Objectives. Induced membrane technique is a relatively new technique in the reconstruction of large bone defects. It involves the implantation of polymethylmethacrylate (PMMA) cement in the bone defects to induce the formation of membranes after radical debridement and reconstruction of bone defects using an autologous cancellous bone graft in a span of four to eight weeks. The purpose of this study was to explore the clinical outcomes of the induced membrane technique for the treatment of post-traumatic osteomyelitis in 32 patients. Methods. A total of 32 cases of post-traumatic osteomyelitis were admitted to our department between August 2011 and October 2012. This retrospective study included 22 men and ten women, with a mean age of 40 years (19 to 70). Within this group there were 20 tibias and 12 femurs with a mean defect of 5 cm (1.5 to 12.5). Antibiotic-loaded PMMA cement was inserted into the defects after radical debridement. After approximately eight weeks, the defects were implanted with bone graft. Results. The patients were followed for 27.5 months (24 to 32). Radiographic bone union occurred at six months for 26 cases (81%) and clinical healing occurred in 29 cases (90%) at ten months. A total of six cases had a second debridement before bone grafting because of recurrence of infection and one patient required a third debridement. No cases of osteomyelitis had recurred at the time of the last follow-up visit. Conclusion. The induced membrane technique for the treatment of post-traumatic osteomyelitis is a simple, reliable method, with good early results. However, there are many challenges in determining the scope of the debridement, type of limb fixation and source of bone graft to be used. Cite this article: Dr Z. Xie. Induced membrane technique for the treatment of bone defects due to post-traumatic osteomyelitis. Bone Joint Res 2016;5:101–105. DOI: 10.1302/2046-3758.53.2000487

The optimal treatment strategy for post-traumatic long bone non-unions is subject of an ongoing discussion. At the Maastricht University Medical Center (MUMC+) the induced membrane technique is used to treat post-traumatic long bone non-unions. This technique uses a multimodal treatment algorithm involving bone marrow aspirate concentrate (BMAC), the reamer-irrigator-aspirator (RIA) and P-15 bioactive peptide (iFactor, Cerapedics). Bioactive glass (S53P4 BAG, Bonalive) is added when infection is suspected. This study aims to objectify the effect of this treatment algorithm on the health-related quality of life (HRQoL) of patients with post-traumatic long bone non-unions. We hypothesized that HRQoL would improve after treatment.

From January 2020 to March 2023, consecutive patients who were referred to a multidisciplinary (trauma, orthopaedic and plastic surgery) non-union clinic at the MUMC+, The Netherlands, were evaluated using the Non-Union Scoring System (NUSS). The EQ-5D-5L questionnaire and the Lower Extremity Functional Scale (LEFS) were employed to obtain HRQoL outcomes both prior to and subsequent to surgery, with a follow-up at 6, 18 and 35 weeks.

Seventy-six patients were assessed at baseline (T0), with a mean NUSS of 40 (± 13 SD). Thirty-eight patients had their first follow-up, six weeks after surgery (T1). Thirty-one patients had a second follow-up at 18 weeks (T2), and twenty patients had the third follow-up at 35 weeks (T3). The EQ-5D index mean at baseline was 0.480, followed by an index of 0.618 at T1, 0.636 at T2, and 0.702 at T3. A significant difference was found in the HRQoL score between T0 and T1, as well as T2 and T3 (p<0.001; p=0.011). The mean LEFS significantly increased from 26 before intervention to 34, 39, and 43 after treatment (p<0.001; p=0.033; p=0.016).

This study demonstrated a significant improvement in the health-related quality of life of patients with post-traumatic long bone non-unions after the standardized treatment algorithm following the induced membrane technique.

In chronically infected fracture non-unions, treatment requires extensive debridement to remove necrotic and infected bone, often resulting in large defects requiring elaborate and prolonged bone reconstruction. One approach includes the induced membrane technique (IMT), although the differences in outcome between infected and non-infectious aetiologies remain unclear. Here we present a new rabbit humerus model for IMT secondary to infection, and, furthermore, we compare bone healing in rabbits with a chronically infected non-union compared to non-infected equivalents.

A 5 mm defect was created in the humerus and filled with a polymethylmethacrylate (PMMA) spacer or left empty (n=6 per group). After 3 weeks, the PMMA spacer was replaced with a beta-tricalcium phosphate (chronOs, Synthes) scaffold, which was placed within the induced membrane and observed for a further 10 weeks. The same protocol was followed for the infected group, except that four week prior to treatment, the wound was inoculated with Staphylococcus aureus (4×10⁶ CFU/animal) and the PMMA spacer was loaded with gentamicin, and systemic therapy was applied for 4 weeks prior to chronOs application.

