Skeletal System revised (cueto).pdf

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Skeletal System
By : Marc Anthony P. Cueto MD
Learning Objectives
Describe the major functions of the skeletal system
Describe the basic structure of bones
To identify the different classification of bones
Identify the different bones per region
Bones
 Bone is a form of connective tissue (review basic tissues) in which the
intercellular substance consists of dense, white fibers embedded in a
hard calcium phosphate matrix.
 The fibrous tissue imparts resilience to the bone, while the calcium
salts resist compression forces.
Functions of Bones
 1. Support.
- give shape and support to the body;
- individual bones or group of bones provide a framework for the attachment of soft tissues
and organs
 2. Protection.
- skeletal elements protect against extraneous forces.
- skull acts as barrier of the brain external assault.
- ribs are commonly dubbed protective as they reduce the risk of impact, and respiratory
movements depend upon the ribs.
Functions of Bones
 3. Blood Cell Production.
- Hematopoietic function because of the presence of red bone marrow in spongy bones.
 4. Storage.
- Stores fats which are present in yellow bone marrow within the medullary cavity of long
bones.
- Calcium salts of bones is a valuable mineral reserve that maintain the normal
concentrations of calcium and phosphate ions in body fluids.
 5. Leverage.
LEVER - a rigid piece that transmits and modifies force or motion
Structure of Bones
 A thick layer of fibrous tissue called the
PERIOSTEUM covers all bone surfaces, other
than the articulating surfaces.
 The periosteum has an abundant vascular
supply, and the cells on its deeper surface are
osteogenic.
 The periosteum is particularly well united to
bone at sites where muscles, tendons, and
ligaments are attached to bone. Bundles of
collagen fibers known as Sharpey’s fibers
extend from the periosteum into the
underlying bone.
 The periosteum receives a rich nerve supply
and is very sensitive to trauma.
Structure of Bones
 Articular Cartilage
- plate of cartilage which covers the
articulating surface of bones.
These surfaces are that parts of the
bone which comes in contact with
another bone in a joint.
 Endosteum
- a membrane that lines the medullary
cavity of long bones.
Structure of Bones
 Bone Marrow
- connective tissue found within bones.
Types of Bone Marrow:
a. Red bone marrow - concerned with
production of RBC
b. Yellow bone marrow – for the storage of
fat. It is found within the medullary cavities of long
bones
 Nutrient blood vessels (nutrient artery)
- enters thru the nutrient foramen to give nutrition
to bones.
Classification : Microscopic Appearance
of Cut Surfaces
 A. Compact or Dense bone
 - These are hard and dense materials which
forms the layer of bone structure
(lamellae) just beneath the periosteum.
 - the ivory surface of mature bone;
 -there are no spaces between osteocytes.
 B. Trabecular or Spongy Bone
 – the interior of mature bone ( also termed
cancellous or spongy bone);
 - presence of spaces between osteocytes
filled with red bone marrow.
Classification : Developmental Origin
 a. Intramembranous (Mesenchymal or Dermal bone)
– formed by the direct formation of condensed mesenchyme.
- the intramembranous bone resembles spongy bone, further remodeling around the trapped vessels
can produce compact bones.
- several flat bones of the skull, and the lower jaw, and clavicles are formed this way.
- therefore they are found in flat bones and those that remain flat on maturation.
 b. Intracartilaginous or Substitution ( Endochondral bone)
-replacing a preformed cartilage model.
-most human bones are preformed cartilages;
-in early fetal life a long bone is prefigured by a rod of hyaline cartilage replacing a similar rod of
condensed mesenchyme.
Classification : Shape
 Long Bones
 Long bones are found in the limbs (e.g., the humerus, femur,
metacarpals,metatarsals, and phalanges).
 Their length is greater than their breadth
 They have a tubular shaft, the diaphysis, and usually an
epiphysis at each end.
 During the growing phase, the diaphysis is separated from the
epiphysis by an epiphyseal cartilage.
 The part of the diaphysis that lies adjacent to the epiphyseal
cartilage is called the metaphysis.
 The shaft has a central marrow cavity containing bone marrow.
 The outer part of the shaft is composed of compact bone that is
covered by periosteum.
 The ends of long bones are composed of cancellous bone
surrounded by a thin layer of compact bone.
 The articular surfaces of the ends of the bones are covered by
hyaline cartilage.
 Function : Support weight and facilitate movement
Classification : Shape
 Short Bones
 Short bones are found in the hand and foot
(e.g., the scaphoid, lunate, talus, and
calcaneum).
 They are roughly cuboidal in shape and are
composed of cancellous bone surrounded by a
thin layer of compact bone.
 Short bones are covered with periosteum, and
the articular surfaces are covered by hyaline
cartilage.
Classification : Shape
 Flat Bones
 Flat bones are found in the vault of the skull
(e.g., the frontal and parietal bones).
 They are composed of thin inner and outer
layers of compact bone, the tables, separated
by a layer of cancellous bone, the diploë.
 The scapulae, although irregular in shape, are
included in this group.
 Function : Protect internal organs
Classification : Shape
 Irregular Bones
 Irregular bones include those not
assigned to the previous groups (e.g.,
the bones of the skull, the vertebrae,
and the pelvic bones).
 They are composed of a thin shell of
compact bone with an interior made up
of cancellous bone.
Classification : Shape
 Sesamoid bones
 A sesamoid bone is one formed within a tendon
where the tendon passes over a joint.
 The greater part of a sesamoid bone is buried in the
tendon, and the free surface is covered with
cartilage.
 The largest sesamoid bone is the patella (“kneecap”),
which is located in the tendon of the quadriceps
femoris.
 Other examples are found in the tendons of the
flexor pollicis brevis (in the thumb) and flexor hallucis
brevis (in the big toe).
 The function of a sesamoid bone is to reduce friction
on the tendon; it can also alter the direction of pull of
a tendon.
Classification : Location

 In the regional classification scheme, the bones are
organized into two main groups: the axial and
appendicular skeletons.
 The axial skeleton consists of the elements forming
the central axis of the body.
 The appendicular skeleton consists of the bones
forming the upper and lower limb girdles and
extremities.
Axial Skeleton
Axial Skeleton

 The axial skeleton creates framework that supports and protects organ
systems in the dorsal and ventral cavities.
 In addition, it provides an extensive surface area for the attachment of
muscles that :
adjusts the position of the head, neck and trunk
perform respiratory movements;
stabilize or position elements of the appendicular skeleton.
Skull
 The skull is the most modified part of the axial skeleton. It is the entire skeleton of the face including
the mandible
 Functions :
 A skeletal complex adapted to support the brain and organs of special senses,
1. Sensation for seeing,
2. Hearing,
3. Taste,
4. Smell,

