Chapter+7+.ppt

Full Transcript

Chapter 7: Bone Structure &
Function

7-1
 Tissues and Organs
of the Skeletal System
Osteology—the study of bone
Skeletal system—composed of bones,
cartilages, and ligaments
– Form strong, flexible framework of the body
– Cartilage—forerunner of most bones
Covers many joint surfaces of mature bone
Ligaments—hold bones together at the joints
Tendons—attach muscle to bone
– Aponeurosis is a thin flatten sheet of dense regular CT

7-2
 Functions of the Skeleton
Support—holds up the body, supports muscles,
mandible and maxilla support teeth
Protection—brain, spinal cord, heart, lungs
Movement—limb movements, breathing, action of
muscle on bone
Electrolyte balance—calcium and phosphate
ions
Acid–base balance—buffers blood against
excessive pH changes
Blood formation—red bone marrow is the chief
producer of blood cells
7-3
 Bones and Osseous Tissue
Bone (osseous tissue)—connective tissue with
the matrix hardened by calcium phosphate and
other minerals
Mineralization or calcification—the hardening
process of bone
Individual bones consist of bone tissue, bone
marrow, cartilage, adipose tissue, nervous tissue,
and fibrous connective tissue
Continually remodels itself and interacts
physiologically with all of the other organ systems
of the body
Permeated with nerves and blood vessels, which
attests to its sensitivity and metabolic activity
7-4
 General Features of Bones
Flat bones
– Protect soft organs
– Curved but wide and thin
Long bones
– Longer than wide
– Rigid levers acted upon by
muscles
Short bones
– Equal in length and width
– Glide across one another in
multiple directions
Irregular bones
– Elaborate shapes that do not
fit into other categories
7-5
 General Features of Bones
Compact (dense) bone—outer shell of long bone
Diaphysis (shaft)—cylinder of compact bone to provide
leverage
Medullary cavity (marrow cavity)—space in the
diaphysis of a long bone that contains bone marrow
Epiphyses—enlarged ends of a long bone
– Enlarged to strengthen joint and attach ligaments and tendons
Metaphysis—between diaphysis and epiphysis
Spongy (cancellous) bone—covered by more durable
compact bone
– Skeleton three-fourths compact and one-fourth spongy bone by
weight
– Spongy bone in ends of long bones, and middle of nearly all
others
7-6
 General Features of Bones

Articular cartilage—layer
of hyaline cartilage that
covers the joint surface
where one bone meets
another; allows joint to
move more freely and
relatively friction free
Nutrient foramina—minute
holes in the bone surface
that allows blood vessels to
penetrate

7-7
 General Features of Bones
Periosteum—external sheath that
covers bone except where there is
articular cartilage
– Outer fibrous layer of dense
irregular CT
Some outer fibers continuous with the
tendons that attach muscle to bone
Perforating fibers—other outer
fibers that penetrate into the bone
matrix
Strong attachment and continuity
from muscle to tendon to bone
– Inner osteogenic layer of bone-
forming cells
Important to growth of bone and
healing of fractures
Includes osteoprogenitor cells,
osteoblasts, osteoclasts 7-8
 General Features of Bones
Endosteum—thin layer of
reticular connective tissue lining
marrow cavity
– Has cells that dissolve osseous
tissue and others that deposit it

Epiphyseal plate (growth
plate)—area of hyaline
cartilage that separates the
marrow spaces of the epiphysis
and diaphysis
– Enables growth in length
– Epiphyseal line—in adults, a bony
scar that marks where growth plate
used to be
7-9
General Features of Bones

Sandwich-like construction
Two layers of compact
bone enclosing a middle
layer of spongy bone
– Both surfaces of flat bone
covered with periosteum
Diploe—spongy layer in
the cranium
– Absorbs shock
– Marrow spaces lined with
endosteum

7-10
 Bone Cells

Bone is connective tissue that consists of cells, fibers, and
ground substance

Four principal types of bone cells
– Osteoprogenitor cells; osteoblasts; osteocytes;
7-11
osteoclasts
 Bone Cells
Osteoprogenitor cells—stem cells found in endosteum,
periosteum, and in central canals
– Arise from embryonic mesenchymal cells; multiply
continuously to produce new osteoblasts
– Located in periosteum and endosteum
Osteoblasts—bone-forming cells
– Line up as single layer of cells under endosteum and
periosteum
– Forms osteoid-semisolid bone matrix
– Nonmitotic
– Synthesize soft organic matter of matrix which then hardens
by mineral deposition
– Become entrapped within the matrix

