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Published bySophie Howard Modified over 8 years ago
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Is the framework of the body Provides shape to the body and protection for organs and soft tissues Consists of cartilage, bones, tendons and ligaments Functions Support: Bone is hard and rigid, bears body weight Cartilage provides firm and flexible support, such as cartilage in nose, external ear, thoracic cage and trachea Ligaments attach bone to bone & hold them together Protection: Bones of skull protects brain Ribs, sternum, vertebrae protect organs of thoracic cavity
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Movement: Skeletal muscles attach to bones by tendons Contraction of skeletal muscles moves the bones, produce body movement Storage: Ca and P. Stored then released as needed. Fat stored in marrow cavities Blood cell production: Blood cells and platelets formation takes place in bone marrow of bones
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Basic Structure of Skeletal Cartilage Consists mostly of water – accounts for resilience contains no nerves and blood vessels Surrounded by double layer of dense irregular connective tissue – Perichondrium Outer layer: Contains fibroblasts Inner layer: More delicate, has fewer fibers, contains chondroblasts and chondrocytes Blood vessels and nerves penetrate the outer layer of pericardium but do not enter cartilage matrix Nutrients diffuse through matrix to reach chondrocytes
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Growth of Cartilage: Cartilage grows in two ways: Appositional growth – Add new matrix and chondrocytes to the outside of tissue Interstitial growth – Chondrocytes within the tissue divide and add more matrix between the cells
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Types of Skeletal Cartilage: Hyaline, Elastic and Fibrocartilage Hyaline Cartilage: Contains fine collagen fibers in matrix, Include Articular cartilages : cover the ends of bones at movable joints Costal cartilages: connect the rib to sternum Respiratory cartilages: forms skeleton of larynx Nasal cartilages: support external nose Elastic Cartilage: Contains collagen and elastic fibers - external ears and epiglottis Fibrocartilage: Thick bundles of collagen fibers, compressible and tough Found in Menisci and intervertebral discs
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Human skeleton consists of 206 bones And divided into two groups: Axial Skeleton: Consists of skull bones, vertebral column and rib cage Protect and support body parts Appendicular Skeletan: Consists of bones of upper and lower limbs and girdles ( shoulder and hip bones) Bones of limbs – help in movement
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Bones are classified by their shape as long, short, flat and irregular Long Bones: Are long and thin Are found in arms, legs, hands, feet, fingers, and toes Flat Bones Are thin, flattened shape, usually curved Are found in the skull, sternum, ribs, and scapula
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Irregular Bones Have complex shapes Examples: –spinal vertebrae –pelvic bones Short Bones Are small and thick Examples: –ankle –wrist bones
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Three levels of structure: Chemical Gross Microscopy
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Consists of both organic and inorganic components Organic components include: Cells ( Osteoprogenitor cells, osteoblasts, osteocytes and osteoclasts) and Osteoid, the organic part of the matrix Osteoid (35%) consists mainly of collagen and proteoglycans Inorganic components 65% of bone tissue is calcium phosphate crystal called hydroxyapatites, CaPO 4 crystals
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Bone Markings Most bones contain features on external surface Depressions and openings along bone surface, passage for blood vessels and nerves Projections where tendons and ligaments attach and at articulations with other bones Include heads, trochanters, spines etc.
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Bone tissue is classified as woven or lamellar bone based on collagen fibers organization within bone matrix Woven bone. Collagen fibers randomly oriented. –First formed During fetal development During fracture repair –Then Woven bone is remodeled into lamellar bone Lamellar bone –Mature bone, organized in sheets called lamellae. Collagen fibers are oriented in one direction in each layer, but in different directions in different layers for strength.
