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Chapter 6: Osseous Tissue and Bone Structure

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Title: Chapter 6: Osseous Tissue and Bone Structure


1
Chapter 6 Osseous Tissue and Bone Structure
2
The Skeletal System
  • Skeletal system includes
  • bones of the skeleton
  • cartilages, ligaments, and other connective
    tissues that stabilize the bones

3
Skeletal System
  • Functions
  • 1. Support framework structure of body
  • 2. Storage of minerals and lipids
  • Minerals calcium and phosphate
  • - for osmotic regulation, enzyme
    function,
  • nerve impulses
  • Yellow marrow triglycerides
  • 3. Blood cell production all formed elements
  • - red marrow stem cells ? hematopiesis
  • 4. Protection surround soft tissues
  • 5. Leverage for movement
  • - levers upon which skeletal muscles act

4
Classification of Bones
  • Bone are identified by
  • shape
  • internal tissues
  • bone markings
  • SHAPE
  • Long bones
  • Flat bones
  • Sutural bones
  • Irregular bones
  • Short bones
  • Sesamoid bones

5
Shape of Bones
  • Long Bones
  • Longer than wide, consist of shaft and 2 ends
  • e.g. bones of appendages
  • Short Bones
  • Approx. equal in all dimensions
  • e.g. carpals, tarsals
  • Flat Bones
  • Thin, 2 parallel surfaces
  • e.g. skull, sternum, ribs, scapula

Figure 61a
6
Shape of Bones
  • Irregular Bones
  • Complex shapes
  • E.g. vertebrae, os coxa
  • Sesamoid Bones
  • Seed shaped, form in tendon
  • E.g. patella, total number can vary
  • Sutural Bones
  • - Extra bones in sutures of skull

7
Bone Structure
  • A bone is an organ consisting of many tissue
    types
  • Osseous, nervous, cartilage, fibrous CT, blood,
    etc.
  • All bones consist of 2 types of bone tissue
  • Compact bone
  • - solid, dense bone, makes up surfaces and
    shafts
  • Spongy Bone/Cancellous bone
  • - meshy, makes up interior of bones, houses red
    marrow in spaces

8
Bone Markings
  • Bones are not flat on the surface
  • Have projections, depressions, and holes for
    muscle attachment, blood nerve supply
  • Depressions or grooves
  • along bone surface
  • Projections
  • where tendons and ligaments attach
  • at articulations with other bones
  • Tunnels
  • where blood and nerves enter bone

9
Bone Markings
Table 61 (2 of 2)
10
Long Bones Structure
  • Diaphysis
  • - Hollow shaft of compact bone
  • Medullary (marrow) cavity
  • Center of diaphysis, contains yellow marrow
  • Triglycerides for energy reserve
  • Epiphysis
  • Expanded end of bone, surface of compact bone
  • Center filled with spongy bone with red marrow in
    spaces
  • Produces blood cells

Figure 62a
11
Long Bones Structure
  • Epiphyseal line or plate
  • Cartilage that marks connection of diaphysis with
    epiphysis
  • Line adults, narrow (aka metaphysis)
  • Plate thick, allows growth during childhood
  • Periosteum
  • 2 layer covering around outside of bone
  • Outer Fibrous Layer
  • Inner Cellular Layer
  • Endosteum
  • Cellular layers, covers all inside surfaces

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13
  • Articular Cartilage
  • Hyaline cartilage on end where bone contacts
    another, no periosteum or perichondrium
  • Joint/Articulation
  • - connection between two bones, surrounded by
    CT capsule, lined with synovial membrane
  • Joint cavity filled with synovial fluid to reduce
    friction on articular cartilage

14
Flat Bone Structure
  • Thin layer of spongy bone with red marrow between
    two layers of compact bone
  • Covered by periosteum and endosteum
  • Site of most hematopoiesis
  • Production of blood cells and cell fragments that
    are suspended in plasma (RBC, WBC, and platelets

