ANATOMY-1.ppt

Transcript

Chapter 07
*Lecture Outline

*See separate Image PowerPoint slides for
all figures and tables pre-inserted into
PowerPoint without notes.

PowerPoints prepared by
Melanie Waite-Altringer
Biology Faculty Member of
Anoka-Ramsey Community College

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 Chapter 7
Skeletal System

2
Introduction:
A. Bones are very active, living tissues
B. Each bone is made up of several types
of tissues and so is an organ.
C. Bone functions include:
Muscle attachment
Protection and support of soft materials
Blood cell production
Storage of minerals

3
Bone Structure
A. Bones differ in size and shape, yet are similar in
several ways.

B. Classification of Bones
Bones are classified according shape:
Long
Short
Flat
Irregular
Sesamoid

4
C. Parts of a Long Bone
1. Expanded ends of bones that form
joints with adjacent bones are called
epiphyses.
2. Articular cartilages (hyaline cartilage) cover
the epiphyses.
3. The shaft of the bone is the diaphysis.
4. A tough layer of vascular connective tissue,
called the periosteum, covers the bone and is
continuous with ligaments and tendons.

5
5. A bone's shape makes possible its
function; bony processes or grooves
indicate places of attachment for muscles.
6. Compact bone makes up the wall of the
diaphysis; the epiphyses are filled with
spongy bone to reduce the weight of the
skeleton.
7. Spongy bone has many branching bony
plates called trabeculae.
8. The diaphysis contains a hollow medullary
cavity that is lined with endosteum and
filled with marrow.

6
Fig07.01

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Epiphyseal plates

Articular cartilage
Proximal
Spongy bone epiphysis

Space containing
red marrow

Endosteum

Compact bone

Medullary cavity

Yellow marrow

Periosteum Diaphysis

Distal
epiphysis

Femur 7
D. Microscopic Structure
1. Bone cells (osteocytes) are located
within lacunae that lie in
concentric circles around central
(Haversian) canals.
2. Osteocytes pass nutrients and
gasses in the matrix via canaliculi.
3. Extracellular matrix of bone
consists mainly of collagen and inorganic
salts.

8
Fig05.19
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Osteon

Lamella

Central
canal

Lacuna

Canaliculi
©The McGraw-Hill Companies, Inc./Dennis Strete, photographer
(a) (b)

©Prof. P. Motta/Univ."La Sapienza"/Photo Researchers
(c) 9
4. In compact bone, osteocytes and
extracellular matrix layers are organized into
osteons (Haversian systems) that are
cemented together.
5. Central canals contain blood vessels
and nerve fibers, and extend
longitudinally through bone.
6. Central canals are interconnected by
transverse perforating (Volkmann’s)
canals.
7. Unlike compact bone, spongy bone is
made of osteocytes and extracellular
matrix that lie within trabeculae.

10
Fig07.03

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Osteon

t
c
Central canal

ne pa
bo om
containing blood

C
Endosteum vessels and nerves

ne gy
bo pon
Periosteum

S
Nerve

Blood Pores
Central
vessels
canal
Perforating
canal
Compact Nerve
bone
Blood
vessels

Nerve
Trabeculae

Bone matrix

Canaliculus

Osteocyte

Lacuna
(space)
11
Bone Development and Growth
A. Bones form by replacing connective
tissues in the fetus.
B. Some form within sheetlike layers of
connective tissue (intramembranous bones),
while others replace masses of cartilage
(endochondral bones).
C. Intramembranous Bones
1. The broad, flat bones of the
skull form as
intramembranous bones
2. Osteoblasts deposit a bony
matrix around themselves.
12
 3. Once the deposited bony
matrix completely surrounds
the osteoblasts, they are then called
osteocytes.
4. Cells of the membranous tissue
that
lie outside the developing bone
give rise to the periosteum.
5. The formation of bone is
referred to as ossification.