All the animals from the infected group were culture positive during the first revision surgery (mean 3×10⁵ CFU/animal, n= 12), while at the second revision, after antibiotic therapy, all the animals were culture negative. The differences in bone healing between the non-infected and infected groups were evaluated by radiography and histology. The initially infected animals showed impaired bone healing at euthanasia, and some remnants of bacteria in histology. The non-infected animals reached bone bridging in both empty and chronOs conditions.

We developed a preclinical in vivo model to investigate how bacterial infection influence bone healing in large defects with the future aim to explore new treatment concepts of infected non-union.

Aims

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

Background:

Segmental defects of long bones are notoriously demanding and difficult to treat. We evaluate nine cases where the Masquelet induced membrane technique to substitute bone loss has been used. We discuss the method compared to other types of bone reconstruction and share our tips and tricks to reduce treatment time and improve patient comfort.

Introduction:

20 cases of bone defect have been treated by the induced membrane technique avoiding allograft, microsurgery and amputation

Purpose of the study: The different conflicts in ex-You-goslavia left a health care desert. A few medicosurgical units attempted to reconstruct, but their capacities were limited and focused on emergencies. Many patients had to be abandoned. One was a 13-year-old Kosovar boy with active torpid osteomyelitis of the humerus whose family brought him to the French military field hospital in Mitrovica.

Case report: The patient’s general status was mediocre with a hanging left arm which was painful upon mobilization. The skin had a normal aspect. Plain x-rays showed a purulent disintegration of the proximal third of the humerus with 11 cm shortening and loss of bone continuity. The forearm and hand were free of vascular or nervous deficits. Joint testing of the elbow and should was not contributive. The infectious agent was identified (multiple susceptible staphylococcus) and treated. A sequential strategy was undertaken for bone healing. The focus was exposed and stabilized by external fixation with insertion of a spacer and cement. At day 45, an autologous graft was inserted into the induced membrane. The fixator was removed at bone healing (20 days).

Results: The gain was 8 cm. Postoperatively, the patient responded well to double antibiotic therapy. Recovery of joint motion was spectacular for the shoulder but difficult for the elbow. The autologous graft inserted on day 45 was composed of a non-vascularized fibular component completed with grafts harvested from the two anterior iliac crests. At one year follow-up, the infectious focus remains quiescent. The patient can use his arm with no problem. The shoulder motion is subnormal and there is a certain degree of persistent stiffness of the elbow but with no functional complaint.

Discussion: This is a unusual clinical case where the induced membrane technique proposed by Masquelet for osteomyelitis of the humerus was used in an adolescent. The surgical strategy was chosen in part because of the context where microsurgery was not available.

Conclusion: Therapeutic success was achieved with simple reliable techniques. The motivation of the young patient and the efforts of four medicosurgical teams overcame the technical limitations encountered in this field situation. The potential usefulness of the induced membrane technique proposed by Masquelet was demonstrated.

Purpose of the study: Resection of a malignant primary tumour of the proximal humerus implies sacrifice of a large part of the humeral shaft and the periarticular muscles. Reconstruction can be difficult and raises the problem of preserving function. Recent work has demonstrated the pertinence of combining a glenohumeral prosthesis with an allograft. Several complications are nevertheless reported: non-union, allograft resorption, loosening. We report three cases of malignant primary tumours requiring wide resection of the humerus which were treated by reconstruction with a shoulder arthrodesis applying the induced membrane technique.

Material and methods: Three patients (mean age 15 years) presented a malignant primary tumour of the proximal humerus (Ewing sarcoma or osteosarcoma) which was locally extensive but not metastatic. Resection implied resection of 16 cm of the humerus (mean). The same procedure was used for the three patients: first phase: wide resection of the tumour and neighbouring soft tissues which removed the majority of the proximal end of the humerus and the glenohumeral joint, then insertion of a cement spacer; second phase: reconstruction with a shoulder arthrodesis using cancellous grafts positioned inside the induced membrane. Stabilisation was ensured by insertion of a non-vascularised fibula inside the membrane and with a plate fixation on the scapular spine.

Results: Mean follow-up is five years. There has been no local recurrence and no distant spread. The arthrodeses and the reconstructions healed without reoperation within six to eight months. The functional outcomes were not different from those obtained with shoulder arthrodesis with a mean elevation of 90°.

