Chest Wall Reconstruction Cohort

Overview

Chest wall reconstruction following tumor or infection-related resections remains a challenging aspect of thoracic surgery, requiring restoration of structural stability and preservation of respiratory mechanics. While polymethyl methacrylate (PMMA) bone cement has long been used for rigid reconstruction, its limitations-including high cost, rigidity, infection risk, and interference with normal respiratory motion-pose challenges in resource-constrained settings. Twisted stainless steel wires offer a low-cost, flexible alternative that allows dynamic chest wall movement and easier adaptability in low- and middle-income countries such as Pakistan. To compare postoperative outcomes, complications, and cost-effectiveness of chest wall reconstruction using twisted stainless steel wires versus PMMA bone cement over a two-year period (January 2025 - December 2026). This prospective cohort study was conducted in the Department of Thoracic Surgery, Services Hospital, Lahore, a high-volume tertiary care and referral center. Patients undergoing chest wall reconstruction following resection for tumors, infections, or trauma were enrolled and divided into two groups based on the reconstruction technique used: Group A (twisted steel wires) and Group B (PMMA bone cement). Parameters assessed included postoperative pain (VAS scores), respiratory function, chest wall stability, complications (infection, wound dehiscence, prosthesis exposure), duration of hospital stay, readmission rate, and cost of reconstruction. Data were analyzed to compare clinical and functional outcomes between both cohorts.

Chest wall resection for tumors results in complex structural defects that require meticulous reconstruction to restore stability, protection, and respiratory function. The chest wall, composed of a combination of bony and soft tissue components, plays a crucial role in ventilation; thus, its reconstruction must achieve mechanical integrity while preserving physiologic mobility and minimizing postoperative morbidity. Multiple techniques and materials have been developed for chest wall reconstruction, including synthetic meshes, titanium plates, and polymethyl methacrylate (PMMA) bone cement. PMMA remains widely used due to its moldability and compressive strength; however, its rigidity, low tensile strength, poor adhesion, and potential for thermal necrosis and infection limit its functional and clinical effectiveness. Furthermore, its high cost and non-dynamic properties make it less suitable in resource-constrained settings. In contrast, twisted stainless steel wires (No. 05) offer a simple, durable, and cost-effective alternative. These wires provide robust mechanical support with dynamic flexibility, preserving normal respiratory motion and chest wall recoil. Recent advancements have demonstrated that wire-reinforced neorib configurations can achieve both tensile and compressive strength comparable to rigid prosthetics, while avoiding the static limitations of PMMA. Their affordability and availability make them particularly advantageous in low- and middle-income countries where economic feasibility dictates surgical decisions. Recent studies have further explored biologic and synthetic prosthetic materials, microvascular flaps, and hybrid "biosandwich" techniques to optimize chest wall reconstruction outcomes. Nevertheless, data comparing simple, low-cost methods such as twisted steel wire constructs and PMMA-based reconstructions remain limited, particularly in regions with restricted access to advanced materials. In Pakistan, evidence is largely confined to isolated case reports, including a novel reconstruction of a neosternum using steel wires for recurrent sternal chondrosarcoma. The present cohort study, conducted in the Department of Thoracic Surgery at Services Hospital, Lahore, aims to compare the outcomes of chest wall reconstruction using twisted stainless steel wires versus PMMA bone cement over two years from January 2025 to December 2026. By evaluating postoperative pain, respiratory function, chest wall recoil, and complication rates, this study seeks to provide evidence-based recommendations for the optimal reconstructive strategy in resource-limited healthcare environments.