since this inspired invention there

have been many generations of CT scanners.

A CT scanner obtains a series of images of the body

(slices) in the axial plane. The patient lies on a bed, an

X-ray tube passes around the body (Fig. 1.7), and a series

of images are obtained. A computer carries out a complex

mathematical transformation on the multitude of images

to produce the final image (Fig. 1.8).

Magnetic resonance imaging

Nuclear magnetic resonance imaging was first described in

1946 and used to determine the structure of complex

Fig. 1.6 Ultrasound examination of the abdomen. Fig. 1.7 Computed
tomography scanner.

7The Body

molecules. The process of magnetic resonance imaging

(MRI) is dependent on the free protons in the hydrogen

nuclei in molecules of water (H2O). Because water is

present in almost all biological tissues, the hydrogen proton

is ideal. The protons within a patient's hydrogen nuclei can

be regarded as small bar magnets, which are randomly

oriented in space. The patient is placed in a strong magnetic

field, which aligns the bar magnets. When a pulse of radio

waves is passed through the patient the magnets are

deflected, and as they return to their aligned position they

emit small radio pulses. The strength and frequency of the

emitted pulses and the time it takes for the protons to

return to their pre-excited state produce a signal. These

signals are analyzed by a powerful computer, and an image

is created (Fig. 1.9).

By altering the sequence of pulses to which the protons

are subjected, different properties of the protons can be

assessed. These properties are referred to as the "weight-

ing" of the scan. By altering the pulse sequence and the

scanning parameters, T1-weighted images (Fig. 1.10A)

and T2-weighted images (Fig. 1.10B) can be obtained.

These two types of imaging sequences provide differences

in image contrast, which accentuate and optimize different

tissue characteristics.

From the clinical point of view:

Most T1-weighted images show dark fluid and bright

fat---for example, within the brain the cerebrospinal

fluid (CSF) is dark.

T2-weighted images demonstrate a bright signal from

fluid and an intermediate signal from fat---for example,

in the brain the CSF appears white.

MRI can also be used to assess flow within vessels and

to produce complex angiograms of the peripheral and

cerebral circulation.

Diffusion-weighted imaging

Diffusion-weighted imaging provides information on the

degree of Brownian motion of water molecules in various

tissues. There is relatively free diffusion in extracellular

spaces and more restricted diffusion in intracellular

spaces. In tumors and infarcted tissue, there is an increase

in intracellular fluid water molecules compared with

the extracellular fluid environment resulting in overall

increased restricted diffusion, and therefore identification

of abnormal from normal tissue.

8

Nuclear medicine imaging

Nuclear medicine involves imaging using gamma rays,

which are another type of electromagnetic radiation.

Fig. 1.8 Computed tomography scan of the abdomen at vertebral

level L2.

Fig. 1.9 A T2-weighted MR image in the sagittal plane of the

pelvic viscera in a woman.

The important difference between gamma rays and

X-rays is that gamma rays are produced from within the

nucleus of an atom when an unstable nucleus decays,

whereas X-rays are produced by bombarding an atom with

electrons.

For an area to be visualized, the patient must receive a

gamma ray emitter, which must have a number of proper-

ties to be useful, including:

a reasonable half-life (e.g., 6 to 24 hours),

an easily measurable gamma ray, andImaging Nuclear Medicine Imaging

1

A

energy deposition in as low a dose as possible in the

patient's tissues.

The most commonly used radionuclide (radioisotope) is

technetium-99m. This may be injected as a technetium

salt or combined with other complex molecules. For

example, by combining technetium-99m with methylene

diphosphonate (MDP), a radiopharmaceutical is produced.

When injected into the body this radiopharmaceutical

specifically binds to bone, allowing assessment of the

skeleton. Similarly, combining technetium-99m with other

compounds permits assessment of other parts of the body,

for example the urinary tract and cerebral blood flow.

Depending on how the radiopharmaceutical is

absorbed, distributed, metabolized, and excreted by the

body after injection, images are obtained using a gamma

camera (Fig. 1.11).

Positron emission tomography

Positron emission tomography (PET) is an imaging

modality for detecting positron-emitting radionuclides. A

positron is an anti-electron, which is a positively charged

particle of antimatter. Positrons are emitted from the

decay of proton-rich radionuclides. Most of these radionu-

clides are made in a cyclotron and have extremely short

half-lives.

The most commonly used PET radionuclide is fluorode-

oxyglucose (FDG) labeled with fluorine-18 (a positron

B

Fig. 1.10 T1-weighted (A) and T2-weighted (B) MR images of the

brain in the coronal plane.

Fig. 1.11 A gamma camera.

9The Body

emitter). Tissues that are actively metabolizing glucose

take up this compound, and the resulting localized high

concentration of this molecule compared to background

emission is detected as a "hot spot."

