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Published byLily Day Modified over 6 years ago
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Bones are alive Living bones: Form Grow Repair Remodel
Move at joints (with help from muscles)
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Skeletal System – Normal Function
Movement Protection Normal Function Support Mineral Storage Blood Cell Production
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Bone Types
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Long Bone – Macroscopic Anatomy
Epiphysis (end) covered with hyaline cartilage compact bone forms exterior spongy bone forms interior contains epiphyseal line/plate Diaphysis (middle) center composed of the medullary cavity containing yellow or red marrow. Marrow helps produce red blood cells. Fig 7.1
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Long Bone – Macroscopic Anatomy
Fig 7.2
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Microscopic Anatomy Osteon = circular structure organized around blood vessels Osteocyte = bone cells Bone matrix = hard calcium-based material between cells Fig 7.3
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Tissue Types – Compact Bone
Functions Hard and provides stability, framework, protection Structure Matrix has hard mineral structure, based on calcium Cells and matrix are arranged in regular, concentric pattern Compact Bone
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Tissue Types – Spongy Bone
Functions Lightens total bone weight and provides space for bone marrow Structure Matrix is softer mineral, less organized and less of it Empty spaces between matrix structure are filled with bone marrow Spongy (cancellous) Bone
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Spongy Bone
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Tissue Types – Hyaline Cartilage
Functions Provides soft and smooth covering to end of bone (articular surface) Helps provide smooth and easy movement between bones (at joints) Provides the starting material for new bone growth Structure Matrix is gelatinous with fibers and is evenly distributed between the cells Cells (chrondocytes) are found in pairs within capsules called lacunae Hyaline Cartilage
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Bone Physiology Living bones perform the following processes:
Formation Starts as an embryo, continues through fetal development and after birth Growth Occurs from before birth through maturity Remodel Old matrix is removed and replaced with new matrix Repair Damaged bones will heal and return to normal structure
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Bone Physiology – Formation
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Bone Physiology – Formation
Fetal bones are made of hyaline cartilage As cartilage cells die, they are replaced with spongy bone in diaphysis After birth, spongy bone invades diaphysis Compact bone replaces spongy bone in diaphysis Hyaline cartilage remains on epiphyseal surface and in growth plate Fig 7.5
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Epiphyseal plate -cartilage band indicates ossification is occurring and spongy bone is being deposited
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X Ray in Newborn
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Bone Physiology - Repair
Hemotoma, a mass of clotted blood, forms at the fracture site. A fibrous callus forms, and cartilage matrix is secreted. Spongy bone forms to replace cartilage. Bone remodeling occurs to remove excess material and replace compact bone.
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Bone Physiology - Remodeling
Bone matrix is inorganic and breaks down over time Specific bone cells (osteoclasts) remove old, broken matrix Other bone cells (osteoblasts) re-make/deposit new matrix The entire skeleton is re- modeled every 7-10 years Remodeling slows with age, elderly people have thinner bones and are more susceptible to broken bones as a result
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Aging and Bone Tissue There are two principal effects of aging on bone tissue: 1) Loss of bone mass Results from the loss of calcium from bone matrix The loss of calcium from bones is one of the symptoms in osteoporosis 2) Brittleness Results from a decreased rate of protein synthesis Collagen fibers gives bone its tensile strength The loss of tensile strength causes the bones to become very brittle and susceptible to fracture
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Osteoporosis
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