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• Loss of bone can occur in several situations including
  • Trauma
  • Tumours
  • Man-made prostheses
• Bone grafts can be used to fill the defect

Classification of bone grafts

• Autograft = bone from the same individual
• Allograft = bone from another individual of the same species
• Xenograft = bone from another species

Autografts

• Autogenous bone is the best graft material
• May only be available in a limited amount
• Also not suitable for significant load bearing
• Cancellous bone can be used to fill cavity defects
• Cortical bone can be used to provide structural support
• Forms scaffold into which osteoblasts and osteoclasts can grow
• Osteoblast differentiation leads graft resorption
• Stimulates local bone growth by the process of osteoinduction
• Remodelling occurs as load is applied to the graft

Harvesting of bone grafts

• Bone can be harvested from the following sites
  • Iliac crest
  • Proximal tibia
  • Distal radius
• Iliac crest is the most common but its use is associated with significant morbidity
• Cortico-cancellous grafts are harvested as strips
• Cancellous bone can be taken from the inner or outer table

Vascularised grafts

• Segments of bone can be transplanted as free vascularised grafts
• Local rotational bone grafts may also be used
• Blood supply to the graft is maintained
• Technically difficult to perform
• Results are unpredictable

Allografts

• Allograft bone is more plentiful
• Can be harvested from living donors or cadavers
• Donor site morbidity is eliminated
• Cadaveric bone and femoral heads are stored in tissue banks
• Bone is frozen at -20 to -86 degrees
• Freeze drying and storage at room temperature is occasionally used
• Used in reconstruction after:
  • Tumour resection
  • Revision hip surgery
• Infection is the major concern with the used of allografts
• Bacterial contamination may occur, especially with cadaveric grafts
• Can be eliminated with irradiation of the graft
• Viral contamination with hepatitis of HIV is a concern
• Bone should be kept in quarantine and living donors tested 90 days post surgery
• Allograft bone is available as:
  • Morsellised bone for impaction grafting
  • Strut grafts to cover cortical bone
  • Massive allografts to replace significant proportions of native bone

Bone substitutes

• Interest exists in artificial bone substitutes
• Would eliminate supply and infection problems associated with auto and allografts
• Possible bone substitutes include:
  • Calcium triphosphate
  • Hydroxyapatite
  • Calcium carbonate
  • Glass-based cements
• Most bone substitutes are brittle
• Unable to withstand significant load bearing

Bibliography

Finkemeir C G.  Bone-grafting and bone graft substitutes.  J Bone Joint Surg Am 2002;  84A:  454-464

Pairkh S N.  Bone graft substitutes in modern orthopaedics.  Orthopedics 2002;  25; 1301-1309

Rees D C,  Haddad F S.  Bone transplantation.  Hosp Med 2003;  64:  205-209

Last updated: 05 January 2008

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