PET has become an important imaging modality in the

detection of cancer and the assessment of its treatment

and recurrence.

Single photon emission computed tomography

Single photon emission computed tomography (SPECT)

is an imaging modality for detecting gamma rays

emitted from the decay of injected radionuclides such as

technetium-99m, iodine-123, or iodine-131. The rays are

detected by a 360-degree rotating camera, which allows the

construction of 3D images. SPECT can be used to diagnose

a wide range of disease conditions such as coronary artery

disease and bone fractures.

IMAGE INTERPRETATION

10

Imaging is necessary in most clinical specialties to diagnose

pathological changes to tissues. It is paramount to appreci-

ate what is normal and what is abnormal. An appreciation

of how the image is obtained, what the normal variations

are, and what technical considerations are necessary to

obtain a radiological diagnosis. Without understanding the

anatomy of the region imaged, it is impossible to comment

on the abnormal.

Plain radiography

Plain radiographs are undoubtedly the most common form

of image obtained in a hospital or local practice. Before

interpretation, it is important to know about the imaging

technique and the views obtained as standard.

In most instances (apart from chest radiography) the

X-ray tube is 1 m away from the X-ray film. The object in

question, for example a hand or a foot, is placed upon the

film. When describing subject placement for radiography,

the part closest to the X-ray tube is referred to first and that

closest to the film is referred to second. For example, when

positioning a patient for an anteroposterior (AP) radio-

graph, the more anterior part of the body is closest to the

tube and the posterior part is closest to the film.

When X-rays are viewed on a viewing box, the right side

of the patient is placed to the observer's left; therefore, the

observer views the radiograph as though looking at a

patient in the anatomical position.

Chest radiograph

The chest radiograph is one of the most commonly

requested plain radiographs. An image is taken with the

patient erect and placed posteroanteriorly (PA chest

radiograph; that is, with the patient's back closest to the

X-ray tube.).

Occasionally, when patients are too unwell to stand

erect, films are obtained on the bed in an anteroposterior

(AP) position. These films are less standardized than PA

films, and caution should always be taken when interpret-

ing AP radiographs.

The plain chest radiograph should always be

checked for quality. Film markers should be placed on the

appropriate side. (Occasionally patients have dextrocardia,

which may be misinterpreted if the film marker is placed

inappropriately.) A good-quality chest radiograph will

demonstrate the lungs, cardiomediastinal contour, dia-

phragm, ribs, and peripheral soft tissues.

Abdominal radiograph

Plain abdominal radiographs are obtained in the AP

supine position. From time to time an erect plain abdominal

radiograph is obtained when small bowel obstruction is

suspected.

Gastrointestinal contrast examinations

High-density contrast medium is ingested to opacify the

esophagus, stomach, small bowel, and large bowel. As

described previously (p. 6), the bowel is insufflated with air

(or carbon dioxide) to provide a double-contrast study. In

many countries, endoscopy has superseded upper gastro-

intestinal imaging, but the mainstay of imaging the large

bowel is the double-contrast barium enema. Typically the

patient needs to undergo bowel preparation, in which

powerful cathartics are used to empty the bowel. At the

time of the examination a small tube is placed into the

rectum and a barium suspension is run into the large

bowel. The patient undergoes a series of twists and turns

so that the contrast passes through the entire large bowel.

The contrast is emptied and air is passed through the same

tube to insufflate the large bowel. A thin layer of barium

coats the normal mucosa, allowing mucosal detail to be

visualized (see Fig. 1.4).

Urological contrast studies

Intravenous urography is the standard investigation for

assessing the urinary tract. Intravenous contrast medium

is injected, and images are obtained as the medium is

excreted through the kidneys. A series of films are obtained

during this period from immediately after the injection up

to approximately 20 minutes later, when the bladder is full

of contrast medium.

This series of radiographs demonstrates the kidneys,

ureters, and bladder and enables assessment of the retro-

peritoneum and other structures that may press on the

urinary tract.Computed tomography

Computed tomography is the preferred terminology rather

than computerized tomography, though both terms are

used interchangeably by physicians.

It is important for the student to understand the presen-

tation of images. Most images are acquired in the axial

plane and viewed such that the observer looks from below

and upward toward the head (from the foot of the bed). By

implication:

the right side of the patient is on the left side of the

image, and

the uppermost border of the image is anterior.

Many patients are given oral and intravenous contrast

media to differentiate bowel loops from other abdominal

organs and to assess the vascularity of normal anatomical

structures. When intravenous contrast is given, the earlier

the images are obtained, the greater the likelihood of arte-

rial enhancement. As the time is delayed between injection

and image acquisition, a venous phase and an equilibrium

phase are also obtained.

The great advantage of CT scanning is the ability to

extend and compress the gray scale to visualize the bones,

soft tissues, and visceral organs. Altering the window set-

tings and window centering provides the physician with

specific information about these structures.

