Difference between revisions of "Bone Response to Damage"
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===Normal structure=== | ===Normal structure=== | ||
[[Image:Bone micro structure.jpg|right|thumb|100px|<small><center>Microscopic bone (Courtesy of RVC Histology images)</center></small>]] | [[Image:Bone micro structure.jpg|right|thumb|100px|<small><center>Microscopic bone (Courtesy of RVC Histology images)</center></small>]] | ||
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Revision as of 10:08, 18 July 2008
Normal structure
Bone organisation
- Normal progression is from woven bone to lamellar bone, even in pathology, except for canine craniomandibular osteopathy and hypervitaminosis D, where lamellar bone is replaced by woven bone
- Patterns of collagen deposition:
- Woven bone:
- "Random weave" which is only a normal feature in the foetus
- Coarse collagen fibres
- Later removed by osteoclasts and replaced by lamellar bone
- In adults it is a sign of a pathological condition (e.g. fracture, inflammation, neoplasia)
- Lamellar bone:
- Orderly layers which are much stronger than woven bone
- Fine collagen fibres in concentric or parallel laminae
- Two main types:
- Compact bone (cortical)
- Forms 80% of total bone mass
- Consists of cells and interstitial substance - 30% ossein (type of collagen) and 70% minerals, especially calcium phosphate
- Forms the shell of long bone shafts - contain Haversian systems
- Cancellous bone (spongy or trabecular)
- Made up of plates, tubes or bars arranged in lines of stress
- In vertebrae, flat bones and epiphyses of long bones
- Contains no Haversian systems
- Compact bone (cortical)
- Laminar bone
- Formed on periosteal surface of diaphysis
- Accomodates rapid growth of large dogs and farm animals
- Plates of woven bone from within the periosteum
- Concentric plates
- As it forms, it fuses with the bone surface
- Woven bone:
Periosteum and blood supply
- Periosteum
- Specialised sheath of connective tissue covering bone except at the articular surfaces
- Loosely attached except at tendon insertions and boney prominences (associated with major blood vessels penetrating bone)
- Histologically:
- Outer layer - fibrous for support
- Inner layer - osteogenic
- Contains osteoblasts and osteoprogenitor stem cells in young animals and in adults with fractures or disease
- Rich supply of nerves and lymph vessels
- Damage to periosteum:
- Invokes a hyperplastic reaction of the inner layer
- Is painful
- Exostoses can remodel or remain
- Lifting of periosteum:
- Causes new bone formation below
- Circumferential incision (e.g. during fracture)
- Longitudinal bone growth results
- May be only on one side where periosteum is damaged
- Used by surgeons to treat angular limb deformities
- Blood vessels
- Nutrient, metaphyseal, periosteal arteries
- Normal flow of blood from medulla to periosteum due to higher pressures in medulla
- Young animals have greater blood supply
- Endosteum lines the marrow cavity
Bone development
- Two main types of bone development:
- Endochondral ossification (cartilage model)
- Long bones mainly - physis and metaphysis
- Mesenchymal cells differentiate into chondroblasts
- Produce scaffold of mineralised cartilage on which osteoblasts deposit bone
- Vascularised
- Developed centres of ossification
- Primary (diaphyseal)
- Secondary (epiphyseal)
- Intramembranous ossification
- Flat bones mainly (e.g. skull), shaft of long bones
- Mesenchymal cells differentiate into osteoblasts
- No cartilage precursor template
- Endochondral ossification (cartilage model)
Physis (Growth plate)
- Originates from the cartilage model that remains only at the junction of the diaphyseal and epiphyseal centres
- Cartilage of metaphyseal growth plate is divided into: (from right to left on the magnified image)
- - Resting (reserve) zone
- - Proliferative zone
- - Hypertrophic zone
- Site of many congenital or nutritional bone diseases in the growing animal
- Open in neonates and growing animals
- Chondrocyte proliferation balances cell maturation and death
- Closes and ossifies at maturity
- Regulated by androgens
- If growth teporarily stops -> layer of bone seals the growth plate -> moves into metaphysis when growth resumes -> forms Harris lines
Bone resorption
- Mediated by two hormones:
- Parathyroid hormone (PTH)
- Produced by chief cells in the parathyroid glands in response to decreased serum calcium
- In response, osteoclasts increase in number and resorb mineralised matrix - increase Ca in blood
- Calcitonin
- Produced by C-cells in the thyroid glands in response to increased serum calcium
- Inhibits osteoclasts
- Parathyroid hormone (PTH)
Bone dynamics
- Bone growth and maintenance of normal structure are directly related to mechanical forces
- Mechanical forces generate bioelectrical potentials (piezoelectricity)
- These potentials strengthen bone
- Inactivity reduces the potentials -> bone loss
- In neonates:
- Bone growth predominates
- Modelling is important
- In adults:
- Formation of bone is balanced by resorption - remodelling
- Continues throughout life under the influence of hormones and mechanical pressure
- Bone resorption may exceed formation in pathological states (hormonal, trauma, nutritional) or in old age and disuse