Aims. The aim of the present study was to assess the outcomes of the induced membrane technique (IMT) for the management of infected segmental bone defects, and to analyze predictive factors associated with unfavourable outcomes. Methods. Between May 2012 and December 2020, 203 patients with infected segmental bone defects treated with the IMT were enrolled. The digital medical records of these patients were retrospectively analyzed. Factors associated with unfavourable outcomes were identified through logistic regression analysis. Results. Among the 203 enrolled patients, infection recurred in 27 patients (13.3%) after bone grafting. The union rate was 75.9% (154 patients) after second-stage surgery without additional procedures, and final union was achieved in 173 patients (85.2%) after second-stage surgery with or without additional procedures. The mean healing time was 9.3 months (3 to 37). Multivariate logistic regression analysis of 203 patients showed that the number (≥ two) of debridements (first stage) was an independent risk factor for infection recurrence and nonunion. Larger defect sizes were associated with higher odds of nonunion. After excluding 27 patients with infection recurrence, multivariate analysis of the remaining 176 patients suggested that intramedullary nail plus plate internal fixation, smoking, and an allograft-to-autograft ratio exceeding 1:3 adversely affected healing time. Conclusion. The IMT is an effective method to achieve infection eradication and union in the management of infected segmental bone defects. Our study identified several risk factors associated with unfavourable outcomes. Some of these factors are modifiable, and the risk of adverse outcomes can be reduced by adopting targeted interventions or strategies. Surgeons can fully inform patients with non-modifiable risk factors preoperatively, and may even use other methods for bone defect reconstruction. Cite this article: Bone Joint J 2024;106-B(6):613–622

Aims

To clarify the effectiveness of the induced membrane technique (IMT) using beta-tricalcium phosphate (β-TCP) for reconstruction of segmental bone defects by evaluating clinical and radiological outcomes, and the effect of defect size and operated site on surgical outcomes.

Aim. Previous studies of primary internal fixation of infected non-unions have reported high failure rates. Local antibiotic carriers and coatings have been advocated to reduce infection around implants and allow bone healing. We evaluated the effect of a calcium sulphate/hydroxyapatite antibiotic-loaded composite on bone healing and the eradication of infection in combination with internal fixation. Method. Twelve cases of established infected non-union, with segmental bone loss of up to 1cm were treated using a multidisciplinary protocol. This included; excision, deep sampling, stabilisation, local and systemic antibiotics, and soft-tissue closure. We treated 5 femurs, 4 humeri, 1 tibia and 2 periarticular non-unions at the ankle. Mean age was 59.8 years (34–75) and 9 patients had systemic co-morbidities (C-M Type B hosts). 9 patients had single stage surgery, with 5 IM Nails and 4 plates. Three patients had planned second stage internal fixation after external fixation to correct deformity. Staph. aureus was the commonest pathogen (5 cases) with polymicrobial infection in 3 cases. Results. All 12 patients were infection-free at a mean follow-up of 23 months (range 13–34 months). Union was achieved in 11/12 (92%) with the primary surgery alone. The single failure was the tibial case, who remains with an infection-free, stiff non-union. Conclusion. This protocol offered good results, mainly with a single stage treatment. Primary internal fixation was possible in 9 cases, without recurrent infection. The combination of excision of infected dead bone and a high level of local antibiotics above the Minimum Inhibitory Concentration and Minimum Biofilm Eradication Concentration levels for common bacteria, allowed a high success rate in these difficult cases

