Skeletal System: Bones and Joints PDF

Summary

This document is a chapter about the skeletal system, describing bones, tendons, ligaments, and cartilages, and their roles in support, protection, movement, storage, and blood cell production. It includes the components of the extracellular matrix in bone, cartilage, tendons, and ligaments. It describes long, short, flat, and irregular bone shapes, and details the structure of long bones such as the diaphysis, epiphysis, articular cartilage, epiphyseal plates, medullary cavity, periosteum, and endosteum. It explores bone marrow, including red and yellow marrow and location in bone structure. Lastly, it covers the bone cells (osteoblasts, osteocytes, and osteoclasts) and bone tissue (compact bone, spongy bone) in the body.

Full Transcript

Seeley’s
ESSENTIALS OF
Anatomy &
Physiology
Tenth Edition

Cinnamon Vanputte
Jennifer Regan
Andrew Russo

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

© 2019 McGraw-Hill Education. All rights reserved. Authorized only for instructor use in the classroom. No reproduction or further distribution permitted without the prior
 2

Chapter 6

Skeletal
System:Bones and
Joints
Lecture Outline
© 2019 McGraw-Hill Education
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Components of Skeletal System
 Bones
 Tendons
 Ligaments
 Cartilages

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Bones of the Skeletal System

Figure
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6.11
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Skeletal System Functions
 Support
 Protect
 Movement
 Storage
 Blood cell production

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Extracellular Matrix 1

 Bone, cartilage, tendons, and ligaments of
the skeletal system are all connective
tissues.
 Their characteristics are largely
determined by the composition of their
extracellular matrix.
 The matrix always contains collagen,
ground substance, and other organic
molecules, as well as water and
minerals.
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Extracellular Matrix 2

Collagen
 is a tough, ropelike protein.
Proteoglycans
 are large molecules consisting of many
polysaccharides attaching to and
encircling core proteins.
 form large aggregates and attract water.

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Extracellular Matrix 2

Tendons and Ligaments
 Their extracellular matrix contains
large amounts of collagen fibers,
making these structures very tough,
like ropes or cables.

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Cartilage Extracellular Matrix
 contains collagen and
proteoglycans.
 Collagen makes cartilage tough,
whereas the water-filled
proteoglycans make it smooth and
resilient.
 As a result, cartilage is relatively
rigid, but it springs back to its
original shape after being bent or
slightly compressed.
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Bone Extracellular Matrix
 contains collagen and minerals,
including calcium and phosphate.
 The ropelike collagen fibers lend
flexible strength to the bone.
 The mineral component gives bone
compression (weight-bearing)
strength.
 Most of the mineral in bone is in the
form of calcium phosphate crystals
called hydroxyapatite.
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Shape Classification of Bones 1

There are four bone shape
classifications: long, short, flat, and
irregular.
Long bones are longer than they are
wide; examples are upper and lower
limb bones.
Short bones are approximately as wide
as they are long; examples are the
bones of the wrist and ankle.
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Shape Classification of Bones 2

Flat bones have a relatively thin,
flattened shape; examples are bones of
the skull and sternum.
Irregular bones include the vertebrae
and facial bones, which have shapes
that do not fit readily into the other
three categories.

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Long Bone Structures 1

Diaphysis
 Shaft
 compact bone
tissue (on
outside)
Epiphysis
 ends spongy
bone tissue
Figure
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6.2a
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Long Bone Structures 1

Articular cartilage
 covers
epiphyses
 reduces friction

Figure
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Long Bone Structures 2

Epiphyseal
plate:
site of growth
between
diaphysis and
epiphysis
Medullary
cavity:
center of
diaphysis red
or yellow Figure
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Long Bone Structures 3

Periosteum
 membrane
around
bone’s
outer
surface
Endosteum:
 membrane
that lines
Figure
medullary
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Structure of Long Bone

Figure
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Bone Marrow 1

Bones contain cavities, such as the
large medullary cavity in the diaphysis,
as well as smaller cavities in the
epiphyses of long bones and in the
interior of other bones.
These spaces are filled with soft tissue
called marrow.
Red marrow is the location of blood
forming cells.
Yellow marrow is mostly fat.
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Bone Marrow 2

In newborns most bones have blood
making red bone marrow.
In adults red marrow in the diaphysis is
replaced by yellow bone marrow.
In adults most red bone marrow is in
the flat bones and the long bones of
the femur and humerus.