13
D. Endochondral Bones
1. Most of the bones of the skeleton
fall into this category.
2. They first develop as hyaline
cartilage models and are then
replaced with bone.
3. Cartilage is broken down in the
diaphysis and progressively replaced with bone
while the periosteum develops on the
outside.
4. Disintegrating cartilage is invaded
by blood vessels and osteoblasts that first
form spongy bone at the primary
ossification center in the diaphysis. 14
5. Osteoblasts from the
periosteum lay down compact bone
around the primary ossification
center.
6. Secondary ossification centers
appear later in the epiphyses.
7. A band of hyaline cartilage, the
epiphyseal plate, forms between the two
ossification centers.
8. Layers of cartilage cells undergoing
mitosis make up the epiphyseal
plate.
9. Osteoclasts break down the calcified
matrix and are replaced with bone-
building osteoblasts that deposit
bone in place of calcified cartilage.
15
10. Increases in thickness are due to
intramembranous
ossification underneath
the periosteum, while
epiphyseal plates are responsible for
lengthening bones.
11. The medullary cavity forms in
the diaphysis due to the
activity of osteoclasts.

16
Fig07.05

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Articular
Remnants of cartilage
Secondary Epiphyseal
ossification plates
Cartilaginous Developing Compact bone center
model periosteum developing Spongy
bone
Epiphyseal
plates

Blood
Medullary Medullary Medullary
vessel
cavity cavity cavity
Compact
bone
Remnant of
Epiphyseal Epiphyseal
Calcified Primary plate plate
cartilage Ossification Secondary Spongy
center Ossification bone
center
Articular
cartilage
(a) (b) (c) (d) (e) (f)

Major stages (a-d fetal, e child, f adult) in the development of an endochondral bone

18
E. Homeostasis of Bone Tissue
1. Osteoclasts tear down and
osteoblasts build bone throughout
the lifespan with the processes of
resorption and deposition, with
an average of 3% to 5% of bone
calcium exchanged each year.

19
Bone Function
A. Support and Protection
1. Bones give shape to the
head, face, thorax, and limbs.
2. Bones such as the pelvis
and lower limbs provide support for the
body’s weight.
3. Bones of the skull protect the
eyes, ears, and brain.

20
B. Body Movement
1. Bones can act as levers.
a. A lever has four
components: a rigid bar or rod,
a pivot or fulcrum, an
object that is moved against
resistance, and a force that
supplies energy.

21
Fig07.07

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Forearm Mo
vem
movement en
t

Biceps brachii
contracting muscle

Force Radius

Relaxed
(a) muscle
Fulcrum
Resistance

Relaxed
muscle
Triceps brachii Ulna
contracting muscle

nt
eme
Force

Fulcrum Mov Resistance

(b) 22
C. Blood Cell Formation
1. Blood cells begin to form
through hematopoieses in
the yolk sac; they are later
manufactured in the liver and
spleen and then finally formed in the
bone marrow.

23
2. Two kinds of marrow occupy
the medullary cavities and
the larger central canals of bone.
a. Red marrow occupies
the spongy bone of the
skull, ribs, sternum, clavicles,
vertebrae, and pelvis in adults. It
function in the formation of red
blood cells, white blood cells,
and platelets. Its color comes
from the O2 carrying
pigment hemoglobin.
b. Yellow marrow stores fat
and occupies most cavities of
bone in adults.
24
D. Storage of Inorganic Salts
1. The extracellular matrix of bone
is rich in calcium salts mainly in
the form of calcium phosphate that is
important in many metabolic
processes.
2. Calcium in bone is a reservoir for
body calcium; when blood levels
are low, osteoclasts release calcium
from bone under the influence of the
parathyroid hormone.

25
 3. Calcium is stored in bone
under the influence of calcitonin
when blood levels of calcium are
high.
4. Bone also stores magnesium,
sodium, potassium, and
carbonate ions.
5. Bones can also accumulate
harmful metallic elements, such
as lead, radium, and strontium.