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Bones, whether woven or lamellar can be classified according to amount of bone matrix relative to amount of space Compact bone: Contains dense outer layer, less space Cancellous or spongy bone: Has less bone matrix & more space Consists of interconnecting rods or plates of bones called trabeculae
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Diaphysis –Shaft, long axis of bone –Made up of Compact bone – Surrounds central medullar or marrow activity – Red marrow - blood cell formation – Yellow marrow – adipose tissue Epiphysis –End of the bone –Cancellous bone –Joint surface of epiphysis is covered with articular (hyaline) cartilage, cushions the bone ends – Epiphyseal plate: growth plate – Growth in length occurs at E. plate –Separates epiphysis from diaphysis –When bone stops growing in length becomes Epiphyseal line
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Membranes External surface of bone is covered by double layer membrane called Periosteum –Fibrous layer – Outer fibrous layer is dense irregular connective tissue contains blood vessels and nerves –Cellular layer – Inner single layer of bone cells consists of osteoblasts, osteoclasts, osteochondral progenitor cells –Periosteum is attached to underlying bone by Perforating or Sharpey`s fibers, made up of collagen –Periosteum provides anchoring points for tendons and ligaments
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Membranes Endosteum: Single layer of cells that lines all internal spaces, such as medullar cavity Contains osteoblasts, osteoclasts, osteochondral progenitor cells
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Structure of Flat, Short, and Irregular Bones Flat Bones –No diaphyses, epiphyses –Sandwich of cancellous between two layers of compact bone, eg. Parietal bone of skull Short and Irregular Bone –Similar to structure of epiphyses of long bones –Compact bone that surrounds cancellous bone center with small spaces filled with marrow –Are not elongated and no diaphyses
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Hematopoietic tissue, red marrow is found in trabeculae of spongy bone of long bones, diploe of flat bones (sternum) and in some irregular bones (hip bones)
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Four major type of Bone cells –Osteoblasts –Osteocytes –Osteoclasts –Stem cells or osteochondral progenitor cells
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Osteoblasts Immature bone cells that secrete organic components of matrix known as Osteoid Osteoblasts surrounded by bone matrix, as the material calcifies, the cell is trapped in a space called a lacuna And becomes osteocytes (mature bone cells)
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Osteocytes Mature bone cells that maintain the bone matrix Live in lacunae Are between layers (lamellae) of matrix Connect by cytoplasmic extensions through canaliculi in lamellae Do not divide Maintains protein and mineral content of matrix Helps repair damaged bone
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Osteoclasts Giant, mutlinucleate cells Secrete acids and protein- digesting enzymes Breakdown bone by dissolving bone matrix
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Osteoprogenitor Cells Mesenchymal stem cells that divide to produce osteoblasts Are located in inner layer of perichondrium, inner layer of periosteum and endosteum Assist in fracture repair
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Cancellous (Spongy) Bone Consists of interconnecting rods or plates of bone called Trabeculae No blood vessels in trabeculae The space between trabeculae is filled with red bone marrow: –which has blood vessels –forms red blood cells –and supplies nutrients to osteocytes
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Compact Bone The basic unit of mature compact bone is Osteon or Haversian system Osteon is a group of hollow tubes of bone matrix, one placed outside the next Osteon consists of single central canal and around a canal contains blood vessels Osteocytes are arranged in concentric lamellae
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Perforating (Volkmann`s )Canals Perpendicular to the central canal Carry blood vessels into bone and marrow Circumferential Lamellae Present on outer surface of compact bone Binds osteons together Interstitial Lamellae Present in between osteons Compact Bone
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Bone formation during fetal development occurs in two patterns: Intramembranous ossification –Takes place in connective tissue membrane Endochondral ossification –Takes place in cartilage Both methods of ossification –Produce woven bone that is then remodeled –After remodeling, formation cannot be distinguished as one or other
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Takes place in fibrous connective tissue membrane formed from embryonic mesenchyme cells around the developing brain Starts at 8 th week & completes by age 2 Forms many skull bones, part of mandible, diaphyses of clavicles Mesenchyme cell in the membrane become osteochondral progenitor cell Osteochondral progenitor cell forms osteoblast
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Osteoblast produce bone matrix and collagen fiber And become osteocyte and develop trabeculae More osteoblast gather around trabeculae and produce more bone Trabeculae join together and form cancellous bone
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Cells in the spongy cell produce red bone marrow Cells surrounding the developing bone forms periosteum Osteoblasts from the periosteum on bone matrix produce compact bone
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Bones of the base of the skull, part of the mandible, epiphyses of the clavicles, and most of remaining bones develop through endochondral ossification Mesenchyme cells develop into chondroblasts which secrete the matrix of hyaline cartilage & surrounded by perichondrium except where joint formation takes place
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Chondroblasts becomes chondrocytes; Chondrocytes in the center of hyaline cartilage: –Enlarge, calcify, and die, leaving cavities in cartilage Blood vessels grow around the edges of the cartilage and osteochondral progenitor cells in the perichondrium change to osteoblasts Perichondrium becomes periosteum when osteoblasts begin to form bone –Osteoblast produce compact bone on the surface of cartilage and forms the Bone collar