Magnetic resonance imaging

There is no doubt that MRI has revolutionized the under-

standing and interpretation of the brain and its coverings.

Furthermore, it has significantly altered the practice of

musculoskeletal medicine and surgery. Images can be

obtained in any plane and in most sequences. Typically the

images are viewed using the same principles as CT. Intrave-

nous contrast agents are also used to further enhance tissue

contrast. Typically, MRI contrast agents contain paramag-

netic substances (e.g., gadolinium and manganese).

Nuclear medicine imaging

Most nuclear medicine images are functional studies.

Images are usually interpreted directly from a computer,

Imaging Safety in Imaging

1

and a series of representative films are obtained for

clinical use.

SAFETY IN IMAGING

Whenever a patient undergoes an X-ray or nuclear medi-

cine investigation, a dose of radiation is given (Table 1.1).

As a general principle it is expected that the dose given is

as low as reasonably possible for a diagnostic image to be

obtained. Numerous laws govern the amount of radiation

exposure that a patient can undergo for a variety of proce-

dures, and these are monitored to prevent any excess or

additional dosage. Whenever a radiograph is booked, the

clinician ordering the procedure must appreciate its neces-

sity and understand the dose given to the patient to ensure

that the benefits significantly outweigh the risks.

Imaging modalities such as ultrasound and MRI are

ideal because they do not impart significant risk to the

patient. Moreover, ultrasound imaging is the modality of

choice for assessing the fetus.

Any imaging device is expensive, and consequently

the more complex the imaging technique (e.g., MRI) the

more expensive the investigation. Investigations must be

carried out judiciously, based on a sound clinical history

and examination, for which an understanding of anatomy

is vital.

Examination

Typical

effective

dose (mSv)

Equivalent duration

of background

exposure

Chest radiograph 0.02 3 days

Abdomen 1.00 6 months

Intravenous urography 2.50 14 months

CT scan of head 2.30 1 year

CT scan of abdomen

10.00 4.5 years

Table 1.1 The approximate dosage of radiation exposure

as an order of magnitude

and pelvis

11The Body

Body systems

SKELETAL SYSTEM

The skeleton can be divided into two subgroups, the axial

skeleton and the appendicular skeleton. The axial skeleton

consists of the bones of the skull (cranium), vertebral

column, ribs, and sternum, whereas the appendicular

skeleton consists of the bones of the upper and lower limbs

(Fig. 1.12).

The skeletal system consists of cartilage and bone.

Cartilage

Cartilage is an avascular form of connective tissue consist-

ing of extracellular fibers embedded in a matrix that con-

tains cells localized in small cavities. The amount and kind

of extracellular fibers in the matrix varies depending on the

type of cartilage. In heavy weightbearing areas or areas

prone to pulling forces, the amount of collagen is greatly

increased and the cartilage is almost inextensible. In con-

trast, in areas where weightbearing demands and stress are

less, cartilage containing elastic fibers and fewer collagen

fibers is common. The functions of cartilage are to:

support soft tissues,

provide a smooth, gliding surface for bone articulations

at joints, and

enable the development and growth of long bones.

There are three types of cartilage:

hyaline---most common; matrix contains a moderate

amount of collagen fibers (e.g., articular surfaces of

bones);

elastic---matrix contains collagen fibers along with a

large number of elastic fibers (e.g., external ear);

fibrocartilage---matrix contains a limited number of

cells and ground substance amidst a substantial amount

of collagen fibers (e.g., intervertebral discs).

Axial skeleton

Appendicular

skeleton

Cartilage is nourished by diffusion and has no blood

vessels, lymphatics, or nerves.

Fig. 1.12 The axial skeleton and the appendicular skeleton.

12Bone

Bone is a calcified, living, connective tissue that forms the

majority of the skeleton. It consists of an intercellular

calcified matrix, which also contains collagen fibers, and

several types of cells within the matrix. Bones function as:

supportive structures for the body,

protectors of vital organs,

reservoirs of calcium and phosphorus,

levers on which muscles act to produce movement, and

containers for blood-producing cells.

There are two types of bone, compact and spongy (tra-

becular or cancellous). Compact bone is dense bone that

forms the outer shell of all bones and surrounds spongy

bone. Spongy bone consists of spicules of bone enclosing

cavities containing blood-forming cells (marrow). Classifi-

cation of bones is by shape.

Long bones are tubular (e.g., humerus in upper limb;

femur in lower limb).

Short bones are cuboidal (e.g., bones of the wrist and

ankle).

Flat bones consist of two compact bone plates separated

by spongy bone (e.g., skull).

Irregular bones are bones with various shapes (e.g.,

bones of the face).

Sesamoid bones are round or oval bones that develop in

tendons.

