Abstract
Background/Objectives: Surgical site infection (SSI) after autologous rib cartilage microtia reconstruction is an uncommon but potentially devastating complication, as infection of the avascular cartilage framework can rapidly lead to partial or complete framework loss. Traditional management often favored aggressive debridement or framework removal, resulting in significant deformity. This study aimed to evaluate salvage-oriented management strategies and to propose a structured treatment algorithm for SSI following microtia reconstruction. Methods: A retrospective case series was conducted of patients who developed SSI after autologous rib cartilage microtia reconstruction between March 2021 and November 2025. SSI was defined by clinical and surveillance criteria requiring intervention beyond routine postoperative care. Nine patients were included. Management strategies were analyzed with respect to infection control, framework preservation, and wound healing outcomes. Results: SSI occurred at variable time points, ranging from early postoperative infection to delayed and late-onset presentations. Identified pathogens included Gram-positive cocci and multidrug-resistant Gram-negative organisms. Negative-pressure wound therapy (NPWT) was applied in all cases with wound dehiscence, persistent drainage, or cartilage exposure. Conservative staged debridement was performed only after clear demarcation of nonviable tissue. Overall auricular framework preservation was achieved in 100% of patients, with no cases requiring complete framework removal, although limited cartilage loss occurred in select cases. These outcomes demonstrate the clinical feasibility and effectiveness of salvage-oriented management across heterogeneous infection scenarios. Conclusions: SSI following autologous microtia reconstruction can be effectively salvaged without routine framework removal through a structured, timing-based algorithm emphasizing early culture-guided antimicrobial therapy, NPWT, and conservative staged intervention. This salvage-oriented approach provides a clinically relevant and reproducible framework for preserving auricular structure while minimizing morbidity, even in infections involving multidrug-resistant organisms.