 Protection of the brain from external impacts,
 Serves as a barrier against stresses from powerful masticatory and axial musculature
 The rigid cranial walls provide continuous isolation for cerebral circulation,
 Contain openings that lead to the digestive tract, respiratory tract, and skull.
Skull
Vertebral Column

 The vertebral column is the central, longitudinal bony pillar of the
body.
 It supports the skull, pectoral girdle, upper limbs, and thoracic cage
and, by way of the pelvic girdle, transmits body weight to the lower
limbs.
 The spinal cord, the roots of the spinal nerves, and the covering
meninges lie within the cavity of the vertebral column, which provides
great protection to those structures.
Vertebral Column
 The vertebral column is composed of
33 vertebrae organized in five
regions—7 cervical, 12 thoracic, 5
lumbar, 5 sacral (fused to form the
sacrum), and ~4 coccygeal (the lower
3 are commonly fused).
 In adults = 26 vertebrae
 Numerous joints connect these
many individual segments, thus
making the vertebral column quite
flexible.
Vertebra
Vertebrae
 A typical vertebra consists of a rounded body anteriorly
and a vertebral arch posteriorly.
 These enclose a space termed the vertebral foramen. In
an articulated skeleton, the vertebral foramina are aligned
to form a continuous passageway termed the vertebral
canal, which conveys the spinal cord and its coverings.
 The vertebral arch consists of a pair of cylindrical pedicles,
which form the sides of the arch, and a pair of flattened
laminae, which complete the arch posteriorly.
 The vertebral arch gives rise to seven processes: one
spinous, two transverse, and four articular.
Typical Cervical Vertebrae
 Typical cervical vertebrae, such as C4 or C5, have several
characteristic features that differentiate them from thoracic or
lumbar vertebrae.
 Cervical vertebrae have a small body, reflecting the fact that
they carry the least amount of body weight.
 Cervical vertebrae usually have a bifid (Y-shaped) spinous
process. The spinous processes of the C3–C6 vertebrae are short,
but the spine of C7 is much longer. You can find these vertebrae
by running your finger down the midline of the posterior neck
until you encounter the prominent C7 spine located at the base
of the neck.
 The transverse processes of the cervical vertebrae are sharply
curved (U-shaped) to allow for passage of the cervical spinal
nerves.
 Each transverse process also has an opening called the transverse
foramen. An important artery (vertebral artery) that supplies the
brain ascends up the neck by passing through these openings.
 The superior and inferior articular processes of the cervical
vertebrae are flattened and largely face upward or downward,
respectively.
Upper six
cervical
vertebrae

Vertebral
artery
Atypical Cervical Vertebrae : Atlas

 The first cervical vertebra, or atlas, does not
possess a body or a spinous process.
 Instead, it has anterior and posterior arches.
 It has a lateral mass on each side with articular
surfaces on its upper surface for articulation with
the occipital condyles of the skull (atlanto-
occipital joints) and articular surfaces on its
inferior surface for articulation with the C2
vertebra (atlantoaxial joints).
Atypical Cervical Vertebrae : Axis
 The second cervical vertebra, or axis, has a
peglike odontoid process (dens) that projects
upward from the superior surface of the body.
 The dens represents the body of the atlas that
fused with the body of the axis during early
development.
Atlanto Axial Joint
Atypical Cervical Vertebra : Vertebra
Prominens
 The seventh cervical vertebra, or vertebra
prominens, is so named because it has the
longest spinous process, and the process is not
bifid.
 The transverse process is large, but the
foramen transversarium is small and transmits
the vertebral vein or veins.
Typical Thoracic Vertebrae
 The bodies of the thoracic vertebrae are larger than those of
cervical vertebrae.
 The characteristic feature for a typical midthoracic vertebra is
the spinous process, which is long and has a pronounced
downward angle that causes it to overlap the next inferior
vertebra.
 The superior articular processes of thoracic vertebrae face
anteriorly and the inferior processes face posteriorly. These
orientations are important determinants for the type and
range of movements available to the thoracic region of the
vertebral column.
 Thoracic vertebrae have several additional articulation sites,
each of which is called a facet, where a rib is attached.
 Most thoracic vertebrae have two facets located on the lateral
sides of the body, each of which is called a costal facet (costal =
“rib”).
 These are for articulation with the head (end) of a rib. An
additional facet is located on the transverse process for
articulation with the tubercle of a rib.
Typical Lumbar Vertebrae
Sacrum and Coccyx
 The sacrum provides
support to the pelvic bones
and forms the lower back
portion of the pelvis.
 Coccyx also known as tail is
the rear end of the spinal
column
Thoracic Cage / Rib Cage
 The thoracic cage (rib cage) forms
the thorax (chest) portion of the
body.
 It consists of the 12 pairs of ribs with
their costal cartilages and the
sternum.
 The ribs are anchored posteriorly to
the 12 thoracic vertebrae (T1–T12).
The thoracic cage protects the heart
and lungs.
Thoracic Cage/Rib Cage
 The upper seven pairs of ribs are
known as true ribs because their
costal cartilages articulate anteriorly
directly with the sternum.
 The lower five pairs of ribs (ribs eight
to twelve) are known as false
ribs because their costal cartilages do
not articulate directly with the
sternum.
 The costal cartilages of ribs eight to
ten connect with the costal cartilages
of the ribs above.
 The costal cartilages of the ribs eleven
and twelve have no articulation with
other ribs or with the sternum and are
know as floating ribs.
Sternum
 The sternum is the elongated bony
structure that anchors the anterior
thoracic cage.
 It consists of three parts: the
manubrium, body, and xiphoid
process.
Ribs