15
Characteristics of Bone Tissue
  • Periosteum
  • covers outer surfaces of bones
  • consist of outer fibrous and inner cellular
    layers
  • Endosteum
  • Inner, cellular layer of periosteum

16
Bone Histology
  • Bone osseous tissue, supporting CT
  • Consists of specialized cells in a matrix of
    fibers and ground substance
  • Characteristics of bone
  • Dense matrix packed with calcium salts
  • Osteocytes in lacunae
  • Canaliculi for exchange of nutrients and waste
  • Two layer periosteum, covers bone except at
    articular surfaces

17
Bone Histology
  • Matrix 98 of bone tissue
  • 1/3 osteoid organic part
  • Collagen fibers ground substance
  • Tough and flexible
  • 2/3 densely packed crystals of hydroxyapatite
    (calcium salts, mostly calcium phosphate)
  • Hard but brittle
  • Cells only 2 of bone
  • Osteocytes
  • Osteoblasts
  • Osteoprogenitor cells
  • Osteoclasts

18
Cells located in Bones
  • Osteocytes mature bone cells
  • -no cell division
  • -located in lacunae between layers of matrix
    called lamellae
  • -canaliculi link lacunae to each other and blood
    supply
  • -osteocytes linked to each other via gap
    junctions on cell projections in canaliculi
  • - allow exchange of nutrients and wastes
  • -Function
  • 1. To maintain protein and mineral content of
    matrix
  • 2. Can also participate in bone repair
  • -become stem cell like when broken free of
    lacuna

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20
Cells located in Bones
  • Osteoblasts - Immature bone cells
  • Perform osteogenesis
  • Formation of new bone matrix
  • Produce osteoid
  • Organic components of matrix that is not yet
    calcified to form bone
  • Promote deposit of calcium salts which
    spontaneously form hydroxyapatite
  • Once enclosed in lacuna by matrix, osteoblast
    differentiates into osteocyte and no longer
    produces new matrix

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22
Cells located in Bones
  • 3. Osteoprogenitor Cells mesenchymal cells
  • - bone stem cell that produces daughters
  • - daughters become osteoblasts for repair
    and growth
  • - located in endosteum and inner periosteum

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24
Cells located in Bones
  • 4. Osteoclasts
  • - large, multinuclear
  • - derived from monocytes (macrophages)
  • - perform osteolysis
  • - digest and dissolve bone matrix
  • - release minerals
  • 1. For use in blood or
  • 2. Recycling during bone remodeling

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26
Cells located in Bones
27
Homeostasis
  • Bone building (by osteocytes) and bone recycling
    (by osteoclasts) must balance
  • more breakdown than building, bones become weak
  • exercise causes osteocytes to build bone

28
How would the strength of a bone be affected if
the ratio of collagen to hydroxyapatite increased?
  • Strength increases, flexibility increases.
  • Strength increases, flexibility decreases.
  • Strength decreases, flexibility. decreases.
  • Strength decreases, flexibility increases.

29
If the activity of osteoclasts exceeds the
activity of osteoblasts in a bone, how will the
mass of the bone be affected?
  • stable mass, but re-positioned matrix
  • mass will not be affected
  • more mass
  • less mass

30
The difference between compact bone and spongy
bone.
31
Structure of Compact Bone
  • Consists of osteons
  • Parallel to surface
  • Each osteon is around a central canal
  • Contains blood vessels and nerves
  • Perforating canals perpendicular to osteons act
    to connect the osteons
  • Osteon is built of layers of matrix secreted by
    osteoblasts
  • Each layer concentric lamella
  • Osteocytes are located in lacunae between
    lamellae
  • Ostocytes are connected to neighboring cells and
    central canal via canaliculi

32
Structure of Compact Bone
  • Interstitial lamellae fill spaces between osteons
  • Circumferiential lamellae run perimeter inside
    and out in contact with
  • endosteum and periosteum
  • Compact bone is designed to receive stress from
    one direction
  • Very strong parallel to osteons
  • Weak perpendicular to osteons