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Structure of Bone Tissue

Figure
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6.3
(a) ©Trent Stephens
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Bone Cells
Osteoblasts: responsible for the
formation of bone and the repair and
remodeling of bone.
Osteocytes: cells that maintain bone
matrix and form from osteoblast after
bone matrix has surrounded it.
Osteoclasts: contribute to bone
repair and remodeling by removing
existing bone, called bone
reabsorption.
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Compact Bone Tissue 1

Location:
outer part of
diaphysis (long
bones)
and thinner surfaces
of other bones
Osteon:
structural unit of
compact bone
includes lamella,
lacunae,
canaliculus,
central canal,
osteocytes Figure
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Compact Bone Tissue 2

Lacunae:
spaces between
lamella
Canaliculus:
tiny canals
transport nutrients
and remove
waste
Central canal:
center of osteon
Figure
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Spongy (Cancellous) Bone Tissue
Spongy bone
It is located at the epiphyses of long
bones and center of other bones.
It has trabeculae(beams), which
are interconnecting rods, and spaces
that contain marrow.
It has no osteons.

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Spongy Bone Tissue

Figure
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Bone Formation
Ossification is the formation of bone by
osteoblasts.
Bone formation that occurs within
connective tissue membranes is called
intramembranous ossification.
Bone formation that occurs inside
hyaline cartilage is called
endochondral ossification.
Both types of bone formation result in
compact and spongy bone.
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Intramembranous Ossification 1

Intramembranous ossification occurs
when osteoblasts begin to produce
bone within connective tissue.
This occurs primarily in the bones of
the skull.
Osteoblasts line up on the surface of
connective tissue fibers and begin
depositing bone matrix to form
trabeculae.
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Intramembranous Ossification 2

The process begins in areas called
ossification centers and the
trabeculae radiate out from the centers.
Usually, two or more ossification
centers exist in each flat skull bone and
mature skull bones result from fusion of
these centers as they enlarge.
The trabeculae are constantly
remodeled and they may enlarge or be
replaced by compact bone.
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Bone Formation in the Fetus

Figure
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(b) ©Biophoto Associates/Science Source
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Endochondral Ossification
Endochondral bone formation is bone
formation within a cartilage model.
The cartilage model is replaced by
bone.
Initially formed is a primary
ossification center, which is bone
formation in the diaphysis of a long
bone.
A secondary ossification center is
bone formation in the epiphysis.
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Steps in Endochondral Ossification
1. Chondroblasts build a cartilage
model, the chondroblasts become
chondrocytes.
2. Cartilage model calcifies (hardens).
3. Osteoblasts invade calcified cartilage
and a primary ossification center
forms diaphysis.
4. Secondary ossification centers form
epiphysis.
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Bone

Figure
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6.6
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Bone Growth in Width
Bone growth occurs by the deposition
of new bone lamellae onto existing
bone or other connective tissue.
As osteoblasts deposit new bone
matrix on the surface of bones
between the periosteum and the
existing bone matrix, the bone
increases in width, or diameter.
This process is called appositional
growth.
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Bone Growth in Length 1

Growth in the length of a bone, which
is the major source of increased height
in an individual, occurs in the
epiphyseal plate.
This type of bone growth occurs
through endochondral ossification.
Chondrocytes increase in number on
the epiphyseal side of the epiphyseal
plate.
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Bone Growth in Length 2

Then the chondrocytes enlarge and
die.
The cartilage matrix becomes calcified.
Much of the cartilage that forms
around the enlarged cells is removed
by osteoclasts, and the dying
chondrocytes are replaced by
osteoblasts.

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Bone Growth in Length 3

The osteoblasts start forming bone by
depositing bone lamellae on the
surface of the calcified cartilage.
This process produces bone on the
diaphyseal side of the epiphyseal
plate.

