1. 5
The Skeletal System: Osseous Tissue and Skeletal Structure

2. Introduction The skeletal system is made of:
Skeletal bones
Cartilage
Ligaments
Connective tissue to stabilize the skeleton
Bones are dynamic organs, which consist of several tissue types 2

3. Introduction Functions of the skeletal system Support
Provides the framework for the attachment of other organs
Storage of minerals
Calcium ions: 98% of the body’s calcium ions are in the bones
Phosphate ions
Blood cell production
Bone marrow produces erythrocytes, leukocytes, and platelets 3

4. Introduction Functions of the skeletal system (continued) Leverage
Muscles pull on the bones to produce movement
Protection
Ribs protect heart and lungs
Skull protects the brain
Vertebrae protect the spinal cord
Pelvic bones protect the reproductive organs 4

5. Anatomy of Skeletal Elements
There are seven broad categories of bones according to their shapes
Sutural bones
Irregular bones
Short bones
Pneumatized bones
Flat bones
Long bones
Sesamoid bones 5

6. Classification of Bones
Long Bones: longer than they are wide, upper and lower limbs.
Short Bones: Broad as they are long, cube shaped, round, i.e. tarsals & carpals
Flat Bones: Thin, flat and curved, skull (parietal), sternum, scapulae.
Irregular Bones: Don’t fit in the others, face, vertebrae
Sesamoid: Sesame seed, patella, small and flat
Sutural bones: Wormian bones, borders like a jigsaw puzzle.

7. Figure 5.11 Shapes of Bones 7 Sutural Bones Pneumatized Bones
Flat Bones
Sutures
Parietal bone
External table
Sutural bone
Internal table
Diploë (spongy bone)
Ethmoid
Air cells
Irregular Bones
Long Bones
Vertebra
Humerus
Short Bones
Sesamoid Bones
Carpal bones
Patella 7

8. Structure of Bone Bones (osseous tissue) Supporting connective tissue
Specialized cells
Solid matrix
Outer lining
Called the periosteum
Inner lining
Called the endosteum 8

9. Structure of Bone The Histological Organization of Mature Bone
The matrix
Calcium phosphate eventually converts to hydroxyapatite crystals
Hydroxyapatite crystals resist compression 9

10. Structure of Bone The Histological Organization of Mature Bone
Collagen fibers
Make up 2/3 of the bone matrix
Contribute to the tensile strength of bones
Collagen and hydroxyapatite make bone tissue extremely strong
Bone cells
Contribute only 2% of the bone mass 10

11. Structure of Bone The Cells of Mature Bone Osteocytes Osteoblasts
Mature bone cells
Maintain the protein and mineral content of the matrix
Osteoblasts
Immature bone cells
Found on the inner and outer surfaces of bones
Produce osteoid, which is involved in making the matrix
Osteoblasts are involved in making new bone. This is a process called osteogenesis
Osteoblasts can convert to osteocytes 11

12. Structure of Bone The Cells of Mature Bone (continued)
Osteoprogenitor cells
Found on the inner and outer surfaces of bones
Differentiate to form new osteoblasts
Heavily involved in the repair of bones after a break
Osteoclasts
Secrete acids, which dissolve the bones thereby causing the release of stored calcium ions and phosphate ions into the blood
This process is called osteolysis 12

13. Figure 5.1a Histological Structure of a Typical Bone
Canaliculi
Osteocyte
Matrix
Endosteum
Osteoprogenitor cell
Medullary
cavity
Osteocyte: Mature bone cell
that maintains the bone matrix
Osteoprogenitor cell:
Stem cell whose divisions produce
osteoblasts
Osteoblast
Osteoid
Matrix
Osteoclast
Matrix
Medullary
cavity
Osteoblast: Immature bone cell that secretes organic
components of matrix
Osteoclast: Multinucleate cell
that secretes acids and enzymes
to dissolve bone matrix
The cells of bone 13

14. Structure of Bone The Osteon It is the basic unit of skeletal bones
Consists of:
Central canal
Canaliculi
Osteocytes
Lacunae
Lamellae 14

15. Figure 5.1c Histological Structure of a Typical Bone
Canaliculi
Concentric
lamellae
Central canal
Osteon
Lacunae
Osteons
LM  220
A thin section through
compact bone; in this
procedure the intact matrix
and central canals appear
white, and the lacunae and
canaliculi are shown in black. 15