33
Compact Bone
Figure 65
34
Structure of Spongy Bone
  • Lamellae meshwork called trabeculae (no
    osteons)
  • Red marrow fills spaces around trabeculae
  • Osteocytes in lacunae are linked by canaliculi
  • No direct blood supply (no central canals)
  • Nutrients diffuse into canaliculi in trabeculae
    from red marrow
  • Spongy bone make up
  • low stress bones
  • Areas of bone where stress comes from multiple
    directions
  • Provide light weigh strength

35
Bone Marrow
  • Red Marrow
  • Located in space between trabeculae
  • Has blood vessels
  • Forms red blood cells
  • Supplies nutrients to osteocytes
  • Yellow Marrow
  • In some bones, spongy bone holds yellow bone
    marrow
  • is yellow because it stores fat

36
Structure of Spongy Bone
37
Periosteum and Endosteum
  • Compact bone is covered with membrane
  • periosteum on the outside
  • endosteum on the inside

38
Periosteum
  • Fibrous outer layer
  • - Dense irregular CT
  • Cellular Inner layer
  • Osteoprogenitor cells
  • Functions
  • Isolate bone from surrounding tissues
  • Site for attachment for tendons and ligaments
  • Route for nerves and blood vessels to enter bone
  • Participates in bone growth and repair

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40
Endosteum
  • Thin cellular layer
  • Lines medullary cavity, central canals, and
    covers trabeculae
  • Consists of
  • osteoblasts, osteoprogenitor cells, and
    osteoclasts
  • Cells become active during bone growth and repair

41
Endosteum
Figure 68b
42
Bone Growth
  • Begins 6-8 weeks post fertilization
  • Continues through puberty (18-25 y)
  • Osteogenesis ossification formation of bone
  • Not calcification
  • Hardening of matrix or cytoplasm with calcium
  • Can happen to many tissues
  • Two types of Ossification
  • Intramembranous forms flat bones
  • Endochondrial forms long bones

43
Bone Development
  • Human bones grow until about age 25
  • Osteogenesis
  • bone formation
  • Ossification Deposition of calcium salts
  • the process of replacing other tissues with bone

44
The difference between intramembranous
ossification and endochondral ossification.
45
Intramembranous Ossification
  • Bone develops from mesenchyme or fibrous CT in
    deep layers of dermis
  • Also called dermal ossification
  • because it occurs in the dermis
  • produces dermal bones such as mandible and
    clavicle
  • Produces skull bones
  • There are 4 main steps in intramembranous
    ossification

46
Intramembranous Ossification Step 1
  • Ossification center appears in the fibrous CT
    membrane
  • Mesenchymal cells aggregate
  • Differentiate into osteoblasts
  • Begin ossification at the ossification center

47
Intramembranous Ossification Step 2
  • Bone matrix (osteoid) is secreted within the
    fibrous membrane
  • Osteoblasts begin to secrete osteoid, which is
    mineralized within a few days
  • Trapped osteoblasts become osteocytes

48
Intramembranous Ossification Step 3
  • Woven bone and periosteum form
  • Accumulating osteoid is laid down between
    embryonic blood vessels, which form a random
    network
  • Vascularized mesenchyme condenses on the external
    face of the woven bone and becomes periosteum
    around spongy bone

49
Intramembranous Ossification Step 4
  • Bone collar of compact bone forms and red marrow
    appears
  • Trabeculae just deep to the periosteum thickens,
    forming a woven bone collar that is later
    replaced with mature lamellar bone
  • Spongy bone, consisting of distinct trabeculae,
    persists internally and its vascular tissue
    becomes red marrow

50
Endochondral Ossification
  • Ossifies bones that originate as hyaline
    cartilage
  • Most bones originate as hyaline cartilage
  • Cartilage grows by interstitial and appositional
    growth
  • Cartilage is slowly replaced from the inside out