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Endochondral Bone Growth

Figure
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6.7
(a) ©Ed Reschke/Photolibrary/Getty Images; (c) ©Biophoto
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Bone Remodeling
Bone remodeling involves:
removal of existing bone by osteoclasts
and
deposition of new bone by osteoblasts
occurs in all bones
responsible for changes in bone shape,
bone
repair, adjustment of bone to stress, and
calcium ion regulation
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Bone Repair 1

1. Broken bone causes bleeding and a
blood clot forms.
2. Callus forms which is a fibrous
network between 2 fragments.
3. Cartilage model forms first then,
osteoblasts enter the callus and
form cancellous bone this continues
for 4-6 weeks after injury.
4. Cancellous bone is slowly remodeled
to form compact and cancellous
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Bone Repair 2

Figure
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6.8
(a) (top and bottom) ©Andrew F. Russo
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Bone and Calcium Homeostasis
Bone is a major storage site for
calcium
Movement of calcium in and out of
bone helps determine blood levels of
calcium
Calcium moves into bone as
osteoblasts build new bone
Calcium move out of bone as
osteoclasts break down bone
Calcium homeostasis is maintained by
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Calcium Homeostasis

Figure
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Bone Anatomical Terms 1

Foramen:
hole
Example - foramen magnum
Fossa:
depression
Example - glenoid fossa
Process:
projection
Example - mastoid process
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Bone Anatomical Terms 2

Condyle:
smooth, rounded end
Example - occipital condyle
Meatus:
canal-like passageway
Example - external auditory meatus
Tubercle:
lump of bone
Example - greater tubercle
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Axial Skeleton 1

The axial skeleton is composed of the
skull, the vertebral column, and the
thoracic cage.
The skull has 22 bones divided into
those of the braincase and those of the
face.
The braincase, which encloses the
cranial cavity, consists of 8 bones that
immediately surround and protect the
brain.
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Axial Skeleton 2

Thirteen of the facial bones are rather
solidly connected to form the bulk of
the face.
The mandible, however, forms a freely
movable joint with the rest of the skull.
There are also three auditory ossicles
in each middle ear (six total).

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Cranial Bones 1

Frontal bone
Anterior part of cranium
Parietal bones
Sides and roof of cranium
Occipital bones
Posterior portion and floor of cranium
Temporal bones
Inferior to parietal bones on each side of the
cranium
Temporomandibular joint
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Cranial Bones 2

Sphenoid bone
Forms part of cranium floor, lateral
posterior portions of eye orbits, lateral
portions of cranium anterior to temporal
bones
Sella turcica

Ethmoid bone
Anterior portion of cranium, including
medial surface of eye orbit and roof of
nasal cavity
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Facial Bones 1

Maxillae
Form upper jaw, anterior portion of hard
palate, part of lateral walls of nasal cavity,
floors of eye orbits
Maxillary sinus

Palatine bones
Form posterior portion of hard palate,
lateral wall of nasal cavity

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Facial Bones 2

Zygomatic bones
Cheek bones
Also form floor and lateral wall of each
eye orbit
Lacrimal bones
Medial surfaces of eye orbits

Nasal bones
Form bridge of nose
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Facial Bones 3

Vomer
In midline of nasal cavity
Forms nasal septum with the ethmoid
bone
Inferior nasal conchae
Attached to lateral walls of nasal cavity

Mandible
Lower jawbone

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The Skull 1

Figure
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6.12
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The Skull 2

Figure
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6.13
(b) ©Eric Wise
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The Skull 3

Figure
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6.15
(b) ©McGraw-Hill Education/Christine Eckel
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The Skull 4

Figure
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6.16
(b) ©McGraw-Hill Education/Christine Eckel
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Paranasal Sinuses 1

Several of the bones associated with
the nasal cavity have large cavities
within them, called the paranasal
sinuses which open into the nasal
cavity.
The paranasal sinuses are:
Frontal
Ethmoid
Sphenoid
Maxillary
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Paranasal Sinuses 2

Figure
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6.14
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Hyoid Bone 1

The hyoid bone is an unpaired, U-
shaped bone that is not part of the skull
and has no direct bony attachment to
the skull or any other bones.
The hyoid bone has the unique
distinction of being the only bone in the
body that does not articulate with
another bone.
The hyoid bone provides an attachment
for some tongue muscles, and it is an
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Hyoid Bone 2

Figure
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6.17
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Vertebral Column 1

The vertebral column, or spine, is the central
axis of the skeleton, extending from the base
of the skull to slightly past the end of the
pelvis.
In adults, it usually consists of 26 individual
bones, grouped into five regions.
The adult vertebral column has four major
curvatures: cervical, thoracic, lumbar and
sacrococcygeal.
The cervical region curves anteriorly.
The thoracic region curves posteriorly.
The lumbar region curves anteriorly
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Vertebral Column 2

