Bone Growth and Fractures Flashcards
Describe endochondral ossification.
Bone is formed onto temporary cartilage model
Cartilage model grows then chondrocytes mature and hypertrophy and growing cartilage model starts to calcify
Chondrocytes far from blood vessels less able to gain nutrients so start to died. Fragmented calified bone matrix left behind acts as structural framework for bony material
Osteoprogenitor cells and blood vessels from periosteum invade the area, proliferate and differentiate into osteoblasts which start to lay down bone matrix (in the primary ossification center first in the shaft, and then in the secondary ossification center in the epiphysis)
Describe the process of cessation of bone growth.
- Growth in height ceases at the end of puberty
- Sex steroids stimulate growth spurt but promote closure of epiphyseal plates
- Growth in length ceases, cell proliferation slows and plate thins
- Plate is invaded by blood vessels, epiphyseal and diaphyseal vessels unite
- May leave a line visible on x rays
How many ossification centers are there in bone ?
Some have only one
• Carpals, tarsals, ear ossicles
Most bones have 2+
• Head of humerus has 3
Why are ossification centers clinically important ?
- Appearance in age varies, so allows estimate of skeletal vs chronological age (can radiologically estimate age)
- Represent areas of bone that are subject to damage or trauma (area of growth plate damage)
Is the rate of growth of different bones the same ? Explain.
No, rate of growth varies
• From bone to bone
• Within same bone
Identify the zones of the epiphyseal plate, describing each.
“Ossification zone: Osteoclasts and osteoblasts from the diaphysial side break down the calcified cartilage and replace with mineralized bone tissue.
Calcification zone: Chondrocytes undergo apoptosis. Cartilaginous matrix begins to calcify.
Hypertrophic zone: Chondrocytes stop mitosis, and begin to hypertrophy
Proliferating (growth) zone: Chondrocytes undergo rapid mitosis
Resting zone: Quiescent chondrocytes are found at the epiphyseal end”
Identify the function of the resting zone of the epiphyseal plate, a possible disease associated with it, and the underlying defect.
RESTING ZONE
Function: Matrix Production
Example of disease: Diastrophic dwarfism
Defects: Defective collagen synthesis/ processing of proteoglycans
Identify the function of the growth zone of the epiphyseal plate, a possible disease associated with it, and the underlying defect.
GROWTH ZONE
Function: Cell Proliferation
Example of disease: Achondroplasia, Malnutrition, Irradiation injury
Defect: Deficiency in cell proliferation and/or matrix synthesis
Example of disease: Gigantism
Defect: Increased cell proliferation
Identify the function of the hypertrophic zone of the epiphyseal plate, a possible disease associated with it, and the underlying defect.
HYPERTROPHIC ZONE
Function: Calcification of matrix
Example of disease: Rickets (More common in children), osteomalacia (more common in adults)
Defect: Insufficiency of calcium or phosphate for normal calcification
Identify the function of the metaphysis of the epiphyseal plate, a possible disease associated with it, and the underlying defect.
METAPHYSIS
Function: Bone formation and vascularisation
Example of disease: Osteomyelitis
Defect: Bacterial infection
Example of disease: Osteogenesis imperfecta
Defect: Abnormality of osteoblasts and collagen synthesis
Example of disease: Scurvy
Defect: Inadequate collagen turnover
Normal growth and development of bone requires ___ (more than one thing) ? Can these affect healing of bone ?
– Calcium
– Phosphorus
– Vitamins A, C and D
– Balance between growth hormone, thyroid and parathyroid hormones, oestrogen and androgens
Yes, abnormalities in these can have an effect on fracture healing
Identify the following for cortical bone.
- Other names
- Percentage of human bones
- Location
- Structure
- Function
- Periosteum thickness
- Turnover rate
- Blood supply
- Fracture patterns
- Other names: Cortical bone, compact bone
- Percentage of human bones: 80%
- Location: Shaft of long bones
- Structure: Concentrically arranged lamellae - Haversian systems
- Function: Mechanically strong
- Periosteum thickness: Thick
- Turnover rate: Slow
- Blood supply: Slow
- Fracture patterns: Direct or indirect violence may result in deficits at the fracture site leading to non-union.
Identify the following for cancellous bone.
- Other names
- Percentage of human bones
- Location
- Structure
- Function
- Periosteum thickness
- Turnover rate
- Blood supply
- Fracture patterns
- Other names: Cancellous bone, trabecular bone
- Percentage of human bones: 20%
- Location: Ends of long bones, vertebral bodies, flat bones
- Structure: Meshwork of trabeculae with intercommunicating spaces
- Function: Metabolic
- Periosteum thickness: Thin
- Turnover rate: Rapid
- Blood supply: Rich
- Fracture patterns: Honeycomb structure fails as the result of compression (e.g. a fall from height compacts the bone)
What are the factors making up mechanism of injury ? Why is this important ?
1) Direction of force
– Direct v angular
– Rotational
– Compression
2) Energy transfer
– Cause
– Site
Important because it determines the likely type of fracture and the likelihood/time frame of recovery.
What information does bone imaging, with regards to a fracture ?
• Site & bones involved • Clues on soft tissue injury • Clues on energy transfer: – Wide displacement – Comminuted – Multiple fracture sites • Pathological bone (bone fracture caused by disease that led to weakness of the bone structure, such as cancer or osterporosis) • Paediatric bone (greenstick fracture, fracture due to energy transfer onto hands/wrists upon falling)