 Each rib is a curved, flattened bone that
contributes to the wall of the thorax.
 The ribs articulate posteriorly with the T1–
T12 thoracic vertebrae, and most attach
anteriorly via their costal cartilages to the
sternum.
 There are 12 pairs of ribs. The ribs are
numbered 1–12 in accordance with the
thoracic vertebrae.
Appendicular Skeleton
Pectoral Girdle
Pectoral Girdle : Clavicle
 The appendicular skeleton includes all of the
limb bones, plus the bones that unite each limb
with the axial skeleton.
 The bones that attach each upper limb to the
axial skeleton form the pectoral girdle (shoulder
girdle). This consists of two bones : the scapula
and clavicle.
 The clavicle (collarbone) is an S-shaped bone
located on the anterior side of the shoulder. It is
attached on its medial end to the sternum of the
thoracic cage, which is part of the axial skeleton.
 The lateral end of the clavicle articulates (joins)
with the scapula just above the shoulder joint.
Pectoral Girdle : Clavicle
 Functions
 Connect the arm with the rest of the
skeleton.
 Allow free movement of the shoulder away
from the body.
 Transmit force or any physical impact from
the upper limb to the axial skeleton.
 Protect the neurovascular bundle supplying
the upper limb.
 Along with the rib cage, they protect the
heart from external shock.
Pectoral Girdle : Clavicle
1. Sternal (Medial) End
 The part of the clavicle that lies towards the
sternum is called the sternal end or the medial
end.
 It is curved and convex, bearing a rounded end
that articulates with the sternum, forming the
sternoclavicular joint.
i) Sternal Facet
 On the far edge of the sternal end, a triangular
facet, called the sternal facet is present.
 It bears a posterior tip and an anterior base,
connecting the clavicle to the manubrium of the
sternum at the sternoclavicular (SC) joint.
 The articular surface extends to the inferior
side, articulating with the costal cartilage of the
first rib.
Pectoral Girdle : Clavicle
2. Acromial (Lateral) End
 The broad, flat region of the clavicle lying
towards the scapula is known as the acromial
end or lateral end.
 It is both the widest and thinnest portion of the
clavicle.
 This region bears a facet known as acromial
facet that articulates with the scapula.
 The lateral end has two borders: anterior and
posterior.
 The anterior border is concave forward, whereas
the posterior border is convex backward.
i) Acromial Facet
 At the extreme edge of the acromial end, there
is a small, flattened, and oval facet called the
acromial facet.
 This helps the clavicle to articulate with the
acromion of the scapula, forming the
acromioclavicular (AC) joint.
Pectoral Girdle : Clavicle
3. Shaft
 The middle region of the clavicle, i.e., the region
between the sternal and acromial end, is the shaft.
Several muscles originate from or get attached in
this part.
 The shaft can be divided into two regions,
depending on its location and spread.
 The region lying on the side of the sternal end,
covers the maximum portion, approximately two-
thirds of the bone.
 This region is known as the medial two-third.
 On the other hand, the region of the shaft that lies
towards the acromial end covers the remaining one-
third of the bone.
 This region is known as the lateral third.
Several important bony landmarks are found in these
regions.
Pectoral Girdle : Clavicle
Medial two-third
i) Costal Tuberosity
 On the inferior side of the sternal end,
the bone bears a roughened oval
elevation, called the costal tuberosity.
 It is over 2 cm in length and acts as a site
of attachment for costoclavicular
ligament.
 This ligament attaches the clavicle to the
costal cartilage of the first rib.
Pectoral Girdle : Clavicle
 Lateral third
 i) Conoid Tubercle
 On the inferior surface of the bone, there is
a rough, bumpy projection called the conoid
tubercle.
 It serves as an attachment site for the
conoid ligament, a part of the
coracoclavicular ligament.
 The coracoclavicular ligament attaches the
clavicle to the coracoid process of the
scapula.
 The prominence of the conoid tubercle
serves as a useful landmark to identify the
inferior surface of the clavicle.
Pectoral Girdle : Clavicle
 ii) Trapezoid Line
 It is an elevation or ridge that runs obliquely
from the conoid tubercle to the lateral end
of the clavicle.
 It provides an attachment point for the
trapezoid ligament, which is also a part of
the coracoclavicular ligament mentioned
above.
 Iii) Subclavian groove or sulcus
 It is an indentation that runs horizontally
along the inferior surface of the shaft, from
the costal tuberosity to the conoid tubercle.
 It acts as a site of attachment for the
subclavius muscle.
Pectoral Girdle : Scapula
 The scapula (shoulder blade) lies on the
posterior aspect of the shoulder.
 It is supported by the clavicle, which also
articulates with the humerus (arm bone) to
form the shoulder joint.
 The scapula is a flat, triangular-shaped bone
with a prominent ridge running across its
posterior surface – spine of the scapula.
 This ridge extends out laterally, where it forms
the bony tip of the shoulder and joins with the
lateral end of the clavicle – acromion
 Glenoid fossa – articulates with the head of the
humerus
Pectoral Girdle : Scapula
 Functions
 The scapula helps in several daily
movements and smooth motion of the
upper arm.
 It assists in both forward and backward
movement of the pectoral girdle and chest
muscles by moving closer and away from
the vertebral column.
 During some motions, like shrugging the
shoulders, the entire shoulder capsule
moves up and down due to elevation and
depression of this bone.
 It stabilizes the shoulder capsule during
excessive arm motion by rotating upwards
and downwards.
Pectoral Girdle : Scapula
 The body of the scapula consists of a
triangular-shaped flat blade, with an apex
pointed below. Since it is triangular, it bears
three borders.
 Borders and angles
 Superior border: It is the shortest and thinnest
border.
 Medial border: It is a thin border running
parallel to the vertebral column and is often
referred to as the vertebral border.
 Lateral border: It is alternatively known as the
axillary border, running towards the apex of
the axilla. Out of the three borders, it is the
thickest and strongest. It also bears the glenoid
cavity, which articulates with the rounded head
of the humerus, forming the shoulder joint or
glenohumeral joint.
Pectoral Girdle : Scapula
 It also has three angles:
 Lateral angle: where the superior
border converges with the lateral
border.
 Superior angle: Where the superior
border also meets with the medial
border.
 Inferior angle: Where the medial and
lateral borders meet.
Pectoral Girdle : Scapula
Surfaces
1. Costal Surface
 It is the anterior surface of the scapula facing the
thoracic cage or ribcage.
 It has a large concave depression over most of the
surface, called the subscapular fossa, from where the
rotator cuff muscle subscapularis originates.
 This region is marked by longitudinal ridges, out of
which a thick ridge joins the lateral border. This part of
the bone acts as a lever for the action of the serratus
anterior muscle, helping to move the arm away from
the body.
 A hook-like projection, called the coracoid process,
originates from the superior border of the head of the
scapula, projecting forward and curving laterally, lying
underneath the clavicle.
Pectoral Girdle : Scapula
2. Lateral Surface
 This surface of the scapula faces the humerus.
 Its important bony landmarks are:
 Glenoid fossa – It is a shallow pyriform cavity located at
the lateral angle of the scapula. It articulates with the
rounded head of the humerus, forming the
glenohumeral (shoulder) joint.
 Supraglenoid tubercle – It is a small rough projection
located immediately above the glenoid fossa near the
base of the coracoid process.
 Infraglenoid tubercle – It is a rough impression located
on the lateral part of the scapula, immediately below
the glenoid fossa.
Pectoral Girdle : Scapula
 3. Posterior Surface
 This surface of the scapula faces outwards. Most of
the rotator cuff muscles of the shoulder arise from
here. Its important anatomical landmarks are:
 Spine: It is a triangular plate of bone located on the
posterior surface, running transversely across the
scapula, dividing the dorsal surface of the scapula
into supraspinous and infraspinous fossae.
 The two fossae remain connected by the
spinoglenoid notch, situated lateral to the root of
the spine, bridged by the spinoglenoid ligament.
 It has three borders and two surfaces. Its posterior
border, the crest of the spine, bears upper and
lower lips.
Pectoral Girdle : Scapula
 Supraspinous fossa: It is the area above the
spine of the scapula.
 It is concave, smooth, and broader at its
vertebral than at its humeral end. The
supraspinatus muscle originates from the
middle of this area.
 It is much smaller than the infraspinous fossa,
bearing the spinoglenoid fossa on its side.
 The fossa houses the suprascapular canal,
connecting the suprascapular notch and the
spinoglenoid notch conveying the suprascapular
nerve and vessels.
Pectoral Girdle : Scapula
 Infraspinous fossa: It is the area below the
spine of the scapula. It is convex and much
larger than the preceding one.
 At its upper part, towards the vertebral
margin, it shows a shallow concavity. In the
center, it is convex, while near the lateral
border, it has a deep groove running from the
upper toward the lower part.
 Acromion: It is a large bony projection on the
upper end of the scapula. It arches over the
shoulder joint, articulating with the clavicle at
the acromioclavicular (AC) joint.
Pectoral Girdle : Scapula
Articulations
 Glenohumeral joint: This is a ball and socket
joint formed between the glenoid fossa of
the scapula and the rounded head of the
humerus.
 Acromioclavicular joint: It is a gliding joint
between the acromion of the scapula and the
clavicle.
Upper Limb
Upper Limb
 The upper limb is divided into three regions.
 These consist of the arm, located between the
shoulder and elbow joints; the forearm, which is
between the elbow and wrist joints; and
the hand, which is located distal to the wrist.
 There are 30 bones in each upper limb.
The humerus is the single bone of the upper arm,
and the ulna (medially) and the radius (laterally)
are the paired bones of the forearm.
 The base of the hand contains eight bones, each
called a carpal bone, and the palm of the hand is
formed by five bones, each called a metacarpal
bone.
 The fingers and thumb contain a total of 14
bones, each of which is a phalanx bone of the
hand.
Upper Limb : Humerus
 The humerus (Latin : upper arm; shoulder) is
the longest and largest bone in the upper
limb. it forms the framework of the arm
and it has expanded ends and a shaft.
 Proximally a round head forms with the
scapular glenoid cavity
 The distal end, loosely termed ‘condylar’, is
adapted to the forearm bones at the elbow
joint.
 https://sketchfab.com/3d-models/humero-
humerus-
9b83b59269ad4c2abfe0a0fb18fec8b9
Upper Limb : Humerus
 Functions
 It helps in the functioning of the upper limb by
providing structural support, and serving as an
attachment site to 13 muscles that aid in the
movements of the hand and elbow.
 The humeral head makes up a portion of the
ball-and-socket shoulder joint, which is the
insertion point for muscles making up the
shoulder girdle.
 Several ligaments present in this area assist
with securing the musculature. They also
provide motion to the shoulder joint.
 The basilic vein, traveling close to the
humerus, helps drain parts of the hand and
forearm.
 The brachial plexus lying across the front
portion of the bone provides sensation and
motion to every muscle in the arm and certain
portions of the neck and spinal cord.
 Upper Limb : Humerus