26
Fig07.08
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Control center
Thyroid gland
releases calcitonin.

Receptors Effectors
Cells in the thyroid Osteoblasts deposit
gland sense the calcium in bones.
increase in blood
calcium.

Stimulus Response
Blood calcium Blood calcium
level increases. level is returned
toward normal.

too high

Normal blood
calcium level

too low

Stimulus Response
Blood calcium Blood calcium
level decreases. level is returned
to normal.

Receptors Effectors
Cells in the parathyroid Osteoclasts break
gland sense the down bone to release
decrease in blood calcium.
calcium.

Control center
Parathyroid glands
release parathyroid
hormone. 27
Skeletal Organization
A. The axial skeleton consists of the
bony and cartilaginous parts that support the
and protect the head, neck and trunk.
(Skull, hyoid bone, vertebral column, &
thoracic cage)
B. The appendicular skeleton consists
of the bones of the upper and lower
limbs and the bones that anchor the limbs to the
axial skeleton. (pectoral girdle, upper
limbs, pelvic girdle, & lower limbs)

29
Fig07.09
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Cranium

Skull

Face
Hyoid

Clavicle
Scapula

Sternum
Humerus

Ribs
Vertebral Vertebral
column column
Hip bone
Carpals Radius Sacrum
Ulna Coccyx

Femur
Metacarpals Phalanges

Patella

Tibia

Fibula

Tarsals
Metatarsals
Phalanges

(a) (b) 30
Skull

A. The skull is made up of 22 bones: 8 cranial bones,
13 facial bones, and the mandible.
B. The Cranium encloses and protects the
brain, provides attachments for muscles, and
contains air-filled paranasal sinuses that reduce its
weight and increase vocal resonance.
1. The frontal bone features include the
supraorbital foramen and the frontal
sinuses.

31
Fig07.10

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Parietal bone

Frontal bone
Coronal suture

Lacrimal bone

Ethmoid bone

Squamous suture
Supraorbital foramen
Sphenoid bone
Temporal bone Nasal bone
Sphenoid bone
Perpendicular plate
of the ethmoid bone Middle nasal concha
of the ethmoid bone
Infraorbital foramen
Zygomatic bone
Inferior nasal concha
Vomer bone

Maxilla
Mandible

Mental foramen

32
Fig07.11

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Frontal sinus

Ethmoidal sinuses

Sphenoidal sinus

Maxillary sinus

33
2. Parietal bones lie at the sides of
the skull, just behind the frontal
bone. They join along the midline sagittal
suture and meet the frontal bone along the
coronal suture.
3. The occipital bone forms the
back of the skull and the base of the
cranium. Features include the lambdoid
suture, foramen magnum, and occipital
condyles.

34
4. The temporal bones
form parts of the sides and base of
the cranium. Features include the
squamous suture, external auditory
meatus, mandibular fossae, mastoid
process, styloid process, and
zygomatic process.
5. The sphenoid bone
helps form the base of the cranium,
sides of the skull and portions of
the orbits. Features include the sella
turcica and sphenoidal sinuses.
35
 6. The ethmoid bone is located in front
of the spenoid bone. Features include
the cribriform plates, crista galli, a
perpendicular plate, superior and
middle nasal conchae, and
ethmoidal sinuses.

36
C. Facial Skeleton has 13 immovable bones and
a movable lower jawbone which forms the
basic shape of the face and provide
attachments for muscles that move the jaw
and control facial expressions.
1. The maxillae form the upper
jaw, hard palate, floor of
the orbits, sides of the nasal
cavity, house the upper teeth, and
contain large maxillary
sinuses. Features include the hard
palate, maxillary sinuses, palatine and
alveolar processes, and alveolar arch.
37
2. Palatine bones are L-shaped bones
located behind the maxillae that form the
floor & lateral walls of the nasal cavity and
the posterior portion of the hard palate.
3. Zygomatic bones form the cheekbones
and lateral walls of the orbits. Features
include the temporal and zygomatic
processes, which form the zygomatic
arch.
4. The lacrimal bones form part of the
medial walls of the orbits.
5. Nasal bones form the bridge of the nose.

