Download The Structure of Bone

Document related concepts
no text concepts found
Transcript
6
The Skeletal
System
The Skeletal System
The skeletal system includes:
•
•
•
•
•
Bones
Cartilages
Joints
Ligaments
Other connective tissues
The Skeletal System
Functions of the Skeletal System
• Support against gravity
• Storage
• Calcium, Phosphorous
• Lipids(in yellow marrow)
• Blood cell production(in red marrow)
• Protection of soft internal organs
• Leverage for muscle action
The Structure of Bone
Bone (Osseous Tissue)
• Specialized cells (osteocytes)
• 2% of bone weight
• Strong flexible matrix
• Made of Calcium phosphate crystals
Ca3(PO4)2
• Account for two-thirds of bone weight
• Collagen fibers
The Structure of Bone
Macroscopic Features of Bone
• General shapes of bones:
• Long bones (e.g., humerus in arm)
• Short bones (e.g., carpal bones in wrist)
• Flat bones (e.g., parietal bone in skull)
• Irregular bones (e.g., vertebra in spine)
The Structure of Bone
Shapes of Bones
The Structure of Bone
Features of Long Bones:
• Diaphysis (shaft)
• Compact (dense) bone
• Marrow cavity
• Epiphyses (ends)
• Spongy (cancellous) bone
• Articular cartilage(on ends of bone)
• Periosteum (external covering)
• Endosteum (marrow lining)
The Structure of a Long Bone
The Structure of Bone
Microscopic Features of Bone:
• Periosteum
• Outer fibrous layer covering bones
• Osteocytes
• Both compact and spongy bone
contain osteocytes
• Found within lacunae (holes) in matrix
• Between lamellae (rings) in matrix
• Canaliculi are branches that allow
nutrients to be transmitted to bone cells
Structure of a Typical Bone
The Structure of Bone
Microscopic Features of Bone
• Osteon- The basic functional unit of
compact bone; columnar in shape
• Strong in long axis of bone
• Consists of concentric layers of osteocytes
(rings)
• Concentric layers of matrix between
osteocytes (lamellae)
• Central (Haversian) canal
• Vertical(axial) tunnel for blood vessels
• Perforating canal
• Radial(horizontal) tunnel for blood
vessels
Structure of a Typical Bone
The Structure of Bone
Microscopic Features of Spongy Bone:
• No osteons
• Lamellae form trabeculae
• Arches, rods, plates of bone
• Branching network of bony tissue
• Strong in many directions
• Red marrow (blood forming) spaces
Cells in Bone
• Osteocytes
• Mature bone cells between lamellae
• Osteoclasts
• Source of acid, enzymes for osteolysis
(breaking down bone)
• Regulate Calcium homeostasis
• Osteoblasts
• Responsible for osteogenesis (new bone)
• Source of collagen, calcium salts
Bone Formation and Growth
Endochondral Ossification
• Most bones formed this way
• Cartilage “model” replaced by bone
• Replacement begins in middle
(diaphysis)
• Replacement follows at ends
(epiphyses)
Bone Formation and Growth
Intramembranous Ossification:
• Ossification—Process of converting other
tissues to bone
• Forms flat bones of skull, mandible, clavicle
• Stem cells differentiate into osteoblasts
• Produces spongy bone, then compact bone
Bone Formation and Growth
Bone Formation in
16-Week-Old Fetus
General Steps in Bone Formation
Chondrocytes at
the center of the
growing cartilage
model enlarge
and then die as
the matrix
calicifies.
Newly derived
osteoblasts cover
the shaft of the
cartilage in a thin
layer of bone.
Blood vessels
penetrate the
cartilage. New
osteoblasts form a
primary ossification
center.
The bone of the
shaft thickens,
and the cartilage
near each
epiphysis is
replaced by shafts
of bone.
Blood vessels invade the
epiphyses and osteoblasts form secondary
centers of ossification.