 The humerus comprises a proximal region, a
shaft, and a distal region. All of these are
important anatomical landmarks.
 1. Proximal Landmarks of Humerus
 Head: The proximal end of the humerus forms
a smooth, spherical structure known as the
head.
 It is the ball in the the ball-and-socket joint
in the shoulder, where the glenoid cavity of
the scapula acts as the socket.
 Due to its round shape, the head rotates
around its axis at the shoulder joint and
moves in all directions.
 Upper Limb : Humerus

 Anatomical Neck: Just below the head, the
humerus narrows into the anatomical neck.
 It separates the head from the other two
regions: greater and lesser tuberosities.
 Greater Tubercle (Greater Tuberosity): It
lies on the lateral side of the bone, with an
anterior, and a posterior surface.
 The three rotator cuff muscles, supraspinatus,
infraspinatus, and teres minor, attach to the
greater tubercle’s superior, middle, and
inferior facets, respectively.
 Upper Limb : Humerus
 Lesser Tubercle (Lesser Tuberosity): It is much smaller than
the greater tubercle located inferior to the head, bearing
only an anterior surface.
 This is where the the fourth and last rotator cuff muscle, the
subscapularis, attaches.
 Intertubercular Sulcus: Separating the two tuberosities is a
deep groove known as the intertubercular sulcus or bicipital
groove.
 The tendon of the bicep’s long head emerges from the
shoulder joint and runs through this groove.
 The edges of the intertubercular sulcus are known as lips,
where pectoralis major, teres major, and latissimus dorsi get
inserted.
 Upper Limb : Humerus

 Surgical Neck: It is the part between the tuberosities
and the shaft where the humerus narrows down to form
the surgical neck before extending toward the elbow
joint.
 Here, circumflex humeral vessels and the axillary nerve
lie against the bone.
 The surgical neck is a common site for fractures (hence
its name), while fractures of the anatomical neck are
rare.
Upper Limb : Humerus
 2. The Shaft
 A long, cylindrical shaft (body) composes
the middle part of the humerus.
 It bears a roughened surface on the
lateral side, known as the deltoid
tuberosity, as the deltoid muscle gets
attached there.
 The width of the bone gradually
increases past the deltoid tuberosity,
becoming double as it moves towards the
elbow joint.
Upper Limb : Humerus
 A shallow depression called the radial (or
spiral) groove runs diagonally down the
posterior surface of the humerus,
parallel to the deltoid tuberosity. This
groove contains the radial nerve and the
profunda brachii artery.
 The shaft serves as the surface for
attachment of several muscles
 Anterior Side: Coracobrachialis,
brachialis, deltoid, brachioradialis
 Posterior Side: The medial and lateral
heads of the triceps. Their origin is
marked by the spiral groove on the
posterior side of the humerus.
Upper Limb : Humerus