In the clinic

Accessory and sesamoid bones

These are extra bones that are not usually found as part of

the normal skeleton, but can exist as a normal variant in

many people. They are typically found in multiple

locations in the wrist and hands, ankles and feet (Fig. 1.13).

These should not be mistaken for fractures on imaging.

Sesamoid bones are embedded within tendons, the

largest of which is the patella. There are many other

sesamoids in the body particularly in tendons of the

hands and feet, and most frequently in flexor tendons of

the thumb and big toe.

Degenerative and inflammatory changes of, as well as

mechanical stresses on, the accessory bones and

sesamoids can cause pain, which can be treated with

physiotherapy and targeted steroid injections, but in some

severe cases it may be necessary to surgically remove the

bone.

Body Systems Skeletal System 1

Os trigonum

A

Sesamoid bones

Os naviculare

B

Fig. 1.13 Accessory and sesamoid bones. A. Radiograph of

the ankle region showing an accessory bone (os trigonum).

B. Radiograph of the feet showing numerous sesamoid bones

and an accessory bone (os naviculare).

13The Body

Bones are vascular and are innervated. Generally, an

adjacent artery gives off a nutrient artery, usually one per

bone, that directly enters the internal cavity of the bone

and supplies the marrow, spongy bone, and inner layers of

compact bone. In addition, all bones are covered externally,

except in the area of a joint where articular cartilage is

present, by a fibrous connective tissue membrane called the

periosteum, which has the unique capability of forming new

bone. This membrane receives blood vessels whose branches

supply the outer layers of compact bone. A bone stripped

of its periosteum will not survive. Nerves accompany the

In the clinic

Determination of skeletal age

Throughout life the bones develop in a predictable way to

form the skeletally mature adult at the end of puberty. In

western countries skeletal maturity tends to occur between

the ages of 20 and 25 years. However, this may well vary

according to geography and socioeconomic conditions.

Skeletal maturity will also be determined by genetic factors

and disease states.

Up until the age of skeletal maturity, bony growth and

development follows a typically predictable ordered state,

which can be measured through either ultrasound, plain

radiographs, or MRI scanning. Typically, the nondominant

(left) hand is radiographed, and the radiograph is compared

to a series of standard radiographs. From these images the

bone age can be determined (Fig. 1.14).

In certain disease states, such as malnutrition and

hypothyroidism, bony maturity may be slow. If the skeletal

bone age is significantly reduced from the patient's true age,

treatment may be required.

In the healthy individual the bone age accurately

represents the true age of the patient. This is important in

determining the true age of the subject. This may also have

medicolegal importance.

14

vessels that supply the bone and the periosteum. Most of

the nerves passing into the internal cavity with the nutrient

artery are vasomotor fibers that regulate blood flow. Bone

itself has few sensory nerve fibers. On the other hand, the

periosteum is supplied with numerous sensory nerve fibers

and is very sensitive to any type of injury.

Developmentally, all bones come from mesenchyme by

either intramembranous ossification, in which mesenchy-

mal models of bones undergo ossification, or endochondral

ossification, in which cartilaginous models of bones form

from mesenchyme and undergo ossification.

A B

Carpal bones

C

D

Fig. 1.14 A developmental series of radiographs showing the

progressive ossification of carpal (wrist) bones from 3 (A) to 10

\(D) years of age.In the clinic

Bone marrow transplants

The bone marrow serves an important function. There are

two types of bone marrow, red marrow (otherwise known

as myeloid tissue) and yellow marrow. Red blood cells,

platelets, and most white blood cells arise from within the

red marrow. In the yellow marrow a few white cells are

made; however, this marrow is dominated by large fat

globules (producing its yellow appearance) (Fig. 1.15).

From birth most of the body's marrow is red; however,

as the subject ages, more red marrow is converted into

yellow marrow within the medulla of the long and

flat bones.

Bone marrow contains two types of stem cells.

Hemopoietic stem cells give rise to the white blood cells,

red blood cells, and platelets. Mesenchymal stem cells

differentiate into structures that form bone, cartilage,

and muscle.

There are a number of diseases that may involve the

bone marrow, including infection and malignancy. In patients

who develop a bone marrow malignancy (e.g., leukemia) it

may be possible to harvest nonmalignant cells from the

patient's bone marrow or cells from another person's bone

marrow. The patient's own marrow can be destroyed with

chemotherapy or radiation and the new cells infused. This

treatment is bone marrow transplantation. Body Systems Skeletal System
1

Red marrow in body

of lumbar vertebra

Yellow marrow in femoral head

Fig. 1.15 T1-weighted image in the coronal plane,

demonstrating the relatively high signal intensity returned from

the femoral heads and proximal femoral necks, consistent with

yellow marrow. In this young patient, the vertebral bodies return

an intermediate darker signal that represents red marrow. There

is relatively little fat in these vertebrae; hence the lower signal

return.

