1 / 26

Lecture # 13: Bone Tissue

Lecture # 13: Bone Tissue. (Chapter 7) . Objectives:. 1- Describe the gross anatomical features of a typical long bone and a typical short bone. . 2- Discuss the microscopic structure of compact bone and compare it to that of cancellous bone. .

penny
Download Presentation

Lecture # 13: Bone Tissue

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Lecture # 13: Bone Tissue (Chapter 7) Objectives: 1- Describe the gross anatomical features of a typical long bone and a typical short bone. 2- Discuss the microscopic structure of compact bone and compare it to that of cancellous bone. 3- Define ossification and distinguish between intramem- branous and endochondral ossification. 4- Explain the effects of vitamin D and various hormones on bone physiology and plasma Ca++.

  2. The Shapes of Bones • Flat bones • Irregular bones • They protect soft organs. They are • curved but wide & thin • They have elaborate shapes that don’t fit into the other categories • Long bones • Short bones • Longer than wide. They serve as rigid levers that are acted upon by skeletal muscles to produce body movements • They are equal in length and width. • They glide across one another in multiple directions

  3. Spongy bone Articular cartilage Articular cartilage Epiphyseal line Medullary cavity Compact bone Periosteum Endosteum Yellow bone marrow Compact bone Periosteum Perforating (Sharpey’s fibers) Nutrient arteries • General Features of Bones Cortex or cortical bone (compact bone) Proximal epiphysis Spongy bone Compact bone Diaphysis Distal epiphysis

  4. Matrix A- Inorganic matter Calcium phosphate (2/3 of the weight of the bone) Hydroxyapatite and other calcium salts They withstand compression but they are inflexible B- Organic matter Collagen fibers (1/3 of the weight of the bone) Osseous Tissue They are remarkably strong and they can easily tolerate twisting and bending The collagen fibers and the hydroxyapatite form a protein-crystal combination that allow the bone to be strong, somewhat flexible, and highly resistant to shattering 1- Osteogenic (Osteoprogenitor ) cell Bone Cells 2- Osteoblast 3- Osteocyte 4- Osteoclast

  5. Bone Cells Matrix Osteoid 1- Osteogenic cell 3- Osteocyte 2- Osteoblast -They are in the inner layer of the periosteum and in the endosteum -They are in pits called resorption bays 4- Osteoclast They are located in the lacunae interconnected by the canaliculi -They are in a single layer in the bone surface under the endosteum Functions: Functions: Functions: Functions: - They contribute to the homeostatic maintenance of the surrounding matrix -They are bone-forming cells. They produce the soft new bone matrix (osteoid) in a process called osteogenesis -They are stem cells that divide to produce the osteoblasts -They are bone-dissolving cells that secret acids and proteolytic enzymes that release the stored calcium (osteolysis)

  6. Osteocyte Concentric lamellae Osteon or Haversian system Circumferential lamellae Concentric lamellae Central or Haversian canal Central or Haversian canal Canaliculus Lacuna Periosteum Perforating or Volkmann’s canal Perforating or Sharpey’s fibers Blood vessel Compact Bone

  7. Spongy Bone • It has a sponge-like appearance • It provides strength with minimal weight. The trabeculae develop along bone’s lines of stress • The spongy bone consists of: • - slivers of bone called spicules • - thin plates of bone called trabeculae • - spaces filled with red bone marrow • - few osteons and no central canals • - all osteocytes close to bone marrow

  8. Bone Development Ossification or Osteogenesis is the formation of bone During ossification, deposit of calcium salts occurs (calcification), but calcification occurs also in other tissues. When calcification occurs in tissues other than bones, the result is calcified tissue that does not resemble bone. Ossification occurs during the whole life 1- Embryo: Formation of bonny skeleton 2- Until early adulthood: Bone growth 3- Adulthood: Remodeling and repair

  9. Fibrous membrane Hyaline cartilage Formation of the Bonny Skeleton Embryo skeleton before week 6 After week 6: Ossification begins Intramembranous Ossification (It produces the flat bones of the skull and clavicles) Ossification Endochondral Ossification (It produces most bones of the body)

  10. Intramembranous Ossification Condensation of mesenchyme into soft sheet permeated with blood capillaries Deposition of osteoid tissue by osteoblasts on mesenchymal surface; entrapment of first osteocytes; formation of periosteum 1 2 3 4 Honeycomb of bony trabeculae formed by continued mineral deposition; creation of spongy bone Surface bone filled in by bone deposition, converting spongy bone to compact bone. Persistence of spongy bone in the middle layer.