16. Figure 5.1d Histological Structure of a Typical Bone
Canaliculi
Concentric
lamellae
Central canal
Osteon
Lacunae
Osteon
LM  343
A single osteon at higher
magnification 16

17. Figure 5.1b Histological Structure of a Typical Bone
Osteon
Lacunae
Central canals
Lamellae
Osteons
SEM  182
A scanning electron
micrograph of several osteons
in compact bone 17

18. Structure of Bone Two types of osseous tissue
Compact bone (dense bone)
Compact bones are dense and solid
Forms the walls of bone outlining the medullary cavity
Medullary cavity consists of bone marrow
Spongy bone (trabecular bone)
Open network of plates 18

19. Figure 5.2a-c The Internal Organization in Representative Bones
Concentric
lamellae
Spongy bone
Blood vessels
Collagen fiber
orientation
Compact bone
Central
canal
Medullary cavity
Endosteum
Endosteum
The organization of collagen
fibers within concentric lamellae
Periosteum
Compact
bone
Spongy
bone
Medullary
cavity
Capillary
Small vein
Circumferential
lamellae
Gross anatomy
of the humerus
Concentric
lamellae
Osteons
Periosteum
Interstitial
lamellae
Trabeculae of
spongy bone
Artery
Vein
Perforating
canal
Central
canal
Diagrammatic view of the histological
organization of compact and spongy bone 19

20. Figure 5.2d The Internal Organization in Representative Bones
Trabeculae of
spongy bone
Endosteum
Lamellae
Canaliculi
opening
on surface
Location and structure of spongy bone. The photo
shows a sectional view of the proximal end of the femur. 20

21. Structure of Bone Structural Differences Compact bone Spongy bone
Consists of osteons
Makes up the dense, solid portion of bone
Spongy bone
Trabeculae are arranged in parallel struts
Trabeculae form branching plates
Trabeculae form an open network
Creates the lightweight nature of bones 21

22. Structure of Bone Functional Differences Compact bone Spongy bone
Conducts stress from one area of the body to another area of the body
Generates tremendous strength from end to end
Weak strength when stress is applied to the side
Spongy bone
Trabeculae create strength to deal with stress from the side 22

23. Figure 5.3a Anatomy of a Representative Bone
Spongy bone
Epiphysis
Articular
surface of
head of femur
Metaphysis
Compact bone
Diaphysis
(shaft)
Medullary cavity
Metaphysis
Epiphysis
Posterior view
Sectional view
The femur, or thigh bone, in superficial and sectional views. The femur has a
diaphysis (shaft) with walls of compact bone and epiphyses (ends) filled with
spongy bone. A metaphysis separates the diaphysis and epiphysis at each
end of the shaft. The body weight is transferred to the femur at the hip joint.
Because the hip joint is off center relative to the axis of the shaft, the body
weight is distributed along the bone so that the medial portion of the shaft is
compressed and the lateral portion is stretched. 23

24. Figure 5.3b Anatomy of a Representative Bone
An intact femur chemically cleared
to show the orientation of the
trabeculae in the epiphysis 24

25. Figure 5.3c Anatomy of a Representative Bone
Articular surface of head of femur
Trabeculae
of spongy
bone
Cortex
Medullary cavity
Compact bone
A photograph showing the
epiphysis after sectioning 25

26. Structure of Bone Organization of Compact and Spongy Bone Epiphysis
Each end of the long bones
Diaphysis
Shaft of the long bones
Metaphysis
Narrow growth zone between the epiphysis and the diaphysis 26

27. Figure 5.3a Anatomy of a Representative Bone
Spongy bone
Epiphysis
Articular
surface of
head of femur
Metaphysis
Compact bone
Diaphysis
(shaft)
Medullary cavity
Metaphysis
Epiphysis
Posterior view
Sectional view
The femur, or thigh bone, in superficial and sectional views. The femur has a
diaphysis (shaft) with walls of compact bone and epiphyses (ends) filled with
spongy bone. A metaphysis separates the diaphysis and epiphysis at each
end of the shaft. The body weight is transferred to the femur at the hip joint.
Because the hip joint is off center relative to the axis of the shaft, the body
weight is distributed along the bone so that the medial portion of the shaft is
compressed and the lateral portion is stretched. 27