38
 6. The vomer bone makes up
a portion of the nasal septum.
7. Inferior nasal conchae are
fragile, scroll-shaped bones
that support mucous
membranes in the nasal cavity.
8. The mandible, or lower
jawbone, supports the lower
teeth and includes the mandibular
condyle, coronoid process,
and alveolar arch.

39
Fig07.12

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Coronal suture
Parietal bone
Frontal bone

Squamous suture
Sphenoid bone

Lambdoid suture Ethmoid bone

Occipital bone Lacrimal bone
Nasal bone
Temporal bone
Zygomatic bone

External acoustic meatus Temporal process of
zygomatic bone

Mastoid process Maxilla
Mandibular condyle

Styloid process
Mental foramen
Zygomatic process
of temporal bone Mandible
Coronoid process

40
Fig07.13

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Palatine process of maxilla
Zygomatic bone
Frontal bone
Palatine bone
Sphenoid bone
Zygomatic arch

Vomer bone

Mandibular fossa

Styloid process
External acoustic meatus

Occipital condyle
Foramen magnum

Lambdoid suture
Temporal bone

Occipital bone

41
Fig07.14

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Crista galli
Ethmoid
Cribriform plate bone

Frontal bone

Sphenoid bone

Sella turcica

Temporal bone

Parietal bone

Foramen magnum

Occipital bone

42
Fig07.15

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Coronal suture

Temporal bone

Parietal bone
Frontal bone

Squamous suture
Sphenoid bone

Frontal sinus Lambdoid suture

Nasal bone Occipital bone

Crista galli
Internal acoustic meatus
Cribriform plate
Ethmoid
bone Perpendicular plate
(nasal septum)
Sella turcica
Inferior nasal concha
Palatine process
of maxilla
Styloid process Foramen magnum

Maxilla Sphenoidal sinus Mastoid process

Palatine bone

Vomer bone

Mandible Alveolar processes

43
D. Infantile Skulls are not completely
developed and have fontanels (soft spots) that
are membranous areas of incomplete
intramembranous ossification.

44
Fig07.16

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Anterior fontanel

Coronal suture

Frontal bone
Parietal bone

Nasal bone

Posterior fontanel

Occipital bone
Zygomatic bone
Maxilla
Mastoid fontanel
(posterolateral Sphenoid bone
fontanel)
Mandible
Temporal bone
Sphenoid fontanel
(a) (anterolateral fontanel)
Frontal suture
(metopic suture)
Frontal bone

Anterior fontanel

Sagittal suture

Posterior fontanel

(b)
45
Vertebral Column
A. The vertebral column is composed of bony
vertebrae separated by fibrocartilagenous
intervertebral discs, connected together by
ligaments and extends from the skull to the pelvis. It
supports the head and trunk and protects the spinal cord
that passes through its vertebral canal.
B. A typical vertebrae consists of a body, pedicles,
laminae, spinous process, vertebral foramen, transverse
process, superior and inferior processes and a
intervertebral foramina.

47
Fig07.17

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Cervical Cervical
curvature vertebrae

Spinous
process

Rib facet

Thoracic
Thoracic vertebrae
curvature

Intervertebral
discs

Intervertebral
foramina Lumbar
Lumbar vertebrae
curvature

Sacrum

Sacral
curvature

Coccyx
48
C. Cervical Vertebrae
1. These seven bones are the smallest
of the vertebrae that
comprise the neck and support the
head and have distinctive
transverse foramina.
2. The first vertebra is the atlas,
supports the head. It has two
facets that articulate with the occipital
condyles.
3. The second vertebra is the axis,
with its, tooth-like dens that pivots
within the atlas.
4. Features that separate cervical 49
D.Thoracic Vertebrae
1. Twelve thoracic vertebrae
articulate with the ribs and are
larger and stronger than the
cervical vertebrae.
E. Lumbar Vertebrae
1. The five massive lumbar
vertebrae support the weight of
the body and are located in the
small of the back.

