Oral 1
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- Alveolar processParts of the maxilla and mandible that form and support the tooth sockets
- Alveolar socketCavity within the alveolar bone in which the root of the tooth is held by the periodontal ligament
- Disappears with loss of tooth
- Interdental septumAlveolar bone between the roots of adjacent teeth
- Inter-radicular septumAlveolar bone between the roots of multi-rooted teeth
- Alveolar bone is subjected to continual and rapid remodeling associated with tooth eruption and subsequently the functional demands of mastication
- Anatomically, no distinct boundary exists between the body of maxilla or the mandible and their respective alveolar bone
- Alveolar crestFound 1.5-2.0 mm below the level of the CEJ
- If you draw a line connecting the CE junctions of adjacent teethThis line should be parallel to the alveolar crest. If the line is not parallel, then there is high probability of periodontal disease
- Chemical composition of alveolar bone
- 67% inorganic: hydroxyapatite crystals
- 33% organic materials, mainly collagen fibers (28%) which lies in a ground substance of glycoproteins and proteoglycans with small amount of noncollagenous proteins (5%)
- HydroxyapatiteDeposited in between the molecules of collagen as well as in the ground substance of bone
- Enzymes that participate in the precipitation of hydroxyapatite crystalsAlkaline phosphatase and pyrophasphatase
- Functions of alveolar bone
- Houses the roots of teeth
- Anchors the roots of teeth to the alveoli
- Helps to move the teeth for better occlusion
- Absorbs and distribute occlusal forces (tooth contact)
- Supplies vessels to pdl
- Houses & protect developing permanent teeth while supporting primary teeth
- Organizes eruption of primary and permanent teeth
- Development of alveolar process1. At the end of 2nd month of fetal life, the maxilla as well as mandible forms a groove that open to surface of oral cavity2. Tooth germs develop within the bony structures at late bell stage3. Bony septa and bony bridge begin to form and separate the individual tooth germs from one another, keeping individual tooth germs in clearly outlined bony compartments4. Along with tooth germs, alveolar nerves and vessels are also present5. Dental follicle surrounds each tooth germ, which is located between tooth germs and its bony compartment6. As roots develop, the alveolar process increases in height7. Cells in the dental follicle start to differentiate into periodontal ligament and cementum8. Cells in the dental follicle differentiate into osteoblasts and form alveolar bone proper
- Alveolar bone properConsists of bundle bone and lamellated bone
- Supporting alveolar boneConsists of cortical bone and spongy bone
- The cortical plate and alveolar bone proper meet at the alveolar crest (usually 1.5-2 mm below the level of the C.E.J. on the tooth it surrounds)
- Cortical boneThe outer (labial or buccal) and inner (lingual) plates of the alveolar process, consisting of compact bone
- Alveolar bone properThe inner wall of the sockets, providing attachment for the fibers of the periodontal ligament (Sharpey's fibers), developed from the dental follicle
- Alveolar bone proper
- Perforated by many foramina transmitting nerves and blood vessels, also called the cribriform plate
- Increased radiodensity due to thick bone without trabeculae, also called the lamina dura
- Bundle bone
- Coarse fibered bone with fibers running parallel to the socket wall and arranged in lamellae
- Bundles of Sharpey's fibers embedded at right angles to the fibers
- Lamellated bone
- Thicker layer of lamellar bone formed of longitudinal lamellae, lying between the bundle bone and the supporting spongiosa
- Supporting alveolar boneBone that forms the labial and lingual covering of the alveolar bone proper
- Cortical plate
- Consists of longitudinal lamellae and Haversian systems, dense and continuous with the compact bone of the jaw bodies
- In the maxilla, perforated by openings for blood and lymph vessels
- In the anterior teeth region, very thin with no spongy bone, fused with the alveolar bone proper
- Spongy/cancellous bone (Supporting spongiosa)
- Fills the space between the alveolar bone proper and cortical plates
- In the anterior teeth and alveolar crest regions, very thin or absent
- Types of spongy bone
- Type I: Trabeculae arranged horizontally in a regular ladder-like manner, more common in the mandible and more resistant to masticatory forces
- Type II: Trabeculae show irregular arrangement, more numerous and delicate, common in the maxilla
- Spongy bone
- Consists of trabeculae of various sizes and shapes, enclosing irregular medullary cavities containing bone marrow
- Marrow spaces contain mainly fatty tissue with infrequent islands of red blood cells
- Red marrow transforms to fatty marrow with age, persisting only in the distal part of the upper third molar, condyle head, and mandibular angle
- Bone cells include osteoprogenitor cells, which are undifferentiated mesenchymal cells located in the periosteum and endosteum
- Spongy bone
- Irregular arrangement of bone trabeculae enclosing irregular medullary cavities containing bone marrow
- Marrow contains mainly fatty tissue with infrequent islets of red blood cells
- Red bone marrow transforms into fatty marrow with age, persisting only in distal part of last upper molar, head of condyle, and mandibular angle
- Type 2 bone
- Bone trabeculae have more irregular arrangement and are more sensitive
- Common in maxilla
- Bone cells
- Osteoprogenitor cells
- Osteoblasts
- Osteocytes
- Osteoclasts
- Osteoprogenitor cells
- Undifferentiated mesenchymal cells in deepest layer of periosteum and lining Haversian canals
- Capable of dividing and giving rise to other bone cell types
- Morphologically resemble mesenchymal cells with pale staining elongated nucleus and eosinophilic cytoplasm
- Osteoblasts
- Responsible for bone formation, found on bone surface when bone matrix is being deposited
- Secrete osteoid tissue which is later mineralized by osteoblasts to form bone
- Elongated cell with basophilic cytoplasm
- Strong alkaline phosphatase activity in cytoplasm
- Contain well-developed rough endoplasmic reticulum and Golgi apparatus typical of protein secretory cells
- Osteocytes
- Principal cells of bone tissue, trapped in bone
- Cell bodies in lacunae, processes in canaliculi
- Morphologically similar to osteoblasts
- Metabolically active, maintain bone tissue and play role in mineral storage
- Osteoclasts
- Located on bone surface where resorption is occurring
- Large multinucleated cells in Howship's lacunae, likely derived from circulating monocytes or osteoprogenitor cells
- Phagocytic cells with numerous nuclei, foamy eosinophilic cytoplasm, and many lysosome vacuoles
- Portion of plasma membrane adjacent to bone has ruffled borders
- Bone formation and growth1. Bones grow until age 252. Process of bone formation/osteogenesis is called ossification3. Two main forms of ossification: endochondral (within cartilage) and intramembranous (in flat bones, mainly skull)
- Endochondral ossification1. Formation of cartilage template2. Chondrocyte hypertrophy in area surrounded by bone collar, then apoptosis3. Vascularization, invasion of osteoblast precursors4. Osteoblasts differentiate and replace cartilage with bone
- Intramembranous ossification1. Occurs in flat bones, mainly skull2. Mesenchymal cells form clusters of osteoprogenitors that differentiate in place into osteoblasts which form bone
- Bone resorption1. Decalcification of inorganic material by osteoclasts secreting organic acids2. Degradation of organic matrix by lysosomal acid proteases and collagenase enzymes secreted by osteoclasts3. Transport of soluble products to extracellular fluid or blood
- Decalcification of inorganic material1. Secretion of organic acids (mainly citric and lactic acid) by osteoclasts at the ruffled border2. Chelation of bone3. Increase solubility of hydroxyapatite