 3. Distal Region of Humerus
 The lower end of the humerus is the
distal humerus, containing two joint-
forming processes, the capitulum and
the trochlea.
 The trochlea tightly hinges with the
forearm’s ulna, forming half of the
elbow joint.
 On the other hand, the convex capitulum
articulates with the concave radial head
on the lateral side of the arm.
 The joint thus formed is the elbow that
allows the human arm to bend and fold
in the middle.
Upper Limb : Humerus

 A small cavity called the olecranon fossa
on the posterior side of the bone locks
the olecranon or the tip of the ulna into
the bone.
 This locking prevents us from extending
the elbow beyond 180 degrees.
 Despite this, the distal portion of the
humerus also contains two other
depressions, known as the coronoid and
radial fossae.
 They lodge the forearm bones during
flexion or extension of the elbow.
Upper Limb : Humerus
 The medial and lateral borders of the distal
humerus form the medial and lateral supracondylar
ridges.
 Among the two ridges, the lateral supracondylar
ridge is relatively roughened, providing the
common origin site of the forearm extensor
muscles.
 The extracapsular projections of the bone, the
lateral and medial epicondyles, are found
immediately distal to the supracondylar ridges.
 Both of the epicondyles can be felt at the elbow
from the outside.
 Among the two, the medial is larger, extending
more towards the elbow joint.
 The ulnar nerve passes through a groove present on
the posterior side of the medial epicondyle.
Upper Limb : Radius
 The radius, also known as the radial
bone, is one of the two forearm bones in
the human body, with the other being
the ulna. It is instrumental in the shaping
and use of hands.
 Where is the Radius Bone Located in
the Arm
 It is located on the thumb side of the
hand, lying laterally in the lower arm,
parallel in reference to the ulna.
 https://sketchfab.com/3d-models/radio-
radius-
f71bb6cf71914e22b7b860c8b9151f78
Upper Limb : Radius
 Functions of the Radius
 Proper functioning of the radius is
essential for performing any day-to-day
activity with our hand, from holding
something, balancing with the arm,
throwing something, writing, typing, using
the phone, etc.
 It forms a hinge joint with the humerus
bone, which allows us to flex and extend
the elbow.
 The radius moves around the ulna at the
wrist, enabling us to turn our hand’s palm
up and down.
 The bone also forms an ellipsoidal joint
with the proximal carpal row that allows
us to move, rotate, bend, and flex the
wrist.
 Upper Limb : Radius
 The proximal end of the radius are
The head is discoid, its proximal surface
has a shallow cup for the humeral
capitulum.
Its smooth articular periphery is
vertically deepest medially, where it
contacts the ulnar radial notch.
The neck is the constriction distal to the
head, which overhangs it, especially on
the lateral side.
The tuberosity is distal to the medial part
of the neck; it is posteriorly rough but
anteriorly usually smooth.
Upper Limb : Radius
 The distal end are describe as
Its lateral surface is slightly rough,
projecting distally as
a styloid process palpable when
tendons around it are slack.
Distal is the
smooth carpal articular surface,
divided by a ridge into medial and
lateral areas.
The anterior surface is a thick,
prominent ridge, palpable even through
overlying tendons.
The medial surface is the ulnar notch,
smooth,anteroposteriorly concave for
articulation with the ulna’s head.
Upper Limb : Ulna
 Ulna (plural: ulnae; pronunciation: úl-nu) is
one of the two primary bones forming the
forearms in humans, the other one being
the radius.
 There is one ulna bone in each arm. It is
a long bone and is vital in forming both the
wrist and elbow joints.
 Where is the Ulna Bone Located in the
Human Body
 It is the medial bone of the forearm, located
on the side opposite to the thumb, that is on
the side of the little finger, extending from
the region of the wrist to the elbow.
 In other words, the ulna can be found
between the proximal carpal row and the
upper arm bone humerus, running parallel to
the other lower arm bone radius.
Upper Limb : Ulna
 The proximal end has the following
The olecranon process is bent forwards at its
summit like beak, which enters the humeral
olecranon fossa in extension.
The coronoid process projects anteriorly distal
to the olecranon process
Distal to which, on the lateral surface, is a
shallow, smooth, oval radial notch for
articulation with the radial head.
The coronoid’s anterior surface is triangular, its
distal part being the tuberosity of the ulna.
The radial notch , an oval proximal depression
on the lateral aspect of the coronoid,
articulates with the peripheryof the radial head
The trochlear notch articulates with the
trochlea of the humerus
https://sketchfab.com/3d-models/ulna-
3bccfa9e2e0a4dab99035605fa9ac059
Upper Limb : Ulna

 The distal of ulna is
 a.The head is visible in
pronation on the
posteromedial carpal aspect
and can be gripped when the
supinated hand is flexed.
 b.The latter, the styloid
process a short round,
posterolateral projection of
the ulna’s distal end.
Upper Limb : Carpal Bones

 The CARPAL bones contains eight
bones in proximal and distal rows of four.
 The term "carpus" is derived from the
Latin carpus and the Greek καρπός
(karpós), meaning "wrist".
 Proximally, in lateral to medial order, are
the :
the scaphoid,
the lunate,
the triquetral,
and the pisiform
https://sketchfab.com/3d-models/bones-of-
the-hand-turntable-
cd8e31d740824d6b93791d52d53be525
Upper Limb : Carpal Bones
 Distal row, are composed of:
trapezium,
trapezoid,
capitate
and hamate
Upper Limb : Metacarpals
 The METACARPALS is composed of five
metacarpal bones, conventionally
numbered in lateromedial order. These
are miniature long bones with a distal
head, shaft, and expanded base.
 "the middle bones of the hand," 1650s,
Modern Latin, from
Greek metakarpion,
from meta "between; next after"
(see meta-) + karpos "wrist"
(see carpus). In humans, the part of
the hand between the wrist and the
fingers or thumb
 There are 14 PHALANGES, three in
each finger, two in the thumb. Each has
a head, shaft and proximal base.
Pelvic Girdle
Pelvic Girdle
 The pelvic girdle is a ring-like bony structure,
located in the lower part of the trunk. It
connects the axial skeleton to the lower limbs.
 The bony pelvis consists of the two hip
bones (also known as innominate or pelvic
bones), the sacrum and the coccyx.
 There are four articulations within the pelvis:
 Sacroiliac joints (x2) – between the ilium of the
hip bones, and the sacrum
 Sacrococcygeal symphysis – between the sacrum
and the coccyx.
 Pubic symphysis – between the pubis bodies of
the two hip bones.
 Ligaments attach the lateral border of the sacrum
to various bony landmarks on the bony pelvis to
aid stability.
Functions of the Pelvis

