FUNCTION(S) OF THE SKELETAL SYSTEM

2. FUNCTION(S) OF THE SKELETAL SYSTEM • Support • Protection • Movement • Mineral storage • Formation of blood cells Hematopoiesis

3. CLASSIFICATION OF BONES • Types of Osseous Tissue • Compact (dense) Bone • Spongy (cancellous) Bone spongy bone compact bone

4. TYPES OF OSSEOUS TISSUE • Long Bones • A shaft with two widened ends • Compact and spongy bone • Examples: • Humerus • Radius & ulna • Femur • Tibia & fibula • Phalanges Femur

5. TYPES OF OSSEOUS TISSUE • Short Bones • Cube-shaped bones • Mostly spongy bone • Examples: • Wrist and ankle bones • Sesamoid bones • Short bones embedded with a tendon • Example: Patella Tarsal Patella

6. TYPES OF OSSEUS TISSUE • Flat Bones • Thin, flat bones • Layer of spongy bone between layers of compact bone • Examples: • Sternum • Ribs • Skull Parietal

7. TYPES OF OSSEOUS TISSUE • Irregular Bones • Irregular shape • Mostly spongy bone • Examples: • Vertebrae • Hip bones Vertebra

8. BONE STRUCTURE • Diaphysis • Shaft of bone • Compact bone surrounds medullary cavity • Contains yellow marrow (fat) Diaphysis medullary cavity

9. BONE STRUCTURE proximal epiphysis • Epiphyses • Widened end of long bones • Spongy bone • May contain red marrow • Epipheseal line or plate • Bone growth during childhood • Actively mitotic plate of hyaline cartilage • Articular cartilage covers joint surface distal epiphysis

10. BONE STRUCTURE • Bone Membranes • Periosteum • Outer C.T. membrane • Inner surface may contain osteoblasts or osteoclasts • Blood vessels and nerves periosteum

11. BONE STRUCTURE • Bone Membranes • Endosteum • Inner C.T. membrane • Lines marrow cavities, Haversian canals and covers trabeculae • Contains osteoblasts and osteoclasts endosteum

12. BONE MARROW • Red Bone Marrow • Found in spongy bone • Hematopoietic tissue • Found in: • Head of femur and humerus • Sternum and hip bones in adults Spongy bone spaces containing red bone marrow

13. BONE MARROW yellow bone marrow • Yellow Bone Marrow • Composed of fat • Found in: • Medullary cavity • May convert to red marrow

14. BONE HISTOLOGY: Compact Bone Haversian canals concentric lamella lacuna canaliculi Volkmann’s canal

15. BONE HISTOLOGY: Compact Bone • Haversian Systems (Osteons) • Lamellae • Concentric, interstitial & circumferential • Haversian canals • Volkmann's canals • Osteocytes within lacunae • Canaliculi

16. BONE HISTOLOGY: Osteon Haversian canal Volkmann’s canal

17. BONE HISTOLOGY: Spongy Bone • Spongy Bone • No osteons • Scattered trabeculae for support • Called diploe in flat bones • Red marrowbetweentrabeculae diploe

18. CHEMICAL COMPOSITION OF BONE • Organic Components • 1/3 of matrix • Includes all 3 cell types • Osteoblasts secrete osteoid = Organic bone matrix • Inorganic Components • 2/3 of matrix • Accounts for bone hardness • Hydroxyapatites [Ca10(PO4)6(OH)2] • Mineral salts of calcium phosphate

19. BONE MARKINGS • Structures on the external surface of bone • Caused by: • Muscle or ligament attachments • Blood vessels, nerves etc. travel • Be familiar with the types of markings found on bones (see Table 6.1 in your textbook or the list in your lab notebook)

20. OSTEOGENESIS/OSSIFICATION • Osteogenesis • Process of bone formation • Used for: • Formation of bony skeleton in embryos • Bone growth during childhood and early adulthood • Bone remodeling and repair in adults

21. OSTEOGENESIS/OSSIFICATION • Two Types of Bone Formation • Intramembranous Ossification • Bone develops from a fibrous membrane • Endochondral Ossification • Bone develops from a hyaline cartilage model

22. Intramembranous Ossification

23. INTRAMEMBRANOUS OSSIFICATION • Used for formation of flat bones (skull & clavicles) • Steps • Formation of bone matrix within fibrous membrane • Initial ossification sight ( 8 wks)  A fibrous C.T. membrane • Ossification center appears in the C.T. membrane • Osteoid secreted by osteoblasts • Osteoid becomes mineralized • Formation of woven bone • Network of bony trabeculae forms = woven bone • Formation of compact bone plates • Trabeculae thicken at the edge, forming compact bone • Spongy bone remains in the center

24. ENDOCHONDRAL OSSIFICATION hyaline cartilage perichondrium deteriorating cartilage matrix periosteum

25. ENDOCHONDRAL OSSIFICATION • Used for formation of most bones of the skeleton (2nd month) • Steps • Formation of bone collar around hyaline cartilage model • Perichondrium around hyaline cartilage model converted to periosteum • Osteoblasts secrete osteoid onto the external shaft of the “hyaline” bone • Deterioration of cartilage matrix • Matrix within the hyaline shaft deteriorates

26. ENDOCHONDRAL OSSIFICATION secondary ossification center articular cartilage blood vessel periosteal bud medullary cavity epiphyseal plate open spaces forming bone