7-12
 Bone Cells
Osteocytes—former osteoblasts that have
become trapped in the matrix they have
deposited
– Lacunae—tiny cavities where osteocytes
reside
– Canaliculi—little channels that connect
lacunae
– Cytoplasmic processes reach into canaliculi
– Maintain the bone matrix by signaling
osteoblast
– When stressed, produce biochemical signals
that regulate bone remodeling
– Contribute to homeostatic mechanism of bone
density and calcium and phosphate ions

7-13
 Bone Cells
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Osteocyte
Osteoclast Osseous
tissue
Stem cells Periosteum Resorption
bay
Nuclei
Osteoclast
Fusion

Ruffled
Lysosomes
border

(b) Osteoclast development

Osteoclasts—bone-dissolving cells found on the bone
surface
– Osteoclasts develop from same bone marrow stem cells that
give rise to blood cells
– Different origin from rest of bone cells
– Unusually large cells formed from the fusion of several stem
cells
Typically have 3 to 4 nuclei, may have up to 50
7-14
 Bone Cells

– Ruffled border—side facing bone surface
Several deep infoldings of the plasma membrane
which increases surface area and resorption
efficiency
– Resorption bays—pits on surface of bone where
osteoclasts reside
– Remodeling—results from combined action of the
bone-dissolving osteoclasts and the bone-
depositing osteoblasts

7-15
 The Matrix
Matrix of osseous tissue is, by dry weight, about one-
third organic and two-thirds inorganic matter
Organic matter—synthesized by osteoblasts
– Collagen, carbohydrate–protein complexes, such as
glycosaminoglycans, proteoglycans, and glycoproteins
– Provides strength by resisting stretching
Inorganic matter
– 85% hydroxyapatite (crystallized calcium phosphate salt)
– 10% calcium carbonate
– Other minerals (fluoride, sodium, potassium, magnesium)
– Harden matrix

7-16
 Histology of Osseous Tissue
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Bone marrow T

Pelvic bone
Head of
femur

Spongy bone

Compact bone

(a)

(c)

Lamella

Lacunae

Canaliculi
Central
canal

(d)
20 m
7-17
a,c: © Dr. Don W. Fawcett/Visuals Unlimited; d: Visuals Unlimited
Histology of Osseous Tissue
Perforating (Volkmann)
canals
– Perpendicular to central
canals
Central canals
– vertical canals
Concentric lamellae
– surround central canal
Circumferential
lamellae
– Rings of bone on entire
bone
Internal & external
Interstitial lamellae
– Between osteons
– Usually old fragments
 Spongy Bone
Spongelike appearance
Spongy bone consists of:
– Slivers of bone called spicules
– Thin plates of bone called trabeculae
– Spaces filled with red bone marrow

No osteons
– All osteocytes close to bone marrow

Provides strength with minimal weight
– Trabeculae develop along bone’s lines
of stress

7-19
Bone Marrow

Bone marrow—general term
for soft tissue that occupies
the marrow cavity of a long
bone and small spaces amid
the trabeculae of spongy bone

7-20
 Bone Marrow
Red marrow (myeloid tissue)
– In nearly every bone in a child
– Hemopoietic tissue—produces blood cells and is
composed of multiple tissues in a delicate, but
intricate arrangement that is an organ to itself
– In adults, found in skull, vertebrae, ribs, sternum,
part of pelvic girdle, and proximal heads of
humerus and femur
Yellow marrow found in adults
– Most red marrow turns into fatty yellow marrow
– No longer produces blood

7-21
 Bone Development

Ossification or osteogenesis—the formation
of bone

In the human fetus and infant, bone develops
by two methods
– Intramembranous ossification
– Endochondral ossification