15The Body

In the clinic

Bone fractures

Fractures occur in normal bone because of abnormal load or

stress, in which the bone gives way (Fig. 1.16A). Fractures

may also occur in bone that is of poor quality (osteoporosis);

in such cases a normal stress is placed upon a bone that is

not of sufficient quality to withstand this force and

subsequently fractures.

In children whose bones are still developing, fractures

may occur across the growth plate or across the shaft. These

shaft fractures typically involve partial cortical disruption,

similar to breaking a branch of a young tree; hence they are

termed "greenstick" fractures.

After a fracture has occurred, the natural response is to

heal the fracture. Between the fracture margins a blood clot

is formed into which new vessels grow. A jelly-like matrix is

formed, and further migration of collagen-producing cells

occurs. On this soft tissue framework, calcium

hydroxyapatite is produced by osteoblasts and forms

insoluble crystals, and then bone matrix is laid down. As

more bone is produced, a callus can be demonstrated

forming across the fracture site.

Treatment of fractures requires a fracture line reduction. If

this cannot be maintained in a plaster of Paris cast, it may

require internal or external fixation with screws and metal

rods (Fig. 1.16B).

In the clinic

Avascular necrosis

Avascular necrosis is cellular death of bone resulting from a

temporary or permanent loss of blood supply to that bone.

Avascular necrosis may occur in a variety of medical

conditions, some of which have an etiology that is less than

clear. A typical site for avascular necrosis is a fracture across

the femoral neck in an elderly patient. In these patients there

is loss of continuity of the cortical medullary blood flow with

loss of blood flow deep to the retinacular fibers. This

essentially renders the femoral head bloodless; it

subsequently undergoes necrosis and collapses (Fig. 1.17). In

these patients it is necessary to replace the femoral head

with a prosthesis.

16

A

B

Fig. 1.16 Radiograph, lateral view, showing fracture of the ulna

at the elbow joint (A) and repair of this fracture (B) using

internal fixation with a plate and multiple screws.

Wasting of gluteal muscle

Avascular necrosis

Bladder

Normal left hip

Fig. 1.17 Image of the hip joints demonstrating loss of height of

the right femoral head with juxta-articular bony sclerosis and

subchondral cyst formation secondary to avascular necrosis.

There is also significant wasting of the muscles supporting the

hip, which is secondary to disuse and pain.In the clinic

Epiphyseal fractures

As the skeleton develops, there are stages of intense

growth typically around the ages of 7 to 10 years and later

in puberty. These growth spurts are associated with

increased cellular activity around the growth plate

between the head and shaft of a bone. This increase in

activity renders the growth plates more vulnerable to

injuries, which may occur from dislocation across a

growth plate or fracture through a growth plate.

Occasionally an injury may result in growth plate

compression, destroying that region of the growth plate,

which may result in asymmetrical growth across that joint

region. All fractures across the growth plate must be

treated with care and expediency, requiring fracture

reduction.

Joints

The sites where two skeletal elements come together

are termed joints. The two general categories of joints

(Fig. 1.18) are those in which:

the skeletal elements are separated by a cavity (i.e.,

synovial joints), and

there is no cavity and the components are held together

by connective tissue (i.e., solid joints).

Blood vessels that cross over a joint and nerves that

innervate muscles acting on a joint usually contribute

articular branches to that joint.

Synovial joints

Synovial joints are connections between skeletal compo-

nents where the elements involved are separated by a

narrow articular cavity (Fig. 1.19). In addition to contain-

ing an articular cavity, these joints have a number of

characteristic features.

First, a layer of cartilage, usually hyaline cartilage,

covers the articulating surfaces of the skeletal elements. In

other words, bony surfaces do not normally contact one

another directly. As a consequence, when these joints are

viewed in normal radiographs, a wide gap seems to sepa-

rate the adjacent bones because the cartilage that covers

the articulating surfaces is more transparent to X-rays

than bone.

A second characteristic feature of synovial joints is the

presence of a joint capsule consisting of an inner syno-

vial membrane and an outer fibrous membrane.

Body Systems Skeletal System 1

A

Bone Articular cavity Bone

Synovial joint

Bone Connective tissue Bone

B

Solid joint

Fig. 1.18 Joints. A. Synovial joint. B. Solid joint.

The synovial membrane attaches to the margins of the

joint surfaces at the interface between the cartilage and

bone and encloses the articular cavity. The synovial

membrane is highly vascular and produces synovial

fluid, which percolates into the articular cavity and

lubricates the articulating surfaces. Closed sacs of

synovial membrane also occur outside joints, where

they form synovial bursae or tendon sheaths. Bursae

often intervene between structures, such as tendons

and bone, tendons and joints, or skin and bone, and

reduce the friction of one structure moving over the

other. Tendon sheaths surround tendons and also

reduce friction.