Bioactive glasses (BAGs) are bone substitutes with bone bonding, angiogenesis promoting and antibacterial properties. The bioactive process leading to bone bonding has been described as a sequence of reactions in the glass and at its surface. Implantation of the glass is followed by a rapid exchange of Na+ in the glass with H+ and H3O+ from the surrounding tissue, leading to the formation of silanol (SiOH) groups at the glass surface. Due to migration of Ca2+ and PO43− groups to the surface and cystallization, a CaO-P2O5 hydroxyapatite (HA) layer is formed on top of the Si-rich layer. Finally, cell interactions with the HA layer subsequently initiate the bone forming pathway. The rapid increase in pH and the subsequent osmotic effect caused by dissolution of the glass have been suggested to partly explain the antibacterial properties observed for BAGs. Comparing bactericidal effects of different BAGs, BAG-S53P4 has been shown to be the most effective, with the fastest killing or growth inhibitory effect. This antibacterial effect has been observed in vitro for all pathogens tested, including the most important aerobic and anaerobic pathogens, as well as very resistant bacteria. In a multicentre study in 2007–2009, BAG-S53P4 was used as bone graft substitute in treatment of osteomyelitis. Eleven patients (nine males, two females) with a radiologically diagnosed osteomyelitis in the lower extremity (N=10) and in the spine (N-1) participated. In the operation, the infected bone and the soft tissue were removed, and the cavitary bone defects were filled with BAG-S53P4 (BonAlive™, Bonalive Biomaterials Ltd., Finland). In four patients, muscle flaps were used as part of the treatment. Eight patients were treated in a one-stage procedure. Kanamycin granules were used in one patient and Garamycin granules (Septocol ®) in two patients. Patient data were obtained from hospital patient' records until August 2010, resulting in a mean follow-up period of 29 months (range 15–43). BAG-S53P4 was well tolerated; no BAG-related adverse effects were seen in any patient. The use of BAG-S53P4 as a bone graft substitute resulted in a fast recovery. Long-term clinical outcome was good or excellent in ten of eleven patients. These primary results indicate that BAG-S53P4 can be considered as a good and usable material in treatment of osteomyelitis. After this study BAG-S53P4 has been used in several other patients with very promising results

Aims

Many authors have reported a shorter treatment time when using trifocal bone transport (TFT) rather than bifocal bone transport (BFT) in the management of long segmental tibial bone defects. However, the difference in the incidence of additional procedures, the true complications, and the final results have not been investigated.

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This study describes the use of the Masquelet technique to treat segmental tibial bone loss in 12 patients.

Aims

The aim of this study was to identify risk factors for the failure of exchange nailing in nonunion of tibial diaphyseal fractures.

We undertook a retrospective study of 50 consecutive patients (41 male, 9 female) with an infected nonunion and bone defect of the femoral shaft who had been treated by radical debridement and distraction osteogenesis. Their mean age was 29.9 years (9 to 58) and they had a mean of 3.8 (2 to 19) previous operations. They were followed for a mean of 5.9 years (2.0 to 19.0). The mean duration of the distraction osteogenesis was 24.5 months (2 to 39). Pin-track infection was observed in all patients. The range of knee movement was reduced and there was a mean residual leg-length discrepancy of 1.9 cm (0 to 8) after treatment. One patient required hip disarticulation to manage intractable sepsis. In all, 13 patients had persistant pain. Bony union was achieved in 49 patients at a mean of 20.7 months (12 to 35).

Although distraction osteogenesis is commonly used for the treatment of infected femoral nonunion with bone defects, it is associated with a high rate of complications.

In this retrospective study we evaluated the method of acute shortening and distraction osteogenesis for the treatment of tibial nonunion with bone loss in 17 patients with a mean age of 36 years (10 to 58). The mean bone loss was 5.6 cm (3 to 10). In infected cases, we performed the treatment in two stages. The mean follow-up time was 43.5 months (24 to 96). The mean time in external fixation was 8.0 months (4 to 13) and the mean external fixator index was 1.4 months/cm (1.1 to 1.8). There was no recurrence of infection. The bone evaluation results were excellent in 16 patients and good in one, while functional results were excellent in 15 and good in two. The complication rate was 1.2 per patient.

We conclude that acute shortening and distraction osteogenesis is a safe, reliable and successful method for the treatment of tibial nonunion with bone loss, with a shorter period of treatment and lower rate of complication.