7-22
 Intramembranous Ossification Figure 7.10

Produces flat bones of skull, clavicle, mandible
Endochondral Ossification

7-24
 Endochondral Ossification
During infancy and childhood, the epiphyses fill with spongy
bone
Cartilage limited to the articular cartilage covering each
joint surface, and to the epiphyseal plate
– A thin wall of cartilage separating the primary and secondary
marrow cavities
– Epiphyseal plate persists through childhood and adolescence
By late teens to early 20s, all remaining cartilage in the
epiphyseal plate is ossified
– Gap between epiphyses and diaphysis closes
– Bone can no longer grow in length

7-25
The Fetal Skeleton at 12 Weeks
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Cranial
bones

Mandible

Humerus Vertebrae

Radius
Ulna
Scapula
Ribs

Femur

Pelvis 7-26
© Biophoto Associates/Photo Researchers, Inc.
 Bone Elongation
Epiphyseal plate—a region of transition from
cartilage to bone
– Functions as growth zone where the bones
elongate
– Consists of typical hyaline cartilage in the middle
– With a transition zone on each side where
cartilage is being replaced by bone
– Metaphysis is the zone of transition facing the
marrow cavity
Interstitial growth—bones increase in length
– Epiphyses close when cartilage is gone—epiphyseal
line
7-27
 Zones of the Metaphysis
Zone 1
Zone 5

Zone of resting cartilage
1
Typical histology of resting
hyaline cartilage; secures epiphysis to
epiphyseal place
2 Zone of cell proliferation
Multiplying Chondrocytes multiplying and
chondrocytes lining up in rows of small
flattened lacunae
Enlarging
chondrocytes 3 Zone of cell hypertrophy
Cessation of mitosis;
enlargement of chondrocytes
and thinning of lacuna walls
Breakdown
of lacunae 4 Zone of calcification
Temporary calcification of
cartilage matrix between
Calcifying columns of lacunae
cartilage

5 Zone of bone deposition
Bone Breakdown of lacuna walls,
marrow leaving open channels; death
of chondrocytes; bone
deposition by osteoblasts,
Osteoblasts forming trabeculae of spongy
bone
Osteocytes

Trabeculae of
spongy bone Victor Eroschenko 7-28
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
 Bone Widening and Thickening
Appositional growth—
bones increase in width
throughout life
– Deposition of new bone at the
surface
– Osteoblasts on deep side of
periosteum deposit osteoid
tissue
Become trapped as tissue
calcifies
– Lay down matrix in layers
parallel to surface
Forms circumferential
lamellae over surface
– Osteoclasts of endosteum
enlarge marrow cavity
7-29
 Bone Remodeling
Bone remodeling occurs throughout life—10% per
year
– Repairs microfractures, releases minerals into blood,
reshapes bones in response to use and disuse
– Wolff’s law of bone: architecture of bone determined by
mechanical stresses placed on it and bones adapt to
withstand those stresses
Remodeling is a collaborative and precise action of
osteoblasts and osteoclasts
Bony processes grow larger in response to mechanical stress

7-30
 Calcium Homeostasis

Calcium homeostasis depends on a balance
between dietary intake, urinary and fecal losses, and
exchanges between osseous tissue
Calcium is required for
– Initiation of muscle contraction
– Exocytosis of molecules from cells, including neurons
– Stimulation of the heart by pacemaker cells
– Blood clotting
Calcium homeostasis is regulated by three hormones:
– Calcitriol, calcitonin, and parathyroid hormone

7-31
 Calcitriol Synthesis and Action
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

7-dehydrocholesterol

Ultraviolet
light
HO

Vitamin D3
(cholecalciferol)

CH2

HO
Bone
resorption
Calcidiol
Reduced
excretion
OH of Ca2+
CH2

Calcitriol

HO OH Absorption
of Ca2+ and
CH2 phosphate

HO
OH

7-32
 Calcitriol
Calcitriol—a form of vitamin D produced by the
sequential action of the skin, liver, and kidneys
Calcitriol behaves as a hormone that raises blood
calcium concentration
– Increases calcium absorption by small intestine
– Increases calcium resorption from the skeleton
– Promotes kidney reabsorption of calcium ions, so less lost
in urine
Necessary for bone deposition—need adequate
calcium and phosphate
Abnormal softness of bones in children (rickets) and
in adults (osteomalacia) without adequate vitamin D
7-33
 Calcitonin
Calcitonin—secreted by C cells (clear cells) of
the thyroid gland when calcium concentration
rises too high
Lowers blood calcium concentration in two ways
– Osteoclast inhibition
Reduces osteoclast activity as much as 70%
Less calcium liberated from bones
– Osteoblast stimulation
Increases the number and activity of osteoblasts
Deposits calcium into the skeleton

