Bone Response to Damage

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Bone Response to Damage

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Normal structure

Microscopic bone (Courtesy of RVC Histology images)

- 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

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

Physis (Growth plate)

Growth plate (Image sourced from Bristol Biomed Image Archive with permission)

Growth plate magnified(Image sourced from Bristol Biomed Image Archive with permission)

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

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

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