28. Structure of Bone The Periosteum and Endosteum Periosteum
Outer surface of the bone
Isolates and protects the bone from surrounding tissue
Provides a route and a place for attachment for circulatory and nervous supply
Actively participates in bone growth and repair
Attaches the bone to the connective tissue network of the deep fascia 28

29. Structure of Bone The Periosteum and Endosteum Periosteum and Tendons
Tendons are cemented into the lamellae by osteoblasts
Therefore, tendons are actually a part of the bone 29

30. Figure 5.4c Anatomy and Histology of the Periosteum and Endosteum
Zone of tendonbone attachment
Tendon
Periosteum
Medullary cavity
Endosteum
Spongy bone of epiphysis
Epiphyseal cartilage
LM  100
A tendonbone junction 30

31. Structure of Bone The Periosteum and Endosteum Endosteum
Inner surface of bone
Lines the medullary cavity
Consists of osteoprogenitor cells
Actively involved in repair and growth 31

32. Figure 5.4ab Anatomy and Histology of the Periosteum and Endosteum
Circumferential
lamellae
Joint capsule
Cellular layer of periosteum
Cellular layer of periosteum
Fibrous layer of periosteum
Fibrous layer
of periosteum
Canaliculi
Lacuna
Endosteum
Compact bone
Osteocyte
Perforating
fibers
The periosteum contains outer (fibrous) and inner (cellular) layers. Collagen fibers of the periosteum are continuous with those of the bone, adjacent joint capsules, and attached tendons and ligaments.
Bone matrix
Giant
multinucleate
osteoclast
Endosteum
Osteoprogenitor
cell
Osteocyte
Osteoid
Osteoblasts
The endosteum is an incomplete
cellular layer containing osteoblasts,
osteoprogenitor cells, and osteoclasts. 32

33. Bone Development and Growth
Before six weeks of development, the skeleton is cartilage
Cartilage cells will be replaced by bone cells
This is called ossification
Osteogenesis
Bone formation
Calcification
The deposition of calcium ions into the bone tissue 33

34. Bone Development and Growth
There are two types of ossification
Intramembranous ossification
Involved in the development of clavicle, mandible, skull, and face
Endochondral ossification
Involved in the development of limbs, vertebrae, and hips 34

35. Bone Development and Growth
Intramembranous ossification
Mesenchymal cells differentiate to form osteoblasts
Osteoblasts begin secreting a matrix
Osteoblasts become trapped in the matrix
Osteoblasts differentiate and form osteocytes
More osteoblasts are produced, thus move outward
Eventually, compact bone is formed 35

36. Figure 5.5 Histology of Intramembranous Ossification
Mesenchymal cells aggregate, differentiate into osteoblasts, and begin the ossification process. The bone expands as a series of spicules that spread into surrounding tissues.
As the spicules interconnect, they trap blood vessels within the bone.
Over time, the bone assumes the structure of spongy bone. Areas of spongy bone may later be removed, creating medullary cavities. Through remodeling, spongy bone formed in this way can be converted to compact bone.
Osteocyte in lacuna
Bone matrix
Osteoblast
Osteoid
Embryonic connective tissue
Blood vessel
Osteocytes in lacunae
Blood vessels
Osteoblast
layer
Mesenchymal cell
Blood vessel
Blood vessel
Osteoblasts
Spicules
LM  32
LM  32 36

37. Bone Development and Growth
Endochondral ossification
The developing bone begins as cartilage cells
Cartilage matrix grows inward
Interstitial growth
Cartilage matrix grows outward
Appositional growth
Blood vessels grow around the cartilage 37

38. Bone Development and Growth
Endochondral ossification (continued)
Perichondrial cells convert to osteoblasts
Osteoblasts develop a superficial layer of bone around the cartilage
Blood vessels penetrate the cartilage
Osteoblasts begin to develop spongy bone in the diaphysis
This becomes the primary center of ossification 38