7-34
 Calcium Homeostasis
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Blood Ca2+ Blood Ca2+
excess returns to
normal

Calcitonin
secretion

Reduced
Less bone
osteoclast
resorption
activity

Increased
More bone
osteoblast
deposition
activity
7-35
(a) Correction for hypercalcemia
 Parathyroid Hormone
Parathyroid hormone (PTH)—secreted by the
parathyroid glands which adhere to the posterior
surface of thyroid gland
PTH released with low calcium blood levels
PTH raises calcium blood level by four mechanisms
– Binds to receptors on osteoblasts
Simulating them to secrete RANKL which raises the
osteoclast population
– Promotes calcium reabsorption by the kidneys, less lost in
urine
– Promotes the final step of calcitriol synthesis in the kidneys,
enhancing calcium-raising effect of calcitriol
– Inhibits collagen synthesis by osteoblasts, inhibiting bone
deposition

7-36
 Calcium Homeostasis
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Blood Ca2+ Blood Ca2+
deficiency returns to
normal

Parathyroid
hormone
secretion

Increased
More bone
osteoclast
resorption
activity

Reduced
Less bone
osteoblast
deposition
activity

More urinary Prevention of
phosphate hydroxyapatite
excretion formation

Less urinary Conservation
calcium of calcium
excretion 7-37
(b) Correction for hypocalcemia
 Factors Affecting Bone
At least 20 or more hormones, vitamins, and
growth factors affect osseous tissue
Bone growth especially rapid in puberty and
adolescence
– Surges of growth hormone, estrogen, and testosterone
occur and promote ossification
– These hormones stimulate multiplication of osteogenic
cells, matrix deposition by osteoblasts, and chondrocyte
multiplication and hypertrophy in metaphyses
– Girls grow faster than boys and reach full height earlier
Estrogen stronger effect than testosterone on bone growth
– Males grow for a longer time and taller

7-38
Factors Affecting Bone

7-39
 Fractures and Their Repair
Stress fracture—thin break caused by abnormal
trauma to a bone
– Falls, athletics, and military combat

Pathological fracture—break in a bone weakened by
disease
– Bone cancer or osteoporosis
Fractures classified by structural characteristics
– Direction of fracture line
– Break in the skin
– Multiple pieces

7-40
Types of Bone Fractures

7-41
 Healing of Fractures

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

Marrow
cavity
Fibrocartilage
Hard
callus
Hematoma Soft callus Spongy
bone

New blood
vessels

Compact bone

1 Hematoma formation 2 Soft callus formation 3 Hard callus formation 4 Bone remodeling
The hematoma is converted Deposition of collagen and Osteoblasts deposit a temporary Small bone fragments are
to granulation tissue by invasion fibrocartilage converts granulation bony collar around the fracture to removed by osteoclasts, while
of cells and blood capillaries. tissue to a soft callus. unite the broken pieces while osteoblasts deposit spongy
ossification occurs. bone and then convert it to
compact bone.

Figure 7.18
7-42
 Bone Disorders
Osteoporosis—the most
common bone disease
– Severe loss of bone density
Bones lose mass and
become brittle due to loss
of organic matrix and
minerals
– Subject to pathological
fractures of hip, wrist, and
vertebral column
– Kyphosis (widow’s hump)
—deformity of spine due to
vertebral bone loss

7-43
 Osteoporosis
Estrogen maintains density in both sexes; inhibits resorption by
osteoclasts
– Testes and adrenals produce estrogen in men
– In women, rapid bone loss after menopause
Osteoporosis is common in young female athletes with low body
fat causing them to stop ovulating and ovarian estrogen
secretion is low
Treatments
– Estrogen replacement therapy (ERT) slows bone
resorption, but increases risk of breast cancer, stroke, and
heart disease
Drugs Fosamax, Actonel destroy osteoclasts
– PTH slows bone loss if given as daily injection
Forteo (PTH derivative) increases density by 10% in 1
year; promotes bone growth
– May promote bone cancer so use is limited to 2 years
– Best treatment is prevention: exercise and a good bone-
building diet