 The strong and rigid pelvis is adapted
to serve a number of roles in the
human body. The main functions
being:
 Transfer of weight from the upper
axial skeleton to the lower
appendicular components of the
skeleton, especially during
movement.
 Provides attachment for a number
of muscles and ligaments used in
locomotion.
 Contains and protects the
abdominopelvic and pelvic viscera.
The Greater and Lesser Pelvis
 The osteology of the pelvic girdle allows the
pelvic region to be divided into two:
 Greater pelvis (false pelvis) – located
superiorly, it provides support of the lower
abdominal viscera (such as the ileum and
sigmoid colon). It has little obstetric
relevance.
 Lesser pelvis (true pelvis) – located
inferiorly. Within the lesser pelvis reside the
pelvic cavity and pelvic viscera.
 The junction between the greater and lesser
pelvis is known as the pelvic inlet. The
outer bony edges of the pelvic inlet are
called the pelvic brim.
Pelvic Inlet
 The pelvic inlet marks the boundary between
the greater pelvis and lesser pelvis. Its size is
defined by its edge, the pelvic brim.
 The borders of the pelvic inlet:
 Posterior – sacral promontory (the superior
portion of the sacrum) and sacral wings (ala).
 Lateral – arcuate line on the inner surface of
the ilium, and the pectineal line on the
superior pubic ramus.
 Anterior – pubic symphysis.
 The pelvic inlet determines the size and
shape of the birth canal, with the prominent
ridges a key site for attachment of muscle
and ligaments.
Pelvic Outlet

 The pelvic outlet is located at the end of
the lesser pelvis, and the beginning of the
pelvic wall.
 Its borders are:
 Posterior: The tip of the coccyx
 Lateral: The ischial tuberosities and the
inferior margin of the sacrotuberous
ligament
 Anterior: The pubic arch (the inferior
border of the ischiopubic rami).
 The angle beneath the pubic arch is known
as the sub-pubic angle and is of a greater
size in women.
Composition of the Hip Bone

 The hip bone is comprised of the three
parts; the ilium, pubis and ischium. Prior to
puberty, the triradiate cartilage separates
these parts – and fusion only begins at the
age of 15-17.
 Together, the ilium, pubis and ischium form
a cup-shaped socket known as
the acetabulum (literal meaning in Latin is
‘vinegar cup‘). The head of the femur
articulates with the acetabulum to form
the hip joint.
 https://sketchfab.com/3d-models/female-
pelvis-2b6d64eef5d840bda4b998e27895038e
The Ilium
 The ilium is the widest and largest of the three
parts of the hip bone, and is located
superiorly. The body of the ilium forms the
superior part of the acetabulum (acetabular
roof). Immediately above the acetabulum, the
ilium expands to form the wing (or ala).
 The wing of the ilium has two surfaces:
 Inner surface – has a concave shape, which
produces the iliac fossa (site of origin of the
iliacus muscle).
 External surface (gluteal surface) – has a
convex shape and provides attachments to the
gluteal muscles.
 The superior margin of the wing is thickened,
forming the iliac crest. It extends from the
anterior superior iliac spine (ASIS) to the
posterior superior iliac spine (PSIS).
 On the posterior aspect of the ilium there is an
indentation known as the greater sciatic notch.
The Pubis
 The pubis is the most anterior portion of the
hip bone. It consists of a body, superior ramus
and inferior ramus (ramus = branch).
 Pubic body – located medially, it articulates
with the opposite pubic body at the pubic
symphysis. Its superior aspect is marked by a
rounded thickening (the pubic crest), which
extends laterally as the pubic tubercle.
 Superior pubic ramus – extends laterally from
the body to form part of the acetabulum.
 Inferior pubic ramus – projects towards the
ischium.
 Together, the superior and inferior rami enclose
part of the obturator foramen – through which
the obturator nerve, artery and vein pass
through to reach the lower limb.
The Ischium
 The ischium forms the posteroinferior part of
the hip bone.
 Much like the pubis, it is composed of a body,
an inferior ramus and superior ramus.
 The inferior ischial ramus combines with the
inferior pubic ramus forming the ischiopubic
ramus, which encloses part of the obturator
foramen.
 The posterorinferior aspect of the ischium
forms the ischial tuberosities and when
sitting, it is these tuberosities on which our
body weight falls.
The Ischium
 Near the junction of the superior ramus and
body is a posteromedial projection of bone;
the ischial spine.
 Two important ligaments attach to the
ischium:
 Sacrospinous ligament – runs from the ischial
spine to the sacrum, thus creating the
greater sciatic foramen through which lower
limb neurovasculature (including the sciatic
nerve) transcends.
 Sacrotuberous ligament – runs from the
sacrum to the ischial tuberosity, forming the
lesser sciatic foramen.
Lower Limb
The Femur
Femur
 The femur is the only bone in the
thigh and the longest bone in the
body.
 It acts as the site of origin and
attachment of many muscles and
ligaments, and can be divided into
three parts; proximal, shaft and
distal.
 https://sketchfab.com/3d-
models/femur-femur-
440a8bf36c2a43d6a16c0d776c783b
45
Proximal Femur
 The proximal aspect of the femur articulates
with the acetabulum of the pelvis to form
the hip joint.
 It consists of a head and neck, and two bony
processes – the greater and lesser trochanters.
There are also two bony ridges connecting the
two trochanters; the intertrochanteric line
anteriorly and the trochanteric crest posteriorly.
 Head – articulates with the acetabulum of the
pelvis to form the hip joint. It has a smooth
surface, covered with articular cartilage (except
for a small depression – the fovea – where
ligamentum teres attaches).
Proximal Femur
 Neck – connects the head of the femur with the
shaft. It is cylindrical, projecting in a superior
and medial direction. It is set at an angle of
approximately 135 degrees to the shaft. This
angle of projection allows for an increased range
of movement at the hip joint.
 Greater trochanter – the most lateral palpable
projection of bone that originates from the
anterior aspect, just lateral to the neck.
 It is the site of attachment for many of the
muscles in the gluteal region, such as gluteus
medius, gluteus minimus and piriformis. The
vastus lateralis originates from this site.
 An avulsion fracture of the greater trochanter can
occur as a result of forceful contraction of the
gluteus medius.
Proximal Femur
 Lesser trochanter – smaller than
the greater trochanter. It projects
from the posteromedial side of the
femur, just inferior to the neck-
shaft junction.
 It is the site of attachment for
iliopsoas (forceful contraction of
which can cause an avulsion
fracture of the lesser
trochanter).
Proximal Femur
 Intertrochanteric line – a ridge of bone
that runs in an inferomedial direction on
the anterior surface of the femur, spanning
between the two trochanters. After it
passes the lesser trochanter on the
posterior surface, it is known as the
pectineal line.
 It is the site of attachment for the
iliofemoral ligament (the strongest
ligament of the hip joint).
 It also serves as the anterior attachment
of the hip joint capsule.
Proximal Femur
 Intertrochanteric crest – like the
intertrochanteric line, this is a ridge
of bone that connects the two
trochanters.
 It is located on the posterior surface
of the femur.
 There is a rounded tubercle on its
superior half called the quadrate
tubercle; where quadratus femoris
attaches.
The Shaft
 The shaft of the femur descends in a
slight medial direction.
 This brings the knees closer to the body’s
centre of gravity, increasing stability.
 A cross section of the shaft in the middle is
circular but flattened posteriorly at the
proximal and distal aspects.
 On the posterior surface of the femoral shaft,
there are roughened ridges of bone, called
the linea aspera (Latin for rough line).
 This splits distally to form the medial and
lateral supracondylar lines. The flat popliteal
surface lies between them.
The Shaft
 Proximally, the medial border of the linea
aspera becomes the pectineal line.
 The lateral border becomes the gluteal
tuberosity, where the gluteus maximus
attaches.
 Distally, the linea aspera widens and forms the
floor of the popliteal fossa, the medial and
lateral borders form the medial and lateral
supracondylar lines.
 The medial supracondylar line ends at the
adductor tubercle, where the adductor magnus
attaches.
 The Distal Femur