  11. Endochondral Ossification

  12. Endochondral Ossification 1 2 3 Early cartilage model Formation of the primary ossification center, bony collar, and periosteum Vascular invasion, formation of primary marrow cavity, and appearance of the secondary ossification center

  13. Endochondral Ossification 4 5 6 Bone at birth, with enlarged primary marrow cavity and appearance of the secondary marrow cavity in one epiphysis Bone of child, with epiphyseal plate at distal end Adult bone with a single marrow cavity and closed epiphyseal plate

  14. Endochondral Ossification All bones of the skeleton below the base of the skull, except the clavicles Intramembranous Ossification Cranial bones of the skull, mandible, and clavicles

  15. Calcium Homeostasis • Calcium is used for much more than bone structure. Calcium is needed in: 1- Neuron communication 2- Muscle contraction 3- Blood clotting • 4- Exocytosis Hypocalcemia: • It is a blood calcium deficiency Hypocalcemia causes an excess of excitability of muscle, tremors, spasms or tetany (inability to relax) • Hypocalcemia can result from: vitamin D deficiency, diarrhea, thyroid tumors, underactive parathyroids, pregnancy and lactation, accidental removal of parathyroid glands during thyroid surgery Hypercalcemia: • It is a blood calcium excess Hypercalcemia causes a deficiency of excitability of nerve and muscle (sluggish reflexes, depression)

  16. Calcium Homeostasis Calcium homeostasis is maintained by three hormones: 1- Parathyroid Hormone It is produced by the parathyroid glands when the concentration of calcium in the blood falls bellow normal 2- Calcitonin It is produced by the thyroid gland when the concentration of calcium in the blood rises above normal 3- Calcitriol (it is a form of vitamin D) It is an steroid hormone produced by the kidneys, which increases the concentration of calcium in the blood when it falls bellow normal

  17. It increases the osteoclast activity and inhibits the osteoblast activity. It also reduces the urinary calcium excretion Parathyroid hormone is released by parathyroid gland Blood concentration of calcium Blood concentration of calcium Blood concentration of calcium Calcitonin hormone is released by thyroid gland It inhibits the osteoclast activity and increases the osteoblast activity Blood concentration of calcium Calcium Homeostasis First Hormonal Mechanism Hypercalcemia Second Hormonal Mechanism Hypocalcemia

  18. Calcitonin

  19. 1- Calcitonin It is produced by the thyroid gland when the concentration of calcium in the blood rises above normal (Hypercalcemia) Correction for Hypercalcemia Ca+2

  20. 2- Parathyroid Hormone (PTH) It is produced by the parathyroid glands when the concentration of calcium in the blood falls bellow normal (Hypocalcemia) Ca+2 Ca+2 Ca+2 Calcitriol Ca+2

  21. Correction for Hypocalcemia

  22. Third Hormonal Mechanism 3- Calcitriol: It is 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: • 1- Increases calcium absorption by small intestine. • 2- Increases calcium resorption from the skeleton (increases stem cell differentiation into osteoclasts which liberates calcium and phosphate from bone). • 3- Promotes kidney reabsorption of calcium ions, so less lost in urine Calcitriol is necessary for bone deposition, which also needs adequate calcium and phosphate Abnormal softness of bones (rickets) in children and (osteomalacia) in adults without adequate vitamin D

  23. Calcitriol Synthesis and Action

  24. 3- Calcitriol It is produced by the sequential action of the skin, liver, and kidneyswhen the concentration of calcium in the blood falls bellow normal. Calcitriol Calcitriol Ca+2 Ca+2 Ca+2 Ca+2 Ca+2 Calcitriol

More Related