Objective To probe the repair method and effect of freesegmented-fibula transplantation to treat chronic osteomyelitis complicated by long bone defect in tibia in the first intention. Methods From March 1996 to December 2003, 67 cases of chronic osteomyelitis complicated by long bone defect were reconstructed with vascularized fibula graft after the long inflammable bone and soft tissue focus were resected. Their age ranged from 8 to 42 years. The course of disease was 6 months to 8 years. There were 14 cases of hematogenous osteomyelitis and 53 cases of traumatic osteomyelitis. Of them, 18 cases complicated by fracture of fibula; 21 cases by defect of skin ( 2 cm×4 cm-4 cm×10 cm) and bone exposure;53 cases by pathological fracture and nonunion; and 46 cases by 1-3 fistula of osteomyelitis. The length of bone defect was from 8 cm to 22 cm(mean 12 cm), andthegermiculture results of all cases were positive. Forty-six cases were treated with vascularized fibula graft, the other 21 cases with the skin flap. The segmentedfibula was 10-28 cm, skin flap size was 4 cm×7 cm6 cm×12 cm. Results After a follow-up of 12-45 months, the healing rate of sinus was 93.5% while the 6.5% remainders healed by the second sinus cleaning-up. The graft bone healed after 4-6 months(mean 4.2 months) by X-ray examination. The limb inflammation was controlled after 2 weeks.All 21 skin flaps all survived and the function recovery of affectedlimb was 79% of normal limbs according to Enneking evaluation system, but 2 patients occurred secondary fracture. The act or process of augmenting of tibia under 18-year-old cases were sooner than those who were more than 18-year-old. Conclusion It is a choice to repair the chronic osteomyelitis complicated by longbone defect with vascularized fibula graft in the first intention. The operation to reconstruct long bone defect is a good method to control inflammation efficiently, shorten period of treatment and reduce the time of operation.
Objective To design a combined flap of subscapular axis including vascularized lateral scapular,rib and latissimus dorsi to repair the large defect of tibia. Methods The patient was a 39-year-old man who got a posttraumatic 12 cm defect of tibiaafter primary debridement and external fixation because of open fracture 5 months ago. There was a 12 cm×6 cm scar involved the proximal medial segment of tibia.After resection of scar and fibular tissue over the bone defect floor, alatissimus dorsi myocutaneous flap 14 cm×5 cm pedicled with subscapular artery-thoracodorsal artery,a flap 12.5 cm on the outside of the scapular pedicled with thoracodorsal artery, and 6th rib flap 13 cm by serratus were prepared.The tibialis posterior and saphenous vein were used for astomosis. A proximalanatomic plate was applied to the fixation of tibia. Results Thecompound flap survived the operation. The follow-up period was 2 years. Bone union occurred 6 months after operation. Conclusion This combined flap is successful and can provide alternative to the resolution of large defect of tibia.
Objective To investigate the ability to repair goat tibia defect with marrow stromal stem cells (MSCs) and bio-derived bone, and the feasibility of the compounds as bone substitute material. Methods MSCs were cultured with the bioderived bone in vitro, and the 20 mm tibia defect of goat was made and fixedwith plate. Eighteen goats were divided into experimental group, control group and blankgroup. The defects were not filled with anything in blank group, with tissue engineering bone in experimental group and bio-derived bone in control group. Therepair capability was assessed by physical, X-ray and bone mineral density examinations8,12,16, and 24 weeks after operation. Results In experimental group, the defects were partially repaired 8 weeks, and completely repaired12 and 16 weeks; there was significant difference in bone density between experimental group and control group (P<0.05) 8,12 and 16 weeks, but no significant difference 24 weeks. The defects of blank group were not repaired 24weeks. Conclusion The tissue engineering bone can efficiently repair bone defect, and its repair capability is better than that of bio-derived bone alone both in quantity and quality of boneformation.