 7 cervical vertebra
 12 thoracic vertebra
 5 lumbar vertebra
 1 sacrum
 1 coccyx
Atlas:
1st vertebra
holds head
Axis:
2nd vertebra
rotates head
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Functions of Vertebral Column
Supports body weight
Protects the spinal cord
Allows spinal nerves to exit the spinal
cord
Provides a site for muscle attachment
Provides movement of the head and
trunk

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Vertebral Column 3

Figure
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Vertebra

Figure
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Regional Differences in Vertebrae

Figure
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6.20
(a) ©McGraw-Hill Education/Christine Eckel
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Sacrum

Figure
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6.21
(c) ©McGraw-Hill Education/Christine Eckel
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Thoracic Cage 1

Protects vital organs
12 pair of ribs
Sternum:
breastbone
True ribs:
attach directly to sternum by cartilage
False ribs:
attach indirectly to sternum by cartilage
Floating ribs:
not attached to sternum
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Thoracic Cage 2

Figure
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6.22
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Bones of the Pectoral Girdle
Scapula:
shoulder blade
Clavicle:
collar bone

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Pectoral Girdle

Figure
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6.23
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Scapula and Clavicle

Figure
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6.25
(d) ©Trent Stephens
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Upper Limb Bones 1

Humerus:
upper limb
Ulna:
forearm
Radius:
forearm
Carpals:
wrist
Metacarpals:
hand
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Upper Limb Bones 2

Figure
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6.23
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The Humerus

Figure
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(c) ©McGraw-Hill Education/ Christine
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Ulna and Radius

Figure
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(b) ©McGraw-Hill Education/Christine Eckel
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Bones of the Wrist and Hand

Figure
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6.29
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Pelvic Girdle
Where lower limbs attach to the body
Pelvis:
includes pelvic girdle and coccyx
Ischium:
inferior and posterior region
Ilium:
most superior region
Acetabulum:
hip socket (joint)
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Pelvis

Figure
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Hip Bones

Figure
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(c) ©McGraw-Hill Education/Christine Eckel
 Comparison of the Male Pelvis 80

to the Female Pelvis

Figure
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Lower Limb Bones 1

Femur:
thigh
Patella:
knee cap
Tibia:
large lower leg
Fibula:
small lower leg

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Lower Limb Bones 2

Tarsals:
ankle
Metatarsals:
foot
Phalanges:
toes and fingers

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Lower Limb Bones 3

Figure
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Bones of the Thigh

Figure
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(b) ©McGraw-Hill Education/Christine Eckel
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Bones of the Leg

Figure
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(b) ©McGraw-Hill Education/Christine Eckel
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Bones of the Foot

Figure
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6.37
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Articulations
 Articulations (joints) are where two bones
come together.
 Joints can be classified structurally as
fibrous, cartilaginous, or synovial,
 Joints are also be classified in functional
categories according to their degree of
motion as synarthroses, amphiarthroses,
or diarthroses.

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Structural Classification of Joints

Fibrous joint
 united by fibrous connective tissue
 subclasses are sutures, syndesmosis,
and gomphoses
Cartilaginous joint
 united by means of cartilage
 subclasses are synchondroses and
symphysis

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Structural Classification of Joints
Synovial
 joined by a fluid cavity
 Most joints of the appendicular skeleton

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Functional Classification of Joints
Synarthrosis:
 non-movable joint
 Example – skull bone articulations
Amphiarthrosis:
 slightly movable joint
 Example - between vertebrae

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Functional Classification of Joints
Diarthrosis
 freely movable joint
 Example - knee, elbow, and wrist
articulations

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Fontanels and Sutures

Figure
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6.39
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Structure of a Synovial Joint

Figure
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Types of Synovial Joints

Figure
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Types of Movement 1

Flexion: bending
Extension: straightening
Abduction: movement away from midline
Adduction: movement toward the midline
Pronation: rotation of the forearm with palms
down
Supination: rotation of the forearm with palms
up
Rotation: movement of a structure about the
long axis
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Types of Movement 2

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 Effects of Aging on the Skeletal System 97

and Joints
1. Decreased Collagen Production
2. Loss of Bone Density
3. Degenerative Changes

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