27. ENDOCHONDRAL OSSIFICATION • Steps • Formation of spongy bone by periosteal bud • Periosteal bud invades the internal cavity • Contains blood vessels and osteoblasts • Osteoblasts produce trabeculae of bone • Formation of medullary cavity • Osteoclasts break down new bone forming a medullary cavity • Ossification of epiphyses • Secondary ossification centers form in epiphyses shortly before or after birth • Spongy bone forms • Hyaline cartilage remains only at the epiphyseal plate and articular surfaces

28. BONE GROWTH IN LONG BONES Growth in Length • Cartilage growth in epiphyseal plate • Cartilage replaced by bone • Bone remodeled • Bone resorption Growing Bone Adult Bone

29. BONE GROWTH IN LONG BONES • Long bones lengthen by growth of the epiphyseal plates • Harden at the end of puberty • All bones grow in width or change shape by appositional growth

30. BONE GROWTH IN LONG BONES • Growth in the Epiphyseal Plate • Hyaline plate contains dividing chondrocytes • Chondrocytes enlarge • Pushed towards diaphysis • Eventually die • Osteoblasts secrete bone matrix • Form small bone spicules

31. BONE GROWTH IN LONG BONES • Growth in the Epiphyseal Plate (cont.) • Epiphyseal plate activity stimulated by growth hormone during childhood • Sex hormones (testosterone & estrogen) • Adolescent growth spurt • End of adolescence • Epiphyseal plate replaced by bone • Longitudinal bone growth ends

32. BONE GROWTH IN LONG BONES • Appositional Growth • Used to widen bones for remodeling • Osteoblasts on the periosteum: • Form new Haversian systems on outer bone surface • Increase thickness of compact bone • Osteoclasts on the endosteum • Resorb bone • Enlarge medullary cavity

33. BONE GROWTH IN LONG BONES Appositional Growth • Bone addition • Bone resorption Growing Bone Adult Bone

34. BONE REMODELING & REPAIR • Bone Remodeling • Bone deposited and resorbed daily at the periosteal and endosteal surfaces • 5 to 7% of bone mass recycled weekly • Rate of resorption should = rate of deposit • Response to blood calcium levels • Ca2+ ions are needed for nerve impulse transmission, muscle contractions, blood coagulation • Vitamin D enhances absorption of Ca2+ from the intestine • When remodeling occurs is determined by mechanical and gravitational forces • Heavier bone usage  heavier bones • Nonuse  bone wasting

35. BONE REMODELING & REPAIR • Bone Deposit • Osteoblasts deposit osteoid which is later mineralized into hard bone • Hormonal Control • Calcitonin • Produced by “C” cells in the thyroid glands • Secreted when blood Ca2+ levels  • Inhibits bone resorption, enhances Ca2+ deposit in bone matrix

36. BONE REMODELING & REPAIR • Bone Resorption • Osteoclasts secrete enzymes • Digest organic matrix • Osteoclasts secrete acids • Make calcium salts more soluble • Minerals freed from bone are put into bloodstream • Hormonal Control • Parathyroid Hormone (PTH) • Produced by the parathyroid glands • Secreted in response to low blood Ca2+ levels • Stimulates bone resorption

37. CALCIUM HOMEOSTASIS: PTH CONTROL BONE PTH promotes Ca2+ release into the blood Ca2+ removed from blood by osteoblasts BLOOD PTH promotes Ca2+ reabsorption from urine Unabsorbed Ca2+ lost in feces Ingested Ca2+ KIDNEY SMALL INTESTINE Ca2+ lost in the urine Vitamin D promotes Ca2+ absorption PTH promotes Vitamin D formation

38. FRACTURES • Fracture • Break in the bone • Fracture Types • Simple • Compound • Comminuted • Compression • Depression • Impacted • Spiral • Greenstick

39. TYPES OF FRACTURES comminuted fracture fissured fracture greenstick fracture transverse fracture oblique fracture spiral fracture

40. FRACTURE REPAIR • Phases of Repair • Hematoma Formation • Blood clot forms hematoma

41. FRACTURE REPAIR • Phases of Repair • Fibrocartilaginous Callus Formation • Fibroblasts secrete collagen • Condroblasts secrete cartilage matrix • Osteoblasts form spongy bone fibrocartilage spongy bone

42. FRACTURE REPAIR • Phases of Repair • Bony Callus Formation • Osteoclasts and osteoblasts convert callus into a bony callus bony callus

43. FRACTURE REPAIR • Phases of Repair • Bony Callus Remodeling • Continues for several months compact bone

44. BONE IMBALANCES • Osteoporosis • A group of diseases in which bone resorption exceeds bone deposit = reduction in bone mass • Vertebrae and neck of femur most susceptible • Most common in postmenapausal women due to estrogen reduction

45. BONE IMBALANCES • Osteoporosis • Risk Factors • Insufficient exercise • Poor calcium or protein intake in diet • Vitamin D or calcitonin metabolism problems • Smoking • Drinking • Immobility

46. BONE IMBALANCES • Osteomalacia • Disorders in which bone is inadequately mineralized • Osteoid is deposited but calcium salts are not • Weight-bearing bones fracture, bend or deform • Rickets may occur in children with insufficient calcium or Vitamin D intake • Causes bowed legs and deformities of the pelvis

47. BONE IMBALANCES • Paget’s Disease • Characterized by excessive, abnormal bone formation and resorption • Bone produced contains a high ratio of woven bone to compact bone • Bone mineralization is reduced • Bones become soft and weak