39. Enlarging chondrocytes within calcifying matrix
Figure 5.7a Anatomical and Histological Organization of Endochondral Ossification (Part 1 of 2)
As the cartilage enlarges, chondrocytes near the center of the shaft increase greatly in size. The matrix is reduced to a series of small struts that soon begin to calcify. The enlarged chondrocytes then die and disintegrate, leaving cavities within the cartilage.
Blood vessels grow around the edges of the cartilage, and the cells of the perichondrium convert to osteoblasts. The shaft of the cartilage then becomes ensheathed in a superficial layer of bone.
Enlarging chondrocytes within calcifying matrix
Epiphysis
Diaphysis
Bone formation
Hyaline cartilage
Steps in the formation of a long bone from a hyaline cartilage model 39

40. Figure 5.7a Anatomical and Histological Organization of Endochondral Ossification (Part 2 of 2)
Blood vessels penetrate the cartilage and invade the central region. Fibroblasts migrating with the blood vessels differentiate into osteoblasts and begin producing spongy bone at a primary center of ossification. Bone formation then spreads along the shaft toward both ends.
Remodeling occurs as growth continues, creating a medullary cavity. The bone of the shaft becomes thicker, and the cartilage near each epiphysis is replaced by shafts of bone. Further growth involves increases in length (Steps 5 and 6) and diameter (see Figure 5.9).
Medullary cavity
Medullary cavity
Blood vessel
Primary ossification center
Superficial bone
See Figure 5.9
Spongy bone
Metaphysis
Steps in the formation of a long bone from a hyaline cartilage model 40

41. Bone Development and Growth
Endochondral ossification (continued)
The cartilage near the epiphysis converts to bone
Blood vessels penetrate the epiphysis
Osteoblasts begin to develop spongy bone in the epiphysis
Epiphysis becomes the secondary center of ossification 41

42. Figure 5.7b Anatomical and Histological Organization of Endochondral Ossification (Part 1 of 2)
Capillaries and osteoblasts migrate into the epiphyses, creating secondary ossification centers.
Soon the epiphyses are filled with spongy bone. An articular cartilage remains exposed to the joint cavity; over time it will be reduced to a thin superficial layer. At each metaphysis, an epiphyseal cartilage separates the epiphysis from the diaphysis.
Hyaline cartilage
Articular cartilage
Epiphysis
Spongy
bone
Metaphysis
Epiphyseal cartilage
Periosteum
Compact bone
Diaphysis
Secondary ossification center 42

43. Bone Development and Growth
Epiphyseal plate
Area of cartilage in the metaphysis
Also called the epiphyseal cartilage
Cartilage near the diaphysis is converted to bone
The width of this zone gets narrower as we age 43

44. Epiphyseal cartilage matrix Cartilage cells undergoing division
Figure 5.7b Anatomical and Histological Organization of Endochondral Ossification (Part 2 of 2)
Epiphyseal cartilage matrix
Cartilage cells undergoing division
Zone of proliferation
Zone of hypertrophy
Medullary cavity
Osteoblasts
Osteoid
Epiphyseal cartilage
LM  250
Light micrograph showing the zones of cartilage and the advancing osteoblasts at an epiphyseal cartilage 44

45. Figure 5.7 Anatomical and Histological Organization of Endochondral Ossification
As the cartilage enlarges, chondrocytes near the center of the shaft increase greatly in size. The matrix is reduced to a series of small struts that soon begin to calcify. The enlarged chondrocytes then die and disintegrate, leaving cavities within the cartilage.
Blood vessels grow around the edges of the cartilage, and the cells of the perichondrium convert to osteoblasts. The shaft of the cartilage then becomes ensheathed in a superficial layer of bone.
Blood vessels penetrate the cartilage and invade the central region. Fibroblasts migrating with the blood vessels differentiate into osteoblasts and begin producing spongy bone at a primary center of ossification. Bone formation then spreads along the shaft toward both ends.
Remodeling occurs as growth continues, creating a medullary cavity. The bone of the shaft becomes thicker, and the cartilage near each epiphysis is replaced by shafts of bone. Further growth involves increases in length (Steps 5 and 6) and diameter (see Figure 5.9).
Capillaries and osteoblasts migrate into the epiphyses, creating secondary ossification centers.
Soon the epiphyses are filled with spongy bone. An articular cartilage remains exposed to the joint cavity; over time it will be reduced to a thin superficial layer. At each metaphysis, an epiphyseal cartilage separates the epiphysis from the diaphysis.
Hyaline cartilage
Epiphyseal cartilage matrix
Cartilage cells undergoing division
Articular cartilage
Epiphysis
Spongy
bone
Zone of proliferation
Enlarging chondrocytes within calcifying matrix
Epiphysis
Metaphysis
Zone of hypertrophy
Epiphyseal cartilage
Medullary cavity
Periosteum
Blood vessel
Medullary cavity
Primary ossification center
Compact bone
Diaphysis
Diaphysis
Superficial bone
See Figure 5.9
Spongy bone
Medullary cavity
Osteoblasts
Osteoid
Bone formation
Metaphysis
Epiphyseal cartilage
LM  250
Hyaline cartilage
Secondary ossification center
Light micrograph showing the zones of cartilage and the advancing osteoblasts at an epiphyseal cartilage
Steps in the formation of a long bone from a hyaline cartilage model 45