Articular
cartilage
Enlarging
chondrocytes within
calcifying matrix
Epiphysis
Diaphysis
Epiphyseal
cartilage
Marrow
cavity
Primary
ossification
center
Bone
formation
Cartilage
model
Blood
vessel
Marrow
cavity
Blood
vessel
Secondary
ossification
center
Appositional Bone Growth
- Increasing the diameter of bone
Requirements for Normal Bone Growth
Minerals:
• Calcium, phosphate
• Vitamins:
• Vitamin D3
• Vitamin C
• Vitamin A
• Hormones:
• Growth Hormone(GH)
• Sex hormones, thyroid hormones
Bone Remodeling/Homeostasis
Role of Remodeling in Support:
• Remodeling—Continuous breakdown
and reforming of bone tissue
• Shapes reflect applied loads & stresses
• Mineral turnover enables adapting to
new stresses
Bone Remodeling/Homeostasis
Homeostasis and Mineral Storage:
• Bones store calcium
• Contain 99% of body's calcium
• Store up to 2 kg calcium
• Hormones control storage/release
• PTH, calcitriol release bone calcium
• Calcitonin stores bone calcium
• Blood levels kept constant through
blood cell formation in the marrow
Bone Remodeling/Homeostasis
Key Note:
With bone, What you don’t use,
you lose. The stresses applied
to bones during exercise are
essential to maintaining bone
strength and bone mass
Bone Remodeling/Homeostasis
Injury and Repair:
• Fracture—A crack or break in a bone
• Steps in fracture repair
1) Fracture hematoma(large blood clot)
2) An external callus is formed from
cartilage
An internal callus is formed from
spongy bone
3) Ossification of cartilage into bone
4) Bone remodeling
Immediately after the fracture,
extensive bleeding occurs. Over
a period of several hours, a large
blood clot, or fracture hematoma,
develops.
Bone
fragments
An internal callus forms as a
network of spongy bone
unites the inner edges, and
an external callus of cartilage
and bone stabilizes the outer
edges.
Spongy bone Cartilage
of internal of external
callus
callus
The cartilage of the
external callus has been
replaced by bone, and
struts of spongy bone
now unite the broken
ends. Fragments of dead
bone and the areas of
bone closest to the break
have been removed and
replaced.
External
callus
Fracture
hematoma
Dead
bone
A swelling initially
marks the location of
the fracture. Over time,
this region will be
remodeled, and little
evidence of the
fracture will remain.
New
bone
Periosteum
Internal
callus
External
callus
Aging and the Skeletal System
Osteopenia—Less than normal
ossification (mineral content) in bone
• Osteopenia starts before age 40
• Women lose 8% per decade
• Men lose 3% per decade
• Spongy bone most affected
• Epiphyses(ends of bone)
• Vertebrae
• Jaws
An Overview of the Skeleton
Surface Features of Bones
Surface Features of Bones
An Overview of the Skeleton
Skeletal Divisions
• Axial skeleton
• Skull
• Thoracic cage and sternum
• Vertebral column
• Appendicular skeleton
• Upper, lower limbs
• Pectoral girdle
• Pelvic girdle
The Skeleton
The Skeleton
Axial and Appendicular Divisions
The Skull
Bones of the Cranium
• Frontal bone
• Forehead, superior surface of orbits
• Parietal bones
• Top, rear
• Occipital bone
• Lower, rear
• Temporal bones
• Sides, base
The Skull
Bones of the Cranium (continued)
• Sphenoid bone
• Bridge between cranial and facial
bones (temple)
• Ethmoid bone
• Back of eye socket
Bones of the Face
• Maxillary bones
• Zygomatic bones
• Zygomatic arch (cheek bones)
• Mandible (jaw)
• Nasal bone
The Adult Skull (side view)
The Adult Skull (frontal view)
The Adult Skull (Inferior View)
Sectional Anatomy of the Skull
Sectional Anatomy of the Skull
Sectional Anatomy of the Skull
The Paranasal Sinuses
The Hyoid Bone
The Skull of a Newborn
The Skull of a Newborn
Vertebral Column
Vertebral Column (Spine)
• 26 Bones
• 7 Cervical vertebrae (C1 to C7)
• 12 Thoracic vertebrae (T1 to T12)
• 5 Lumbar vertebrae (L1 to L5)
• Sacrum
• Coccyx (tailbone)
Vertebral Column/Thoracic Cage
Spinal Curvature
• Due to alignment of body weight
• Primary curves- appear late in
fetal development
• Thoracic(back)
• Sacral(tail bone)
• Secondary curves- do not appear
until months after birth
• Cervical(neck)
• Lumbar(lower back)
Vertebral Column
Vertebrae Anatomy
Vertebral Column
Regional Differences in Vertebrae
• Cervical
• Oval body
• Transverse foramina
• Thoracic
• Heart-shaped body
• Lumbar
• Massive (heaviest loading)
• Blade-like transverse processes
Cervical Vertebra
Thoracic Vertebra
Lumbar Vertebra
The Atlas and Axis
Functions of the Sacrum
• Protects pelvic organs
• Base articulates with