The fibrous membrane is formed by dense connective

tissue and surrounds and stabilizes the joint. Parts of

the fibrous membrane may thicken to form ligaments,

which further stabilize the joint. Ligaments outside the

capsule usually provide additional reinforcement.

Another common but not universal feature of synovial

joints is the presence of additional structures within the

area enclosed by the capsule or synovial membrane, such

as articular discs (usually composed of fibrocartilage),

fat pads, and tendons. Articular discs absorb compres-

sion forces, adjust to changes in the contours of joint sur-

faces during movements, and increase the range of

movements that can occur at joints. Fat pads usually occur

between the synovial membrane and the capsule and move

17The Body

Tendon

Sheath

Synovial

membrane

Hyaline cartilage

Joint

capsule

Fibrous

membrane

Fat pad

Articular cavity

Articular

disc

Bone

Bone

Hyaline

cartilage

Bone

Bone

Articular cavity

Bursa

A B

Skin

Fibrous

membrane

Synovial

membrane

Fig. 1.19 Synovial joints. A. Major features of a synovial joint. B.
Accessory structures associated with synovial joints.

into and out of regions as joint contours change during

movement. Redundant regions of the synovial membrane

and fibrous membrane allow for large movements at joints.

Descriptions of synovial joints based on shape

and movement

Synovial joints are described based on shape and

movement:

based on the shape of their articular surfaces, synovial

joints are described as plane (flat), hinge, pivot,

bicondylar (two sets of contact points), condylar (ellip-

soid), saddle, and ball and socket;

based on movement, synovial joints are described as

uniaxial (movement in one plane), biaxial (movement

in two planes), and multiaxial (movement in three

planes).

Hinge joints are uniaxial, whereas ball and socket joints

are multiaxial.

18Body Systems Skeletal System 1

Specific types of synovial joints

(Fig. 1.20)

Plane joints---allow sliding or gliding movements when

one bone moves across the surface of another (e.g.,

acromioclavicular joint)

Hinge joints---allow movement around one axis that

passes transversely through the joint; permit flexion and

extension (e.g., elbow \[humero-ulnar\] joint)

Pivot joints---allow movement around one axis that

passes longitudinally along the shaft of the bone; permit

rotation (e.g., atlanto-axial joint)

Bicondylar joints---allow movement mostly in one axis

with limited rotation around a second axis; formed by

two convex condyles that articulate with concave or flat

surfaces (e.g., knee joint)

Condylar (ellipsoid) joints---allow movement around

two axes that are at right angles to each other; permit

flexion, extension, abduction, adduction, and circum-

duction (limited) (e.g., wrist joint)

Saddle joints---allow movement around two axes that

are at right angles to each other; the articular surfaces

are saddle shaped; permit flexion, extension, abduction,

adduction, and circumduction (e.g., carpometacarpal

joint of the thumb)

Ball and socket joints---allow movement around

multiple axes; permit flexion, extension, abduction,

B

Ulna

adduction, circumduction, and rotation (e.g., hip

joint)

Solid joints

Solid joints are connections between skeletal elements

where the adjacent surfaces are linked together either

by fibrous connective tissue or by cartilage, usually fibro-

cartilage (Fig. 1.21). Movements at these joints are more

restricted than at synovial joints.

Fibrous joints include sutures, gomphoses, and

syndesmoses.

Sutures occur only in the skull where adjacent bones

are linked by a thin layer of connective tissue termed a

sutural ligament.

Gomphoses occur only between the teeth and adjacent

bone. In these joints, short collagen tissue fibers in the

periodontal ligament run between the root of the tooth

and the bony socket.

Syndesmoses are joints in which two adjacent bones

are linked by a ligament. Examples are the ligamentum

flavum, which connects adjacent vertebral laminae,

and an interosseous membrane, which links, for

example, the radius and ulna in the forearm.

Cartilaginous joints include synchondroses and

symphyses.

Humerus

Radius

Synovial membrane

Wrist joint

Articular disc

Radius

Olecranon

A C

Synovial cavity

Ulna

Odontoid process

of axis

Cartilage

Trapezium

Synovial membrane

Atlas

Metacarpal I

Femur

D E

Synovial

membrane

F

Fig. 1.20 Various types of synovial joints. A. Condylar (wrist). B.
Gliding (radio-ulnar). C. Hinge (elbow). D. Ball and socket (hip). E.
Saddle

(carpometacarpal of thumb). F. Pivot (atlanto-axial).

19The Body

**SOLID JOINTS**

**Fibrous Cartilaginous**

**Sutures**

Sutural ligament

Skull

**Synchondrosis**

Head

**Gomphosis**

Cartilage of

growth plate

Tooth

Long bone

Shaft

Periodontal

ligament

Bone

**Symphysis**

**Syndesmosis**

Intervertebral

discs

Radius

Ulna

Interosseous

membrane

Pubic

symphysis

Fig. 1.21 Solid joints.