46. Figure 5.8 Epiphyseal Cartilages and Lines
X-ray of the hand of a young child. The arrows indicate the locations of the epiphyseal cartilages.
X-ray of the hand of an adult. The arrows indicate the locations of epiphyseal lines. 46

47. Figure 5.6 Fetal Intramembranous and Endochondral Ossification
Temporal bone
Parietal bone
Mandible
Intramembranous ossification produces the roofing bones of the skull
Clavicle
Frontal bone
Scapula
Humerus
Metacarpal bones
Phalanges
Ribs
Radius
Endochondral ossification replaces cartilages of embryonic skull
Vertebrae
Ulna
Cartilage
Hip bone (ilium)
Primary ossification centers of the diaphyses (bones of the lower limb)
Femur
Fibula
Tibia
Phalanx
Future hip bone
Metatarsal bones
At 10 weeks the fetal skull clearly shows both membrane and cartilaginous bone, but the boundaries that indicate the limits of future skull bones have yet to be established.
At 16 weeks the fetal skull shows the irregular margins of the future skull bones. Most elements of the appendicular skeleton form through endochondral ossification. Note the appearance of the wrist and ankle bones at 16 weeks versus at 10 weeks. 47

48. Bone Development and Growth
Enlarging the diameter of bone
Called appositional growth
Blood vessels that run parallel to the bone becomes surrounded by bone cells
“Tunnels” begin to form
Each “tunnel” has a blood vessel in it 48

49. Bone Development and Growth
Enlarging the diameter of bone
Osteoblasts begin to produce matrix, thus creating concentric rings
As osteoblasts are laying down more bone material, osteoclasts are dissolving the inner bone, thus creating the marrow cavity 49

50. Figure 5.9a Appositional Bone Growth (Part 1 of 2)
Bone formation at the surface of the bone produces ridges that parallel a blood vessel.
The ridges enlarge and create a deep pocket.
The ridges meet and fuse, trapping the vessel inside the bone.
Ridge
Periosteum
Perforating canal
Artery
Three-dimensional diagrams illustrate the mechanism responsible for increasing the diameter of a growing bone. 50

51. Figure 5.9a Appositional Bone Growth (Part 2 of 2)
Bone deposition proceeds inward toward the vessel, beginning the creation of a typical osteon.
Additional circumferential lamellae are deposited and the bone continues to increase in diameter.
Osteon is complete with new central canal around blood vessel. Second blood vessel becomes enclosed.
Periosteum
Circumferential lamellae
Central canal of new osteon
Three-dimensional diagrams illustrate the mechanism responsible for increasing the diameter of a growing bone. 51

52. Figure 5.9b Appositional Bone Growth
Bone resorbed by osteoclasts
Bone deposited by osteoblasts
Infant
Child
Young adult
Adult
A bone grows in diameter as new bone is added to the outer surface. At the same time, osteoclasts resorb bone on the inside, enlarging the medullary cavity. 52

53. Bone Development and Growth
There are four major sets of blood vessels associated with the long bones
Nutrient vessels
Enter the diaphysis and branch toward the epiphysis
Re-enter the compact bone, leading to the central canals of the osteons
Metaphyseal vessels
Supply nutrients to the diaphyseal edge of the epiphysis 53