50
Fig07.18
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Bifid spinous process

Vertebral foramen
Lamina
Superior articular
facet
Transverse foramen
Body
Transverse process
(a) Cervical vertebra

Spinous process

Lamina Transverse process

Facet that articulates
with rib tubercule
Superior articular
facet
Pedicle Vertebral foramen
Facet that articulates
Body with rib head

(b) Thoracic vertebra

Spinous process
Lamina
Superior articular
process

Transverse process
Pedicle
Vertebral foramen

Body

(c) Lumbar vertebra 51
Fig07.19

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Posterior Facet that articulates
with occipital condyle Vertebral
foramen

Transverse
process

Facet that articulates Transverse
Anterior with dens (odontoid process) foramen
of axis Atlas
(a)

Anterior articular
facet for atlas
Dens Spinous process
Spinous
process Superior
articular facet

Transverse
foramen

Body
Inferior articular
process Transverse
process
Dens (odontoid
Axis
(b) (c) process) 52
F. Sacrum
1. The sacrum is a triangular
structure at the base of the vertebral
column made up of five vertebrae fused
together into one bone.
2. Features include a ridge of
tubercles, posterior sacral foramina,
sacral canal, sacral hiatus and four
pairs of anterior sacral foramina.
E. Coccyx
1. The coccyx is the lowest
part of the vertebral column and
is typically composed of four 53
fused vertebrae
Fig07.20

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Sacral promontory Superior articular process Sacral canal

Auricular
surface

Sacrum Tubercle
of median
sacral crest

Posterior sacral
foramen

Sacral hiatus

Anterior sacral
foramen
Coccyx

(a) (b)

54
Thoracic Cage
A. The thoracic cage includes the ribs, thoracic
vertebrae, sternum, and costal cartilages.
B. It supports the pectoral girdle and upper
limbs, protects the viscera in the thoracic and
abdominal cavities and plays a role in
breathing.

55
C. Ribs normally humans have 12 pairs that
attach to the thoracic vertebrae.
1. The first seven pairs of
ribs are true (or vertebrosternal) ribs that
join the sternum directly by their
costal cartilages.
2. The remaining five pairs
are false ribs because that do not reach the
sternum directly. The first
three pairs join the cartilages of the
seventh rib, and the last two pairs are
floating ribs, because they have no
cartilaginous rib attachments.
56
 3. Features of a typical rib
include a shaft, head, and tubercle.
a. The head articulates
with the vertebra facet and the
tubercle articulates with the transverse
process of the vertebrae.

D. Sternum (breastbone) is located along the
anterior midline of the thoracic cage.
1. Its features include an
upper manubrium, middle body, and
lower xiphoid process.
57
Fig07.21

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

1
Thoracic vertebra
2 Clavicular notch

Manubrium
3

Trueribs 4
(vertebrosternal
ribs) 5 Sternum
Body

6

7
Xiphoid process

8
Ribs
Vertebrochondral 9
False ribs Costal
ribs cartilage
10
11
12
Floating ribs
(vertebralribs)
58
Pectoral Girdle
A. The pectoral girdle makes an incomplete ring that
supports the upper limbs and is composed of
two scapulae and two clavicles.
B. The clavicles are elongated S-shaped bones
located at the base of the neck that function to
brace the scapulae.

59
Fig07.22
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Acromion Acromial end
Clavicle
process Sternal end

Head of
humerus
Acromion
process

Head of
Coracoid
humerus
rocess
Coracoid
process

Sternum

Humerus

Rib
Costal
Scapula Rib cartilage

Humerus

Courtesy Eastman Kodak

Ulna
Radius

60
C. The scapulae (shoulder blades) are broad,
triangular bones on either side of the upper back.
1. A spine divides the posterior
scapula into unequal portions.
2. The spine has two processes, an
acromion process (articulates with
clavicle) and a coracoid process
(provides attachments for limb and chest
muscles).
3. The glenoid cavity articulates with
the head of the humerus.