Synchondroses occur where two ossification centers

in a developing bone remain separated by a layer of

cartilage, for example, the growth plate that occurs

between the head and shaft of developing long bones.

These joints allow bone growth and eventually become

20

completely ossified.

Symphyses occur where two separate bones are inter-

connected by cartilage. Most of these types of joints

occur in the midline and include the pubic symphysis

between the two pelvic bones, and intervertebral discs

between adjacent vertebrae.In the clinic

Degenerative joint disease

Degenerative joint disease is commonly known as

osteoarthritis or osteoarthrosis. The disorder is related to

aging but not caused by aging. Typically there are decreases

in water and proteoglycan content within the cartilage. The

cartilage becomes more fragile and more susceptible to

mechanical disruption (Fig. 1.22). As the cartilage wears, the

underlying bone becomes fissured and also thickens.

Synovial fluid may be forced into small cracks that appear in

the bone's surface, which produces large cysts. Furthermore,

reactive juxta-articular bony nodules are formed

(osteophytes) (Fig. 1.23). As these processes occur, there is

slight deformation, which alters the biomechanical forces

through the joint. This in turn creates abnormal stresses,

which further disrupt the joint.

PatellaCartilage loss

Femoral condyles Cartilage loss

Fig. 1.22 This operative photograph demonstrates the focal

areas of cartilage loss in the patella and femoral condyles

throughout the knee joint.

Body Systems Skeletal System 1

In the United States, osteoarthritis accounts for up to

one-quarter of primary health care visits and is regarded as a

significant problem.

The etiology of osteoarthritis is not clear; however,

osteoarthritis can occur secondary to other joint diseases,

such as rheumatoid arthritis and infection. Overuse of joints

and abnormal strains, such as those experienced by people

who play sports, often cause one to be more susceptible to

chronic joint osteoarthritis.

Various treatments are available, including weight

reduction, proper exercise, anti-inflammatory drug treatment,

and joint replacement (Fig. 1.24).

Osteophytes

Loss of joint space

Fig. 1.23 This radiograph demonstrates the loss of joint space in

the medial compartment and presence of small spiky

osteophytic regions at the medial lateral aspect of the joint.

21The Body

In the clinic---cont'd

Arthroscopy

Arthroscopy is a technique of visualizing the inside of a joint

using a small telescope placed through a tiny incision in the

skin. Arthroscopy can be performed in most joints. However,

it is most commonly performed in the knee, shoulder, ankle,

and hip joints.

Arthroscopy allows the surgeon to view the inside of the

joint and its contents. Notably, in the knee, the menisci and

the ligaments are easily seen, and it is possible using

separate puncture sites and specific instruments to remove

the menisci and replace the cruciate ligaments. The

advantages of arthroscopy are that it is performed through

small incisions, it enables patients to quickly recover and

return to normal activity, and it only requires either a light

anesthetic or regional anesthesia during the procedure.

Fig. 1.24 After knee replacement. This radiograph shows the

position of the prosthesis.

In the clinic

Joint replacement

Joint replacement is undertaken for a variety of reasons.

These predominantly include degenerative joint disease and

joint destruction. Joints that have severely degenerated or

lack their normal function are painful. In some patients, the

pain may be so severe that it prevents them from leaving

the house and undertaking even the smallest of activities

without discomfort.

Large joints are commonly affected, including the hip,

knee, and shoulder. However, with ongoing developments

in joint replacement materials and surgical techniques, even

small joints of the fingers can be replaced.

Typically, both sides of the joint are replaced; in the hip

joint the acetabulum will be reamed, and a plastic or metal

cup will be introduced. The femoral component will be fitted

precisely to the femur and cemented in place (Fig. 1.25).

Most patients derive significant benefit from joint

replacement and continue to lead an active life afterward. In

a minority of patients who have been fitted with a metal

acetabular cup and metal femoral component, an aseptic

lymphocyte-dominated vasculitis-associated lesion (ALVAL)

may develop, possibly caused by a hypersensitivity response

to the release of metal ions in adjacent tissues. These

patients often have chronic pain and might need additional

surgery to replace these joint replacements with safer

models.

Artificial femoral head Acetabulum

Fig. 1.25 This is a radiograph, anteroposterior view, of the

pelvis after a right total hip replacement. There are additional

significant degenerative changes in the left hip joint, which will

also need to be replaced.

22SKIN AND FASCIAS

Skin

The skin is the largest organ of the body. It consists of the

epidermis and the dermis. The epidermis is the outer cel-

lular layer of stratified squamous epithelium, which is

avascular and varies in thickness. The dermis is a dense bed

of vascular connective tissue.

The skin functions as a mechanical and permeability

barrier, and as a sensory and thermoregulatory organ. It

also can initiate primary immune responses.