lumbar vertebra
• Apex articulates with
coccyx
The Sacrum and Coccyx
The Sacrum and Coccyx
The Thoracic Cage
Components of Thoracic Cage
• Thoracic vertebrae
• Ribs
• Seven pairs of true ribs
• Cartilaginous joint with sternum
• Five pairs of false ribs
• Sternum
• Manubrium, body, xiphoid process
The Thoracic Cage
The Thoracic Cage
The Appendicular Skeleton
Pectoral Girdle (Shoulder Girdle)
• Components
• Scapulae (“shoulder blade”)
• Coracoid process
• Acromium
• Scapular spine
• Clavicles (“collar bone”)
• Functions
• Shoulder, arm movement
• Articulation for arm
Appendicular Division
The Clavicle
Appendicular Division
The Scapula
Appendicular Division
Upper Limbs
• Humerus (upper arm)
• Head(upper end) articulates with scapula
• Muscles attach to points along humerus
• Greater, lesser tubercles
• Deltoid tuberosity
• Medial, lateral epicondyles
• Distal condyle articulates with forearm
The Humerus
Appendicular Division
Bones of the Forearm:
• Radius
• Lateral (thumb side)
• Head articulates with humerus
• Radial tuberosity attaches biceps
• Participates in wrist joint
• Ulna
• Outer forearm (“pinky” side)
• Trochlear notch articulates with humerus
• Olecranon forms point of elbow
The Radius and Ulna
Appendicular Division
Bones of the Wrist and Hand:
• Two rows of carpal bones
• Proximal articulation with radius
• Distal articulation with metacarpal bones
• Proximal phalanges (finger bones)
articulate with metacarpals
• Three phalanges/finger
• Two phalanges/thumb (pollex)
Bones of the Wrist and Hand
Appendicular Division
The Pelvic Girdle
• Formed by two coxae (hipbones)
• Coxa formed by fusion of:
• Ilium
• Ischium
• Pubis
• Pubic symphysis(fusion at base)
limits movement
• Pelvis formed by coxae, sacrum,
coccyx
The Pelvis
Copyright © 2007 Pearson Education, Inc., publishing as Benjamin Cummings
The Pelvis
The Pelvis
Differences in the Anatomy of the Pelvis
Appendicular Division
Bones of the Lower Limb(legs):
•
•
•
•
•
•
Femur (thighbone)
Patella (kneecap)
Tibia (shinbone)
Fibula
Ankle bones
Foot bones
The Femur
The Right Tibia and Fibula
Appendicular Division
The Bones of the Ankle and Foot:
• Ankle
• Seven tarsal bones
• Talus
Joint with tibia, fibula
• Foot
• Calcaneus (heel bone)
• Major load-bearing bone
• Metatarsal bones
• Five phalanges (toes)
Bones of the Ankle and Foot
Bones of the Ankle and Foot
Articulations & Joints
Classification of Joints (Articulations)
• Joint—Where two bones interact
• Three functional classes of joint
• Synarthroses
• Immovable
• Amphiarthroses
• Slightly movable
• Diarthroses
• Freely movable
Articulations
Synovial Joints (Diarthroses)- freely
moveable
•
•
•
•
Ends covered by articular cartilage
Lubricated by synovial fluid
Enclosed within joint capsule
Other synovial structures include:
• Menisci
• Bursae
• Fat pads
• Ligaments
The Structure of Synovial Joints
The Structure of Synovial Joints
Articulations
Synovial Joints: Movements
• Flexion- reduces angle at joint
• Extension- increases angle at joint
• Hyperextension- extension past
anatomical position
• Abduction- movement away from body
• Adduction- movement towards body
• Circumduction- circular motion
• Rotation- pivot
• Pronation(face down), supination(face up)
Angular Movements
Angular Movements
Angular Movements
Angular Movements
Rotational Movements
Rotational Movements
Articulations
Special Movements
• Foot and ankle
• Inversion(inward),
Eversion(outward)
• Dorsiflexion(Up),
Plantar flexion(Down)
• Hand
• Opposition of thumb, palm
• Head
• Protraction(foreward),
Retraction(reverse)
• Depression, elevation (jaw)
Special Movements
Structural Classification of Synovial Joints
•
•
•
•
•
•
Gliding (e.g., vertebra–vertebra)
Hinge (e.g., knee)
Pivot (e.g., atlas–axis)
Ellipsoidal (e.g., distal radius)
Saddle (e.g., thumb)
Ball-and-Socket (e.g., hip)
Intervertebral Articulations
• Two kinds join adjacent vertebrae
• Gliding joints
• Between superior and inferior
articular processes
• Permit small movements
• Symphyseal joints
• Intervertebral discs composed of
fibrocartilage
• Cushion and connect
Intervertebral Articulations
Gliding Joint
Hinge Joint
The Elbow Joint
The Knee Joint
Pivot Joint
Ellipsoidal Joint
Saddle Joint
Ball & Socket Joint
The Shoulder Joint
The Hip Joint
Articulations
Key Note:
A joint cannot be both highly mobile and
very strong. The greater the mobility,
the weaker the joint, because mobile
joints rely on support from muscles and
ligaments rather than solid bone-tobone connections.