61
Fig07.23

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Superior
border
Coracoid
process
Suprascapular
Acromion
notch
process
Acromion Coracoid
process process
Spine
Glenoid
Glenoid cavity
cavity
Supraspinous Latera
fossa (axillaryl
border)
Infraspinous
fossa
Medial
(vertebral
border)

(a) (b) (c)

62
Upper Limb
A. Bones of the upper limb form the
framework for the arm, forearm, and hand.
They also provide for muscle attachments
and they function in levers to move limb parts.

63
 B. The humerus is a long bone
extending from the scapula to the elbow.
1. It articulates with the
scapulae at its head, with the radius at the
capitulum, and with the ulna at the
trochlea.
2. Other features include the
greater and lesser tubercles,
intertubercular groove, anatomical and
surgical necks, deltoid tuberosity, two
condyles (capitulum & trochanter)
epicondyles, coronoid fossa, and olecranon fossa.

64
Fig07.24

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Greater tubercle Head Greater tubercle

Anatomical
Intertubercular
neck
groove
Surgical
Lesser tubercle neck

Deltoid tuberosity

Coronoid Olecranon
fossa fossa
Lateral
Lateral epicondyle
Medial
epicondyle
epicondyle
Capitulum
Trochlea

(a) (b) 65
C. The radius is located on the
thumb side of the forearm, extending from
the elbow to the wrist.
1. The flattened head of
the radius pivots with the
humerus.
2. Other features of the
radius include the radial tuberosity
and styloid process.

66
D. The ulna is the longer of the two bones
making up the forearm and has
a trochlear notch that articulates with the
humerus.
1. Other features include the
olecranon process, coronoid
process, head, and styloid process.

67
Fig07.25

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Trochlear notch Olecranon
process
Coronoid process

Head of radius
Olecranon
process
Radial tuberosity Trochlear
notch

Coronoid
process
Radial
notch

Radius

(b)

Ulna

Head of ulna

Styloid process
Styloid process Ulnar notch of radius
(a)
68
E. The hand is made up of the wrist,
palm, and
fingers.
1. The wrist of the hand is made up of
eight carpal bones bound into a
carpus.
2. The framework of the hand is made
up of five metacarpal bones.
3. The fingers are composed of three
phalanges in each finger except the
thumb, which lacks the middle
phalanx.

69
Fig07.26
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Radius
Scaphoid Ulna Scaphoid
Lunate
Capitate Capitate
Hamate
Trapezoid Trapezoid
Triquetrum
Trapezium Trapezium
Pisiform

Carpals
(carpus)

1 1

Metacarpals 5 5
2 4 2
(metacarpus) 3 4 3

Proximal
phalanx

Middle
Phalanges phalanx
Distal
phalanx

70
(a) (b)
Pelvic Girdle
A. The pelvic girdle consists of
the two hip (innominate) bones; it
supports the trunk of the body on the lower
limbs, provides attachments for the
lower limbs and protect the organs within
it.
B. The pelvis is the sacrum,
coccyx and pelvic girdle al together.

71
Fig07.27

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Hip bones

Sacrum

Pubic symphysis

Obturator foramen

Femur

©Martin Rotker
(b)

(a)

72
C. Each hip bone is made up of three bones: ilium,
ischium, and pubis. These bones
are fused in the region of the acetabulum, the
cuplike depression that articulates with
the head of the femur.
D. The ilium is the largest and upper-most
portion of the hip bone. Features
include the iliac crest, sacroiliac joint, and
the anterior superior iliac spine

73
E. The ischium forms the L-shaped portion
that supports weight during
sitting. Features include the
ischial tuberosity and ischial spine.
F. The pubis constitutes the anterior portion
of the hip bones and join at the
pubic symphysis. Additional
features include the pubic arch, obturator
foramen, and pubic brim.
G. Refer to Table 7.3 for differences between
the female and male skeletons