Fascia

Fascia is connective tissue containing varying amounts of

fat that separate, support, and interconnect organs and

structures, enable movement of one structure relative to

another, and allow the transit of vessels and nerves from

one area to another. There are two general categories of

fascia: superficial and deep.

Superficial (subcutaneous) fascia lies just deep to and is

attached to the dermis of the skin. It is made up of loose

connective tissue usually containing a large amount of

fat. The thickness of the superficial fascia (subcutane-

ous tissue) varies considerably, both from one area of

the body to another and from one individual to another.

The superficial fascia allows movement of the skin over

deeper areas of the body, acts as a conduit for vessels and

nerves coursing to and from the skin, and serves as an

energy (fat) reservoir.

Deep fascia usually consists of dense, organized connec-

tive tissue. The outer layer of deep fascia is attached to

the deep surface of the superficial fascia and forms a

thin fibrous covering over most of the deeper region of

the body. Inward extensions of this fascial layer form

intermuscular septa that compartmentalize groups of

muscles with similar functions and innervations. Other

extensions surround individual muscles and groups of

vessels and nerves, forming an investing fascia. Near

some joints the deep fascia thickens, forming retinacula.

These fascial retinacula hold tendons in place and

prevent them from bowing during movements at the

joints. Finally, there is a layer of deep fascia separating

the membrane lining the abdominal cavity (the parietal

peritoneum) from the fascia covering the deep surface

of the muscles of the abdominal wall (the transversalis

fascia). This layer is referred to as extraperitoneal

fascia. A similar layer of fascia in the thorax is termed

the endothoracic fascia.

Body Systems Muscular System 1

In the clinic

The importance of fascias

A fascia is a thin band of tissue that surrounds muscles,

bones, organs, nerves, and blood vessels and often

remains uninterrupted as a 3D structure between tissues. It

provides important support for tissues and can provide a

boundary between structures.

Clinically, fascias are extremely important because they

often limit the spread of infection and malignant disease.

When infections or malignant diseases cross a fascial

plain, a primary surgical clearance may require a far more

extensive dissection to render the area free of tumor or

infection.

A typical example of the clinical importance of a fascial

layer would be of that covering the psoas muscle.

Infection within an intervertebral body secondary to

tuberculosis can pass laterally into the psoas muscle. Pus

fills the psoas muscle but is limited from further spread by

the psoas fascia, which surrounds the muscle and extends

inferiorly into the groin pointing below the inguinal

ligament.

In the clinic

Placement of skin incisions and scarring

Surgical skin incisions are ideally placed along or parallel

to Langer's lines, which are lines of skin tension that

correspond to the orientation of the dermal collagen

fibers. They tend to run in the same direction as the

underlying muscle fibers and incisions that are made

along these lines tend to heal better with less scarring. In

contrast, incisions made perpendicular to Langer's lines

are more likely to heal with a prominent scar and in some

severe cases can lead to raised, firm, hypertrophic, or

keloid, scars.

MUSCULAR SYSTEM

The muscular system is generally regarded as consisting of

one type of muscle found in the body---skeletal muscle.

However, there are two other types of muscle tissue found

in the body, smooth muscle and cardiac muscle, that are

important components of other systems. These three types

of muscle can be characterized by whether they are con-

trolled voluntarily or involuntarily, whether they appear

striated (striped) or smooth, and whether they are associ-

ated with the body wall (somatic) or with organs and blood

vessels (visceral).

Skeletal muscle forms the majority of the muscle tissue

in the body. It consists of parallel bundles of long,

23The Body

multinucleated fibers with transverse stripes, is capable

of powerful contractions, and is innervated by somatic

and branchial motor nerves. This muscle is used to

move bones and other structures, and provides support

and gives form to the body. Individual skeletal muscles

are often named on the basis of shape (e.g., rhomboid

major muscle), attachments (e.g., sternohyoid muscle),

function (e.g., flexor pollicis longus muscle), position

(e.g., palmar interosseous muscle), or fiber orientation

(e.g., external oblique muscle).

Cardiac muscle is striated muscle found only in the walls

of the heart (myocardium) and in some of the large

vessels close to where they join the heart. It consists of

a branching network of individual cells linked electri-

cally and mechanically to work as a unit. Its contrac-

tions are less powerful than those of skeletal muscle and

it is resistant to fatigue. Cardiac muscle is innervated by

visceral motor nerves.

Smooth muscle (absence of stripes) consists of elongated

or spindle-shaped fibers capable of slow and sustained

contractions. It is found in the walls of blood vessels

(tunica media), associated with hair follicles in the skin,

located in the eyeball, and found in the walls of various

structures associated with the gastrointestinal, respira-

tory, genitourinary, and urogenital systems. Smooth

muscle is innervated by visceral motor nerves.