Discussion: There are many advantages of reconstruction with shoulder arthrodesis using the induced membrane technique: possible wide initial resection, more satisfactory carcinological resection, the periarticular muscles are not pertinent after arthrodesis; there is no need for prosthetic elements or an allograft exposing to later complications; the reconstruction time is a simple procedure; elevation remains satisfactory.

Conclusion: This technique should be included in the surgical armamentarium just like vascularised transfers, allografts and massive prostheses. The indication should be reserved for extensive resection.

Introduction

20 cases of bone defect have been treated by the induced membrane technique avoiding allograft, microsurgery and amputation

Recent researches indicate that both M1 and M2 macrophages play vital roles in tissue repair and foreign body reaction processes. In this study, we investigated the dynamics of M1 macrophages in the induced membrane using a mouse femur critical-sized bone defect model.

The Masquelet method (M) and control (C) groups were established using C57BL/6J male mice (n=24). A 3mm-bone defect was created in the right femoral diaphysis followed by a Kirschner wire fixation, and a cement spacer was inserted into the defect in group M. In group C, the bone defect was left uninserted. Tissues around the defect were harvested at 1, 2, 4, and 6 weeks after surgery (n=3 in each group at each time point). Following Hematoxylin and eosin (HE) staining, immunohistochemical staining (IHC) was used to evaluate the CD68 expression as a marker of M1 macrophage. Iron staining was performed additionally to distinguish them from hemosiderin-phagocytosed macrophages.

In group M, HE staining revealed a hematoma-like structure, and CD68-positive cells were observed between the spacer and fibroblast layer at 1 week. The number of CD68-positive cells decreased at 2 weeks, while they were observed around the new bone at 4 and 6 weeks. In group C, fibroblast infiltration and fewer CD68-positive cells were observed in the bone defect without hematoma-like structure until 2 weeks, and no CD68-positive cells were observed at 4 and 6 weeks. Iron staining showed hemosiderin deposition in the surrounding area of the new bone in both groups at 4 and 6 weeks. The location of hemosiderin deposition was different from that of macrophage aggregation.

This study suggests that M1 macrophage aggregation is involved in the formation of induced membranes and osteogenesis and may be facilitated by the presence of spacers.

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.

Aims

Treatment of chronic osteomyelitis (COM) for young patients remains a challenge. Large bone deficiencies secondary to COM can be treated using induced membrane technique (IMT). However, it is unclear which type of bone graft is optimal. The goal of the study was to determine the clinical effectiveness of bone marrow concentrator modified allograft (BMCA) versus bone marrow aspirate mixed allograft (BMAA) for children with COM of long bones.

Aims

This study aimed to evaluate the effectiveness of the induced membrane technique for treating infected bone defects, and to explore the factors that might affect patient outcomes.

Introduction. The treatment of large segmental defects of long bones, which is caused by high energy trauma, revision surgery and resection of tumor or osteomyelitis and so on, is usually difficult. Recently the usefulness of Induced membrane technique (Masquelet technique) is reported. Induced membrane technique is an alternative method to reconstruct long-bone defects, which is two-stage surgery and combines the use of induced pseudo-membranes and cancellous autografts. The mechanism of bone formation in this technique is unknown. We performed Induced membrane technique on four patients, collected their membranes, and tested osteogenic ability and multipotency of cells derived from the membrane. Material and Method. From 2011, we had 4 patients of large segmental defects of long bones, which underwent operations of induced membrane technique. All operation performed by one surgeon. There were 2 nonunion (2 femur) and 1 open fracture (tibia), and close comminuted fracture (femur). Average length of bone defects was 5 cm. On the second stage, we collect some membranes and cultured cells derived from them. Then, cultured cells were tested for the ability to differentiate in vitro to multiple lineage. Results. Average period of bony union was 16 weeks. Cells (Passage 0) formed calcium deposition. Cells (Passage 3) differentiated into Adipogenic, chondrogenic, and osteogenic lineage in 3 weeks. Conclusion. Induced membrane derived cells have ability of bone synthesis and multipotency

Aims

In contrast to operations performed for other fractures, there is a high incidence rate of surgical site infection (SSI) post-open reduction and internal fixation (ORIF) done for tibial plateau fractures (TPFs). This study investigates the effect of induced membrane technique combined with internal fixation for managing SSI in TPF patients who underwent ORIF.

Aims

The purpose of this study was to: review the efficacy of the induced membrane technique (IMT), also known as the Masquelet technique; and investigate the relationship between patient factors and technique variations on the outcomes of the IMT.