74
Fig07.28

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Iliac crest

Iliac fossa
Iliac crest
Anterior
superior
iliac spine Posterior Ilium
Ilium superior
Anterior iliac spine
inferior
iliac spine Posterior
Inferior
iliac spine
Obturator
foramen Acetabulum
Greater
sciatic notch
Obturator
Ischium Ischial spine foramen
Pubis
Ischium
Lesser
sciatic notch Pubis

Ischial
tuberosity

(a) (b)

75
Fig07.29

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Flared ilium

Sacral promontory

Pelvic brim

Pubic symphysis

(a) Pubic arch

Sacral promontory

Sacral curvature

(b) Pubic arch
76
Lower Limb
A. The bones of the lower limb provide the
framework for the thigh, lower
leg, and foot.
B. The femur, or thighbone, extends from the
hip to the knee and is the longest bone in
the body.
1. Its head joins with the
acetabulum; it also joins with the tibia at
the medial and lateral condyles.

77
 3. Other features of the
femur include the fovea capitis, neck,
and greater and lesser trochanters.
C. The patella (kneecap) is located in the tendon
that passes over the knee.

78
Fig07.30
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Fovea capitis

Neck Head

Greater
trochanter Gluteal
tuberosity

Lesser
trochanter

Linea
aspera

Lateral Medial
epicondyle epicondyle
Medial Lateral
condyle condyle

Intercondylar
fossa
Patellar
(a) surface (b)
79
 D. The tibia (shinbone) supports the weight of
the body and articulates with the femur (medial
and lateral condyles) and with the tarsal bones
of the foot.
1. Its anterior tibial tuberosity is the
point of attachment for the patellar
ligament.
2. Other features include the
medial malleolus (inner ankle).

80
 E. The fibula is a slender bone lying lateral to
the tibia; it does not bear body
weight.
1. Features include the
head and a distal lateral malleolus
(outer ankle).

81
Fig07.31

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Intercondylar
eminence
Lateral Medial
condyle condyle
Tibial
Head of
tuberosity
fibula

Anterior
crest

Fibula
Tibia

Medial
malleolus
Lateral
malleolus
82
F. The foot is made up of the ankle, the instep
and the toes.
1. The ankle (tarsus) is
composed of seven tarsal bones.
a. The talus articulates
with the tibia and fibula.
b. The calcaneus (heel
bone) supports the body weight.

83
 2. The instep (metatarsus) of
the foot consists of five
metatarsal bones and provides an
arch.
3. Each toe is made up of
three phalanges, with
the exception of the great toe,
which lacks a middle phalanx.

84
Fig07.32

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Fibula
Tibia

Talus
Medial
Navicular
Metatarsals cuneiform
(metatarsus)
Calcaneus
Phalanges

Tarsals
(tarsus)

85
Fig07.33
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Calcaneus

Talus Tarsals
(tarsus)
Navicular
Cuboid
Lateral cuneiform
Intermediate cuneiform
Medial cuneiform

5
4
3 Metatarsals
2 1
(metatarsus)
Proximal phalanx

Middle phalanx

Distal phalanx Phalanges

86
Joints
A. Joints (articulations) are the functional
junctions between bones.
B. Joints enable a wide variety of body
movements.
C. Joints can be classified according to the
degree of movement possible
and can be immovable, slightly movable, or
freely movable.
D. Joints can also classified according to the
type of tissue that binds them together.
(more commonly used today)
87
E. Fibrous joints are held close together by
dense connective tissue and are immovable
(sutures of skull) or only slightly movable
(joint between the distal tibia and fibula).

88
Fig07.34

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(a)

Connective tissue

(b)
89
F. Cartilaginous Joints are connected by either
hyaline or fibrocartilage.
1. Intervertebral disks
between vertebrae
help absorb shock and are
slightly movable.
2. Other examples of
cartilaginous joints include
the pubic symphysis and the
first rib with the sternum.