 The distal end of the femur is characterised by the
presence of the medial and lateral condyles,
which articulate with the tibia and patella to form
the knee joint.
 Medial and lateral condyles – rounded areas at
the end of the femur.
 The posterior and inferior surfaces articulate with
the tibia and menisci of the knee, while the
anterior surface articulates with the patella.
 The more prominent lateral condyle helps prevent
the natural lateral movement of the patella; a
flatter condyle is more likely to result in patellar Condyle and epicondyle occur at the end of the long
dislocation. bones. The condyle is more prominent than the
epicondyle. The condyle is smooth and round
whereas epicondyle is rough. Epicondyle is a
projection on the condyle. The main
difference between condyle and epicondyle is
that condyle forms an articulation with another
bone. whereas epicondyle provides sites for the
attachment of muscles.
 The Distal Femur

 Medial and lateral epicondyles – bony elevations
on the non-articular areas of the condyles. The
medial epicondyle is the larger.
 The medial and lateral collateral ligaments of the
knee originate from their respective epicondyles.
 Intercondylar fossa – a deep notch on the
posterior surface of the femur, between the two
condyles. It contains two facets for attachment of
intracapsular knee ligaments; the anterior
cruciate ligament (ACL) attaches to the medial
aspect of the lateral condyle and the posterior
cruciate ligament (PCL) to the lateral aspect of Condyle and epicondyle occur at the end of the long
bones. The condyle is more prominent than the
the medial condyle. epicondyle. The condyle is smooth and round
whereas epicondyle is rough. Epicondyle is a
projection on the condyle. The main
difference between condyle and epicondyle is
that condyle forms an articulation with another
bone. whereas epicondyle provides sites for the
attachment of muscles.
The Patella
Patella
 The patella (kneecap) is located at the front
of the knee joint, within the patellofemoral
groove of the femur. Its superior aspect is
attached to the quadriceps tendon and inferior
aspect to the patellar ligament.
 It is classified as a sesamoid type bone due to
its position within the quadriceps tendon, and
is the largest sesamoid bone in the body. In
this article we will look at the anatomy of the
patella – its surface features, functions and
clinical relevance.
 The patella has two main functions:
 Leg extension – Enhances the leverage that the
quadriceps tendon can exert on the femur,
increasing the efficiency of the muscle.
 Protection – Protects the anterior aspect of the
knee joint from physical trauma.
 https://sketchfab.com/3d-models/patela-
patella-f0e558f9a8734e459bee82a319876621
Patella
 The patella has a triangular shape, with
anterior and posterior surfaces.
The apex of the patella is situated
inferiorly and is connected to the tibial
tuberosity by the patellar ligament.
The base forms the superior aspect of the
bone and provides the attachment area for
the quadriceps tendon.
 The posterior surface of the patella
articulates with the femur, and is marked
by two facets:
 Medial facet – articulates with the medial
condyle of the femur.
 Lateral facet – articulates with the lateral
condyle of the femur.
The Tibia
Tibia
 The tibia is the main bone of the lower
leg, forming what is more commonly
known as the shin.
 It expands at its proximal and distal ends;
articulating at the knee and ankle joints
respectively. The tibia is the second
largest bone in the body and it is a
key weight-bearing structure.
 https://sketchfab.com/3d-models/tibia-
77bcff2d834e47f4bb19fe19f912f44b
Proximal tibia
 The proximal tibia is widened by the medial
and lateral condyles, which aid in weight-
bearing.
 The condyles form a flat surface, known as
the tibial plateau.
 This structure articulates with the femoral
condyles to form the key articulation of the
knee joint.
 Located between the condyles is a region
called the intercondylar eminence – this
projects upwards on either side as the medial
and lateral intercondylar tubercles.
 This area is the main site of attachment for the
ligaments and the menisci of the knee joint.
 The intercondylar tubercles of the tibia
articulate with the intercondylar fossa of the
femur.
Tibial Shaft
 The shaft of the tibia is prism-shaped, with three
borders and three surfaces; anterior, posterior and
lateral. For brevity, only the anatomically and
clinically important borders/surfaces are mentioned
here.
 Anterior border – palpable subcutaneously down the
anterior surface of the leg as the shin. The proximal
aspect of the anterior border is marked by the tibial
tuberosity; the attachment site for the patella
ligament.
 Posterior surface – marked by a ridge of bone known
as soleal line. This line is the site of origin for part of
the soleus muscle, and extends inferomedially,
eventually blending with the medial border of the
tibia. There is usually a nutrient artery proximal to
the soleal line.
 Lateral border – also known as the interosseous
border. It gives attachment to the interosseous
membrane that binds the tibia and the fibula
together.
Distal Tibia
 The distal end of the tibia widens to
assist with weight-bearing.
 The medial malleolus is a bony projection
continuing inferiorly on the medial aspect
of the tibia.
 It articulates with the tarsal bones to
form part of the ankle joint.
 On the posterior surface of the tibia,
there is a groove through which the
tendon of tibialis posterior passes.
 Laterally is the fibular notch, where the
fibula is bound to the tibia – forming the
distal tibiofibular joint.
The Fibula
Fibula
 The fibula is a bone located within the
lateral aspect of the leg. Its main function is
to act as an attachment for muscles, and
not as a weight-bearer.
 It has three main articulations:
 Proximal tibiofibular joint – articulates
with the lateral condyle of the tibia.
 Distal tibiofibular joint – articulates with
the fibular notch of the tibia.
 Ankle joint – articulates with the talus bone
of the foot.
 https://sketchfab.com/3d-
models/fibulafibula-
4976343a75af43cdb5573d653562e11d
Fibula
 Proximal
 At the proximal end, the fibula has an enlarged
head, which contains a facet for articulation with
the lateral condyle of the tibia. On the posterior
and lateral surface of the fibular neck, the common
fibular nerve can be found.
 Shaft
 The fibular shaft has three surfaces – anterior,
lateral and posterior. The leg is split into three
compartments, and each surface faces its
respective compartment e.g anterior surface faces
the anterior compartment of the leg.
 Distal
 Distally, the lateral surface continues inferiorly, and
is called the lateral malleolus. The lateral malleolus
is more prominent than the medial malleolus, and
can be palpated at the ankle on the lateral side of
the leg.
Bones of the Foot:
Tarsals, Metatarsals and
Phalanges
Bones of the Foot: Tarsals, Metatarsals
and Phalanges
 The bones of the foot provide mechanical support
for the soft tissues; helping the foot withstand the
weight of the body whilst standing and in motion.
 They can be divided into three groups:
 Tarsals – a set of seven irregularly shaped bones.
They are situated proximally in the foot in the ankle
area.
 Metatarsals – connect the phalanges to the tarsals.
There are five in number – one for each digit.
 Phalanges – the bones of the toes. Each toe has
three phalanges – proximal, intermediate, and distal
(except the big toe, which only has two phalanges).
 The foot can also be divided up into three regions:
(i) Hindfoot – talus and calcaneus; (ii) Midfoot –
navicular, cuboid, and cuneiforms; and (iii) Forefoot
– metatarsals and phalanges.
Tarsals

