ObjectiveTo review the research progress of cementless intercalary prosthesis stem. MethodsThe literature about the cementless intercalary prosthesis in treatment of bone defects of extremities was reviewed, and the designing and application of prosthesis stem were analyzed. ResultsCementless intercalary prosthesis has the advantages of good biocompatibility. However, there are also some disadvantages, including the multiple factors affecting the fixation of the prosthesis stem and individual differences in the stability of the prosthesis. The methods to improve the fixation stability of prosthesis stem mainly include the optimization of prosthesis stem shape, addition of auxiliary fixation, and improvement of coating materials on the stem surface as well as porous structure of the stem surface. Among these methods, augment with auxiliary fixation has the most satisfactory effect on improving the stability of prosthesis. However, the deficiency of the method is the increasing risk of the larger incision exposure and surgical trauma. ConclusionImproving the design and fixation method of the cementless intercalary prosthesis stem can further improve the stability of the prosthesis. Under the premise of avoiding increasing surgical trauma as much as possible, addition of the auxiliary fixation can be a feasible choice to improve the fixation stability of prosthesis.
ObjectiveTo investigate the effectiveness of tibial periosteal flap pedicled with intermuscular branch of posterior tibial vessels combined with autologous bone graft in the treatment of tibial bone defects. MethodsBetween January 2007 and December 2013, 19 cases of traumatic tibia bone and soft tissue defects were treated. There were 14 males and 5 females, aged from 18 to 49 years (mean, 28 years). The tibial fracture site located at the middle tibia in 6 cases and at the distal tibia in 13 cases. According to Gustilo type, 4 cases were rated as type Ⅲ A, 14 cases as type Ⅲ B, and 1 case as type Ⅲ C (injury of anterior tibial artery). The length of bone defect ranged from 4.3 to 8.5 cm (mean, 6.3 cm). The soft tissue defects ranged from 8 cm×5 cm to 17 cm×9 cm. The time from injury to operation was 3 to 8 hours (mean, 4 hours). One-stage operation included debridement, external fixation, and vacuum sealing drainage. After formation of granulation tissue, the fresh wound was repaired with sural neurovascular flap or posterior tibial artery perforator flap. The flap size ranged from 10 cm×6 cm to 19 cm×11 cm. In two-stage operation, tibial periosteal flap pedicled with intermuscular branch of posterior tibial vessels combined with autologous bone graft was used to repair tibial defect. The periosteal flap ranged from 6.5 cm×4.0 cm to 9.0 cm×5.0 cm; bone graft ranged from 4.5 to 9.0 cm in length. External fixation was changed to internal fixation. ResultsAll flaps survived with soft texture, and no ulcer and infection occurred. All incisions healed by the first intention. All patients were followed up 18-40 months (mean, 22.5 months). All graft bone healed, with the healing time from 3 to 9 months (mean, 6.5 months). No complication of implant loosening or fracture was observed. No pain and abnormal activity in the affected leg occurred. All patients resumed weight-bearing and walking function. The length of the limb was recovered and difference value was 0.5-1.5 cm between normal and affected sides. The function of the knee and ankle joint was good without infection, malunion, and equinus. According to the Johner standard at last follow-up, the results were excellent in 15 cases, good in 3 cases, and fair in 1 case, with an excellent and good rate of 94.7%. ConclusionTibial periosteal flap pedicled with intermuscular branch of posterior tibial vessels combined with autologous bone graft is an effective method to treat bone defect of the tibia.
ObjectiveTo discuss the effectiveness of free anterolateral thigh flap pedicled with medial sural vessels for treatment of leg skin and soft tissue defects. MethodsBetween July 2008 and January 2014, 32 cases of serious skin and soft tissue defects in the leg were repaired by using free anterolateral thigh flap pedicled with medial sural artery and vein. Of them, there were 22 males and 10 females, aged 23 to 50 years (mean, 36.5 years). Defects were caused by traffic accidents injury in 9 cases, crash injury of heavy object in 15 cases, and machine twist injury in 8 cases. The left side was involved in 10 cases and the right side in 22 cases. The mean interval of injury and admission was 2.5 hours (range, 1-4 hours). The location was the upper, middle, and lower one third of the anterior tibia in 15 cases, 10 cases, and 7 cases respectively. The area of defect ranged from 10 cm×5 cm to 23 cm×9 cm. After debridement and vaccum sealing drainage treatment, the anterolateral thigh flap ranging from 12 cm×7 cm to 25 cm×11 cm pedicled with the medial sural vessels was used to repair the wound. The donor site was sutured directly or repaired with the skingrafts. ResultsAll flaps and skingrafts survived after operation, and primary healing of wound was obtained. After 6-23 months (mean, 14.5 months) follow-up, all flaps were characterized by soft texture, good color, and satisfactory appearance. The sensation of the flaps were recovered to S2~S3+ according to the Britain's Medical Research Council criteria at 6 months after operation. No obvious scar contracture was observed at donor site. ConclusionThe medial sural artery has the advantages of constant anatomical position, large diameter, rich blood flow, and a long artery pedicle, so the medial sural vessels is an ideal choice as recipient vessels for the reconstruction of leg skin and soft tissue defect.
Objective To investigate the effects of percutaneous cement discoplasty (PCD) and percutaneous cement interbody fusion (PCIF) on spinal stability by in vitro biomechanical tests. Methods Biomechanical test was divided into intact (INT) group, percutaneous lumbar discectomy (PLD) group, PCD group, and PCIF group. Six specimens of L4, 5 (including vertebral bodies and intervertebral discs) from fresh male cadavers were taken to prepare PLD, PCD, and PCIF specimens, respectively. Before treatment and after the above treatments, the MTS multi-degree-of-freedom simulation test system was used to conduct the biomechanical test. The intervertebral height of the specimen was measured before and after the axial loading of 300 N, and the difference was calculated. The range of motion (ROM) and stiffness of the spine in flexion, extension, left/right bending, and left/right rotation under a torque of 7.5 Nm were calculated. Results After axial loading, the change of intervertebral height in PLD group was more significant than that in other three groups (P<0.05). Compared with INT group, the ROM in all directions significantly increased and the stiffness significantly decreased in PLD group (P<0.05). Compared with INT group, the ROM of flexion, extension, and left/right rotation in PCD group significantly increased and the stiffness significantly decreased (P<0.05); compared with PLD group, the ROM of flexion, extension, and left/right bending in PCD group significantly decreased and the stiffness significantly increased (P<0.05). Compared with INT group, ROM of left/right bending in PCIF group significantly decreased and stiffness significantly increased (P<0.05); compared with PLD group, the ROM in all directions significantly decreased and the stiffness significantly increased (P<0.05); compared with PCD group, the ROM of flexion, left/right bending, and left/right rotation significantly decreased and stiffness significantly increased (P<0.05). Conclusion Both PCD and PCIF can provide good biomechanical stability. The former mainly affects the stiffness in flexion, extension, and bending, while the latter is more restrictive on lumbar ROM in all directions, especially in bending and rotation.