90
G. Synovial Joints
1. Most joints of the
skeleton are synovial joints,
which are more complex than
fibrous or
cartilaginous joints.
2. The articular ends of
bone in a synovial joint
are covered with hyaline
cartilage.

91
Fig07.35
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Spongy
bone

Joint
capsule

Joint cavity Articular
filled with cartilage
synovial
fluid Synovial
membrane

92
3. A joint capsule consists of an
outer layer of dense connective tissue
that joins the periosteum, and an
inner layer made up of synovial
membrane.
a. Synovial fluid has the
consistency of egg whites enabling it to lubricate
joints.
4. Some synovial joints contain
shock absorbing pads of fibrocartilage
called menisci.
5. Some synovial joints have fluid-
filled sacs called bursae.

93
Fig07.36

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Femur
Synovial membrane

Suprapatellar bursa

Patella

Prepatellar bursa

Subpatellar fat
Articular cartilage

Menisci

Infrapatellar bursa

Tibia

94
6. Based on the shapes of their
parts and the movements they
permit, synovial joints can be classified
as follows:
a. A ball-and-socket joint consists
of a bone with a globular or
egg- shaped head articulating with
the cup-shaped cavity of
another bone; a very wide
range of motion is possible; examples
include the shoulder and hip
joints.
95
b. A condylar joint consists of an
ovoid condyle fitting into an
elliptical cavity, permitting a variety of
motions; an example is the joint
between a metacarpal and a phalange.
c. Plane joints or Gliding joints
occur where articulating surfaces are
nearly flat or slightly curved, allowing a back-
and-forth motion; the joints of
the wrist and ankle, as well as
those between vertebrae, are
gliding joints.

96
 d. In a hinge joint, a
convex surface fits into a concave
surface, as is found in the elbow
and phalange joints; movement
is in one plane only.
e. In a pivot joint, a
cylindrical surface
rotates within a ring of bone and
fibrous tissue; examples
include the joint between the
proximal ends of the radius and
ulna.
97
 f. A saddle joint
forms where articulating
surfaces have both concave
and convex areas,
permitting a wide range of
movements; the joint between
the trapezium and the
metacarpal of the thumb is of
this type.

98
Fig07.37

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display

Hip bone

Head of femur Metacarpal
in acetabulum

Femur

Phalanx

(a) Ball-and-socket joint (b) Condylar joint

Humerus

Radius

Carpals

Ulna
(c) Plane joint (d) Hinge joint

Dens
Transverse
ligament First
metacarpal
Atlas
Axis Trapezium

(e) Pivot joint (f) Saddle joint
99
H. Types of Joint Movements
1. When a muscle contracts, its fibers
pull its movable end (insertion) toward its
stationary end (origin), causing movement at a joint.
2. These terms describe movements that
occur at joints: flexion, extension, dorsiflexion,
plantar flexion, hyperextension, abduction, adduction,
rotation, circumduction, pronation, supination,
eversion, inversion, retraction, protraction, elevation,
and depression.

100
Fig07.38

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Hyperextension
Hyperextension

Extension
E n

Flexionn

Flexion

Abduction
Extension

Adduction Dorsiflexion

Plantar flexion

©The McGraw-Hill Companies, Inc./Womack Photography, Ltd.; Plates 8-11: ©McGraw-Hill Higher Education, Inc./Jim Womack

101
Fig07.39

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Circumduction

Supination

Medial Pronation
Lateral
rotation rotation

102
©The McGraw-Hill Companies, Inc./Womack Photography, Ltd.; Plates 8-11: ©McGraw-Hill Higher Education, Inc./Jim Womack
Fig07.40

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display

Inversion Eversion

Protraction Retraction

Elevation

Depression

103
©The McGraw-Hill Companies, Inc./Womack Photography, Ltd.; Plates 8-11: ©McGraw-Hill Higher Education, Inc./Jim Womack