54. Bone Development and Growth
Four major sets of blood vessels (continued)
Epiphyseal vessels
Supply nutrients to the medullary cavities of the epiphysis
Periosteal vessels
Supply nutrients to the superficial osteons 54

55. Figure 5.10 Circulatory Supply to a Mature Bone
Articular cartilage
Epiphyseal artery and vein
Branches of nutrient artery and vein
Metaphyseal artery and vein
Periosteum
Periosteum
Compact bone
Periosteal arteries and veins
Connections to superficial osteons
Medullary cavity
Nutrient artery and vein
Nutrient foramen
Metaphyseal artery and vein
Metaphysis
Epiphyseal line 55

56. Bone Development and Growth
Factors Regulating Bone Growth
Nutrition
Calcium ions
Phosphate ions
Magnesium ions
Citrate
Carbonate ions
Sodium ions
Vitamins A, C, D (calcitriol) 56

57. Bone Development and Growth
Factors Regulating Bone Growth (continued)
Hormones: Parathyroid gland
Releases parathyroid hormone
Stimulates osteoclasts
Stimulates osteoblasts
Increases calcium ion absorption from the small intestine to the blood 57

58. Bone Development and Growth
Factors Regulating Bone Growth (continued)
Hormones: Thyroid gland
Releases calcitonin
Inhibits osteoclasts
Removes calcium ions from blood and adds it to bone 58

59. Bone Development and Growth
Factors Regulating Bone Growth (continued)
Hormones: Thyroid gland
Releases thyroxine (T4)
Maintains normal activity of the epiphyseal cartilage 59

60. Bone Development and Growth
Factors Regulating Bone Growth (continued)
Hormones: Pituitary gland
Releases growth hormone (somatotropin)
Maintains normal activity of the epiphyseal cartilage 60

61. Bone Maintenance, Remodeling, and Repair
Aging and the Skeletal System
When we’re young, osteoblast activity balances with osteoclast activity
When we get older, osteoblast activity slows faster than osteoclast activity
When osteoclast activity is faster than osteoblast activity, bones become porous
Estrogen keeps osteoclast activity under control 61

62. Bone Maintenance, Remodeling, and Repair
Aging and the Skeletal System
As women age, estrogen levels drop
Osteoclast control is lost
Osteoclasts are overactive
Bones become porous
This is osteoporosis 62

63. Bone Maintenance, Remodeling, and Repair
Injury and Repair
When a bone is broken, bleeding occurs
A network of spongy bone forms
Osteoblasts are overly activated, thus resulting in enlarged callused area
This area is now stronger and thicker than normal bone 63

64. Clinical Note 5.3 Fractures and Their Repair (Part 3 of 4)
Repair of a fracture
Fracture hematoma
Dead bone
Bone fragments
Spongy bone of external callus
Periosteum
Immediately after the fracture, extensive bleeding occurs. Over a period of several hours, a large blood clot, or fracture hematoma, develops.
An internal callus forms as a network of spongy bone units the inner edges, and an external callus of cartilage and bone stabilizes the outer edges. 64

65. Clinical Note 5.3 Fractures and Their Repair (Part 4 of 4)
External callus
Internal callus
External 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.
A swelling initially marks the location of the fracture. Over time, this region will be remodeled, and little evidence of the fracture will remain. 65

66. Anatomy of Skeletal Elements
Bone markings include:
Projections
Depressions
Fissures
Foramina
Canals (meatuses) 66

67. Figure 5.12a Examples of Bone Markings (Surface Features)
Trochanter
Head
Neck
Facet
Tubercle
Condyle
Femur 67

68. Figure 5.12b Examples of Bone Markings (Surface Features)
Fissure
Process
Ramus
Foramen
Skull, anterior view 68

69. Figure 5.12c Examples of Bone Markings (Surface Features)
Canal
Sinuses
Meatus
Skull, sagittal section 69

70. Figure 5.12d Examples of Bone Markings (Surface Features)
Tubercle
Head
Sulcus
Neck
Tuberosity
Fossa
Trochlea
Condyle
Humerus 70

71. Figure 5.12e Examples of Bone Markings (Surface Features)
Crest
Spine
Fossa
Line
Foramen
Ramus
Pelvis 71

72. Table 5.1 Common Bone Marking Terminology72