51
Endochondral Ossification
  • Growth and ossification of long bones occurs in 6
    steps

52
Endochondral Ossification Step 1
  • Primary ossification center begins to form
  • Chondrocytes in the center of hyaline cartilage
  • Enlarge in diaphysis
  • Surrounding matrix calcifies killing the enclosed
    chondrocytes
  • die, leaving cavities in cartilage

Figure 69 (Step 1)
53
Endochondral Ossification Step 2
  • Blood vessels grow around the edges of the
    cartilage
  • Cells in the perichondrium change to osteoblasts
  • Secrete osteoid
  • Osteiod is mineralized and produces a layer of
    superficial bone around the shaft which will
    continue to grow around the diaphysis and become
    compact bone (appositional growth)

Figure 69 (Step 2)
54
Endochondral Ossification Step 3
  • Capillaries and fibroblast migrate into the
    primary ossification center
  • Blood vessels enter the cartilage
  • Bringing fibroblasts that become osteoblasts and
    secrete osteoid
  • Mineralized into rebeculae
  • Spongy bone develops at the primary ossification
    center and continues to growth toward the
    epiphysis

Figure 69 (Step 3)
55
Endochondral Ossification Step 4
  • Remodeling creates a marrow cavity
  • Osteoclasts degrade trabeculae in the center to
    create the marrow cavity
  • Bone increases in length by interstital growth of
    the epiphyseal plate followed by replacement of
    plate cartilage by spongy bone
  • Cartilage continues to grow on epiphyseal side
    and is replaced by bone on diaphysis side
  • Bone increases in diameter by appositional growth
    from cellular layers of peristeum

Figure 69 (Step 4)
56
Endochondral Ossification Step 5
  • Secondary ossification centers form in epiphyses
  • Capillaries and osteoblasts enter the epiphyses
  • creating secondary ossification centers

Figure 69 (Step 5)
57
Endochondral Ossification Step 6
  • Epiphyses become ossified with spongy bone
  • Hyaline cartilage remains on articular surfaces
    (not calcified or ossified)
  • Ossification continues at both 1and 2
    ossification centers until all epiphyseal
    cartilage has been replaced with bone ?
    epiphyseal closure
  • Adult bone retains the epiphyseal line

Figure 69 (Step 6)
58
Endochondral Ossification
  • Appositional growth
  • compact bone thickens and strengthens long bone
    with layers of circumferential lamellae

Figure 69 (Step 2)
59
During intramembranous ossification, which
type(s) of tissue is/are replaced by bone?
  • hyaline cartilage
  • fibrous connective tissue
  • mesenchymal connective tissue
  • osteoid tissue

60
In endochondral ossification, what is the
original source of osteoblasts?
  • de novo synthesis
  • cells brought with via the nutrient artery
  • cells of the inner layer of the perichondrium
  • chondrocytes from the original model

61
The characteristics of adult bones.
62
Epiphyseal Lines
Figure 610
63
Epiphyseal Lines
  • When long bone stops growing, after puberty
  • epiphyseal cartilage disappears
  • is visible on X-rays as an epiphyseal line

64
A child who enters puberty several years later
than the average age is generally taller than
average as an adult. Why?
  • Epiphyseal plates fuse during puberty.
  • Bone growth continues throughout childhood.
  • Growth spurts usually occur at the onset of
    puberty.
  • All of the above.

65
The skeletal system remodels and maintains
homeostasis.The effects of nutrition,
hormones, exercise, and aging on bone.
66
Bone Remodeling
  • Bones are not static constantly recycled and
    renewed
  • 5-7 of skeleton is recycled/week
  • Osteoclasts secrete
  • Lysosomal enzymes digest osteoid
  • Hydrochloric acid solubilize calcium salts
  • Osteoblasts secrete
  • Osteoid (organic matrix)
  • Alkaline phosphatase induces mineralization of
    osteoid
  • - Complete mineralization takes 1 week