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Blood vessels enter the cartilage Connective tissue surrounding the blood vessels bring osteoblasts and osteoclasts Osteoblasts secrete bone matrix and changes the calcified cartilage of diaphysis into cancellous bone Bone formation area – Primary ossification center Osteoclasts remove the bone from center and forms medullar cavity – Forms red bone marrow
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Capillaries and osteoblasts enter the epiphyses creating secondary ossification centers Epiphyses fill with spongy bone: – All the cartilage is replaced by bones except in epihhyseal plate and an articular sufaces In mature bone, compact and cancellous bone are fully developed and epiphyseal plate becomes epiphyseal line
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Bones increase in size only by Appositional growth Formation of new bone takes place on the surface of older bone or cartilage Growth in Bone Length Growth in bone length occurs at the epiphyseal plate Growth at epiphyseal plate involves the formation of new cartilage by –Interstitial cartilage growth –Followed by Appositional bone growth on the surface of the cartilage
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Epiphyseal plate is organized into 4 zones: Zone of Resting Cartilage: Nearest to epiphysis, contains randomly arranged chondrocytes Do not involve in bone growth Zone of Proliferation: Contains actively dividing chondrocytes Chondrocytes produce new cartilage through interstitial cartilage growth As the cells divide, the epiphysis moves away from the diaphysis. This in turn produces length growth in bone
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Zone of Hypertrophy: Contains mature and enlarge chondrocytes Zone of Calcification: Matrix is calcified, chondro- cytes die Calcified cartilage is replaced by bone
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Growth at articular cartilage increases the epiphyses size Also growth at articular cartilage increases size of bones with no epiphyses: e.g., short bones Articular cartilage persists throughout life and does not ossified as epiphyseal plate
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Bones increases in thickness or long bones increase in width, because appositional bone growth takes place beneath periosteum
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Size and shape of a bone determined genetically but can be modified and influenced by nutrition and hormones Nutrition –Lack of calcium, protein and other nutrients during growth and development can cause bones to be small Vitamin D –Necessary for absorption of calcium from intestines –Can be eaten or manufactured in the body when skin is exposed to sunlight –Rickets: lack of vitamin D during childhood Have bowed bones –Osteomalacia: lack of vitamin D during adulthood leading to softening of bones
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Vitamin C Necessary for collagen synthesis by osteoblasts Scurvy: deficiency of vitamin C, causes hemorrhage because of lack of collagen deficiency Lack of vitamin C also causes wounds not to heal, teeth to fall out
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Bone Remodeling: Old bone is replaced with new bone Osteoclasts remove old bone and osteoblast forms new bone Bone remodeling converts woven bone into lamellar bone And involve in bone growth, changes in bone shape, adjustments in bone due to stress, bone repair, and Ca ion regulation Caused by migration of Basic Multicellular Units –Groups of osteoclasts and osteoblasts that remodel bones Bone constantly removed by osteoclasts and new bone formed by osteoblasts
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Bone undergo repair after damage Has four major steps: Hematoma formation: Bone fracture damages blood vessels in bone & periosteum and hematoma forms Hematoma - Localized mass of blood released from blood vessels, Clot formation stop the bleeding Inflammation and swelling occurs after injury
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Callus formation. Callus is mass of tissue that forms at a fracture site and connects the broken ends of the bone Internal Callus – Forms between the ends of broken bones Several days after fracture blood vessels grow into clot Macrophages clean up debris, osteoclasts break down dead bone tissue, fibroblasts produce collagen and helps in put the bone together Osteoprogenitor cells from the periosteum of healthy bone tissue produce Chondroblasts - which secrete cartilage tissue Ostoeblasts - which secrete bone matrix New bone is formed
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External Callus – Forms collar around opposite ends of bone fragments Periosteal osteochondral progenitor cells osteoblasts and chondroblasts Produce bones and cartilage
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Callus ossification: Callus replaced by woven, cancellous bone Bone remodeling: Replacement of woven bone and damaged material by compact bone
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Bone is major storage site for calcium The level of calcium in the blood depends upon movement of calcium into or out of bone –Calcium enters bone when osteoblasts create new bone; calcium leaves bone when osteoclasts break down bone –Two hormones control blood calcium levels- parathyroid hormone and calcitonin
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Parathyroid hormone (PTH) Major regulator of blood Ca+ level If blood Ca + level decreases, secretion of PTH increases, increases osteoclast no. Causes increase bone breakdown and increases blood Ca + level Calcitonin Increase in blood Ca+ level stimulates thyroid gland and secrete calcitonin and inhibits osteoclast activity
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Bone matrix decreases and bone is more brittle due to decreased collagen production; but also less hydroxyapatite Bone mass: Highest around 30. Men denser due to testosterone and greater weight. African Americans and Hispanics have higher bone masses than Caucasians and Asians. Rate of bone loss increases 10 fold after menopause (estrogen production decreases), Cancellous bone lost first, then compact Increased bone fractures Bone loss causes deformity, loss of height, pain, stiffness –Stooped posture –Loss of teeth
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