Treatment Of Meta-diaphyseal Bone Defect In Long Bone With Titanium Mesh Cage

Meta-diaphyseal bone defects in long bones present a significant challenge in orthopedic surgery. Traditional treatment methods include autologous bone grafts, allografts, and distraction osteogenesis. Autologous bone grafting, considered the gold standard, is limited by donor site morbidity and the finite availability of graft material. Allografts provide an alternative but carry risks such as immune rejection and disease transmission. Distraction osteogenesis, popularized by Ilizarov, allows for gradual bone lengthening but requires prolonged treatment periods and may lead to complications like pin tract infections. More recently, bioengineered materials and growth factors have been explored as potential solutions, but their clinical application remains challenging.

Open fractures are classified based on orthogonal radiographs to assess the extent and geometry of bone loss. These classifications include incomplete defects (D1), minor or subcritical complete defects (D2), and segmental or critical-sized defects (D3). Incomplete defects (D1) are further divided into D1A (<25% cortical loss), D1B (25-75% cortical loss), and D1C (>75% cortical loss). Minor/subcritical defects (D2) are categorized as D2A (two oblique ends allowing overlap), D2B (one oblique end and one transverse end), and D2C (two transverse ends). Segmental/critical-sized defects (D3) are classified into D3A (moderate defects, 2 to <4 cm), D3B (major defects, 4 to <8 cm), and D3C (massive defects, ≥8 cm). The reliability of these classifications has been assessed using Fleiss' kappa tests among independent observers.

The use of titanium mesh cages, particularly the Harms cage, emerged in the late 1990s as a novel approach for treating meta-diaphyseal bone defects. Initially developed for spinal surgery, the Harms cage was adapted for long bone reconstruction due to its structural stability and biocompatibility. These cages provide immediate mechanical support while promoting bone ingrowth, addressing many limitations of traditional methods. The porous structure facilitates vascularization and integration with surrounding bone, potentially leading to improved healing outcomes.

Titanium mesh cages offer several advantages in managing meta-diaphyseal defects. They maintain bone length, provide immediate stability, and allow for earlier weight-bearing. However, challenges such as the risk of subsidence and the need for precise surgical technique remain. Recent studies have reported high union rates and favorable functional outcomes in long-term follow-ups, suggesting that titanium mesh cages are a reliable option for treating complex long bone defects.

This case series study aims to evaluate the efficacy of titanium mesh cages in addressing meta-diaphyseal bone defects. It focuses on clinical outcomes, radiographic healing, and patient-reported functional improvements. By validating this technique, titanium mesh cages could potentially set a new standard in managing challenging bone defects in orthopedic surgery.