67
Bone Remodeling
  • Bones Adapt
  • Stressed bones grow thicker
  • Bumps and ridges for muscle attachment enlarge
    when muscles are used heavily
  • Bones weaken with inactivity up to 1/3 or mass
    is lost with few weeks of inactivity
  • Heavy metals can get incorporated
  • Condition of bones depends on interplay between
    osteoclast and osteoblast activity

68
Skeleton as a Calcium Reserve
  • Calcium is important for normal function of
    neurons and muscle
  • Blood calcium 9-11 mg/100ml
  • If blood levels are too high
  • Nerve and muscle cells are non responsive
  • If blood levels are too low
  • Nerve and muscle cells are hyper-excitable ?
    convulsions, death

69
The Skeleton as Calcium Reserve
  • Bones store calcium and other minerals
  • Calcium is the most abundant mineral in the body
  • Calcium ions are vital to
  • membranes
  • neurons
  • muscle cells, especially heart cells

70
Skeleton as a Calcium Reserve
  • Calcium homeostasis depends on
  • Storage in the Bones
  • Absorption in the GI
  • Excretion at the Kidneys
  • These factors are controlled by hormones to
    regulate blood calcium levels

71
If blood calcium levels Low
  • Parathyroid hormone (from parathyroid gland)
    triggers
  • Increase osteoclast activity
  • - decrease storage
  • Enhanced calcitriol action
  • - increase absorption
  • Decreased calcium excretion at the kidneys

72
If Blood Calcium levels High
  • Calcitonin (from thyroid gland) triggers
  • Inhibition of osteoclast activity
  • Increased calcium excretion at the kidneys

73
Nutritional and Hormone Effects on Bone
  • Many nutrients and hormones are required for
    normal bone growth and maintenance
  • Calcium and phosphate salts
  • Calcitriol
  • Vitamin C
  • Vitamin A
  • Vitamin K and B12
  • Growth Hormones
  • Thyroxin
  • Estrogens and Androgens
  • Calcitonin
  • Parathyroid Hormone

74
Nutritional and Hormone Effects on Bone
  • Calcium and phosphate salts
  • - From food, for mineralization of matrix
  • Calcitriol
  • - From kidneys, for absorption of calcium and
    phosphate
  • Vitamin C
  • - From food, for collagen synthesis and
    osteoblast differentiation
  • Vitamin A
  • - From carotene in food, for normal bone growth
    in children
  • Vitamin K and B12
  • - From food, for synthesis of osteoid proteins

75
Nutritional and Hormone Effects on Bone
  • Growth Hormones
  • - From pituitary gland, for protein synthesis and
    cell growth
  • Thyroxin
  • - From thyroid gland, for cell metabolism and
    osteoblast activity
  • Estrogens and Androgens
  • - From gonads, for epiphyseal closure
  • Calcitonin
  • - From thyroid gland AND
  • Parathyroid Hormone
  • From parathyroid gland, to regulate calcium and
    phosphate levels in body fluids
  • Affects bone composition

76
Hormones for Bone Growth and Maintenance
Table 62
77
Abnormalities
  • Genetic/Physiological Abnormalities1. Giantism
  • too much Growth hormone prior to epiphyseal
    closure, bones grow excessively large
  • 2. Acromegaly
  • - too much GH after closure, bones dont
  • grow but all cartilage does
  • - ribs, nose, ears, articular cartilage
  • 3. Pituitary Dwarfism
  • - not enough GH, bones fail to elongate

78
Abnormalities
  • Diet Related Abnormalities
  • 1. Scurvy
  • - lack of Vit. C
  • - causes low collagen content, reduced bone
  • mass, bones brittle
  • 2. Osteomalacia
  • - lack calcitriol, osteoid produced but
  • not mineralized, bones flexible
  • -Called Rickets in children and leads to
  • permanent deformity

79
A seven-year-old child has a pituitary tumor
involving the cells that secrete growth hormone
(GH), resulting in increased levels of GH. How
will this condition affect the childs growth?
  • The individual will be taller.
  • The individual will be shorter.
  • Growth of the individual will be erratic and
    slow.
  • Excessive growth will be limited to axial
    skeleton.