 The tarsal bones of the foot are
organised into three rows: proximal,
intermediate, and distal.
 Proximal Group
 The proximal tarsal bones are the
talus and the calcaneus. These comprise
the hindfoot, forming the bony
framework around the proximal ankle
and heel.
 https://sketchfab.com/3d-models/foot-
bones-
40e73f63fb0146f594f87239192494e4
Tarsals
 Talus
 The talus is the most superior of the tarsal bones. It
transmits the weight of the entire body to the foot. It has
three articulations:
 Superiorly – ankle joint – between the talus and the bones
of the leg (the tibia and fibula).
 Inferiorly – subtalar joint – between the talus and
calcaneus.
 Anteriorly – talonavicular joint – between the talus and
the navicular.
 The main function of the talus is to transmit forces from
the tibia to the heel bone (known as the calcaneus). It is
wider anteriorly compared to posteriorly which provides
additional stability to the ankle.
 Whilst numerous ligaments attach to the talus, no muscles
originate from or insert onto it. This means there is a high
risk of avascular necrosis as the vascular supply is
dependent on fascial structures.
Tarsals
 Calcaneus
 The calcaneus is the largest tarsal bone
and lies underneath the talus where it
constitutes the heel. It has two
articulations:
 Superiorly – subtalar (talocalcaneal) joint –
between the calcaneus and the talus.
 Anteriorly – calcaneocuboid joint –
between the calcaneus and the cuboid.
 It protrudes posteriorly and takes the
weight of the body as the heel hits the
ground when walking. The posterior aspect
of the calcaneus is marked by calcaneal
tuberosity, to which the Achilles tendon
attaches.
Tarsals
Intermediate Group
 The intermediate row of tarsal bones
contains one bone, the navicular (given
its name because it is shaped like a boat).
 Positioned medially, it articulates with the
talus posteriorly, all three cuneiform
bones anteriorly, and the cuboid bone
laterally.
 On the plantar surface of the navicular,
there is a tuberosity for the attachment
of part of the tibialis posterior tendon.
Tarsals
Distal Group
 In the distal row, there are four tarsal bones – the cuboid
and the three cuneiforms. These bones articulate with the
metatarsals of the foot
 The cuboid is furthest lateral, lying anterior to the
calcaneus and behind the fourth and fifth metatarsals. As its
name suggests, it is cuboidal in shape. The inferior (plantar)
surface of the cuboid is marked by a groove for the tendon
of fibularis longus.
 The three cuneiforms (lateral, intermediate (or middle)
and medial) are wedge shaped bones. They articulate with
the navicular posteriorly, and the metatarsals anteriorly.
The shape of the bones helps form a transverse arch across
the foot. They are also the attachment point for several
muscles:
 Medial cuneiform – tibialis anterior, (part of) tibialis
posterior, and fibularis longus
 Lateral cuneiform – flexor hallucis brevis
Metatarsals
 The metatarsals are located in the forefoot,
between the tarsals and phalanges. They are
numbered I-V (medial to lateral).
 Each metatarsal has a similar structure. They
are convex dorsally and consist of a head,
neck, shaft, and base (distal to proximal).
 They have three or four articulations:
 Proximally – tarsometatarsal joints – between
the metatarsal bases and the tarsal bones.
 Laterally – intermetatarsal joint(s) – between
the metatarsal and the adjacent metatarsals.
 Distally – metatarsophalangeal joint – between
the metatarsal head and the proximal phalanx.
Phalanges
 The phalanges are the bones of the toes. The
second to fifth toes all have proximal, middle,
and distal phalanges. The great toe has only 2;
proximal and distal phalanges.
 They are similar in structure to the metatarsals,
each phalanx consists of a base, shaft, and head.
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