80
Why does a child who has rickets have difficulty
walking?
  • Joints become fused, preventing movement.
  • Bones are brittle and break under body weight.
  • Bones are flexible and bend under body weight.
  • Motor skills are impaired.

81
What effect would increased PTH secretion have on
blood calcium levels?
  • higher level of calcium
  • lower level of calcium
  • uncontrolled level of calcium
  • no effect on blood calcium, PTH effects calcium
    in the bones

82
How does calcitonin help lower the calcium ion
concentration of blood?
  • by inhibiting osteoclast activity
  • by increasing the rate of calcium excretion at
    the kidneys
  • by increasing the rate of calcium uptake by
    intestinal cells
  • 1 and 2

83
Types of fractures and how do they heal.
84
Fractures
  • Fractures
  • cracks or breaks in bones
  • caused by physical stress
  • Bones break in response to excessive stress
  • Bones are designed to heal
  • Fractures are repaired in 4 steps

85
Fracture Repair Step 1
  • Bleeding
  • produces a clot (fracture hematoma)
  • Seals off dead osteocytes and broken blood vessels

Figure 615 (Step 1)
86
Fracture Repair Step 2
  • Cells of the endosteum and periosteum
  • Divide and migrate into fracture zone
  • Cells of Periosteum
  • create external callus of fibrocartilage
  • Cells of Endosteum
  • create internal callus of spongy bone
  • Calluses stabilize the break
  • external callus of cartilage and bone surrounds
    break
  • internal callus develops in marrow cavity

Figure 615 (Step 2)
87
Fracture Repair Step 3
  • Osteoblasts
  • replace cartilage with spongy bone
  • Fracture gap is now filled with all spongy bone

Figure 615 (Step 3)
88
Fracture Repair Step 4
  • A bulge from the callus marks the fracture point
  • Osteoblasts and osteocytes remodel the fracture
    for up to a year
  • Spongy bone is replaced with compact bone and
    excess callus material is removed

Figure 615 (Step 4)
89
The effects of aging on the skeletal system.
90
Effects of Aging
  • Bones become thinner and weaker with age
  • 1. Osteopenia reduction in bone mass
  • All adults suffer in some degree
  • Osteoclasts out-work osteoblast
  • sex hormones in youth inhibit osteoclasts
  • Women 8/decade after 40
  • Men 3/decade after 40

91
Effects of Aging
  • 2. Osteoporosis reduction in bone mass that
    compromises function
  • More common in women
  • Over age 45, occurs in
  • 29 of women
  • 18 of men
  • Thinner bones to start
  • Greater rate of osteopenia

92
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93
Effects of Bone Loss
  • The epiphyses, vertebrae, and jaws are most
    affected
  • resulting in fragile limbs
  • reduction in height
  • tooth loss

94
Hormones and Bone Loss
  • Estrogens and androgens help maintain bone mass
  • Bone loss in women accelerates after menopause

95
Why is osteoporosis more common in older women
than in older men?
  • Testosterone levels decline in post-menopausal
    women.
  • Older women tend to be more sedentary than older
    men.
  • Declining estrogen levels lead to decreased
    calcium deposition.
  • In males, androgens increase with age.

96
SUMMARY (1 of 2)
  • Bone shapes, markings, and structure
  • The matrix of osseous tissue
  • Types of bone cells
  • The structures of compact bone
  • The structures of spongy bone
  • The periosteum and endosteum
  • Ossification and calcification
  • Intramembranous ossification
  • Endochondrial ossification

97
SUMMARY (2 of 2)
  • Blood and nerve supplies
  • Bone minerals, recycling, and remodeling
  • The effects of exercise
  • Hormones and nutrition
  • Calcium storage
  • Fracture repair
  • The effects of aging
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