PURPOSE: Composite tissue defects in the head and neck region present unique challenges. Definitive head and neck reconstruction of these cases is often complicated by complex 3-dimensional defects that may require multiple flap or chimeric flap procedures. These advanced techniques can have serious repercussions should poor perfusion of the flap cause flap failure, which can be devastating. MATERIALS AND METHODS: A retrospective review was completed for those complex reconstructions using free tissue transfers and fluorescent indocyanine green angiography (Lifecell SPY Elite imaging, Lifecell Corporation, Bridgewater, NJ) at Walter Reed National Military Medical Center over a 24-month period. Data analyzed included flap type (myocutaneous, osteocutaneous, or fasciocutaneous), flap success and failure rates, and complications. These also were compared with data from the institution before the study period and the incorporation of SPY technology. RESULTS: Sixty-one free flaps, including 11 head and neck flaps, were performed. The head and neck flaps included 1 latissimus, 3 gracilis, 1 vastus lateralis, 4 anterior lateral thigh, and 2 fibular flaps. The overall success rate was 98.4%; 1 flap was lost (1.6%) and 2 flaps developed partial flap necrosis (3.3%). Where SPY Elite was used, there was no unpredicted partial flap necrosis. The only total flap loss was related to a hypercoagulable condition. CONCLUSIONS: Free tissue transfer can be technically challenging, especially in complex head and neck reconstruction. An algorithmic approach using SPY Elite imaging aids in pedicle location, angiosomal assessment, anastomotic flow visualization, and cutaneous and osteocutaneous flap perfusion assessment. This objective tool can assist the reconstructive surgeon in avoiding perfusion-related complications and total and partial flap losses, thus improving patient outcomes. Published by Elsevier Inc.
PURPOSE: Composite tissue defects in the head and neck region present unique challenges. Definitive head and neck reconstruction of these cases is often complicated by complex 3-dimensional defects that may require multiple flap or chimeric flap procedures. These advanced techniques can have serious repercussions should poor perfusion of the flap cause flap failure, which can be devastating. MATERIALS AND METHODS: A retrospective review was completed for those complex reconstructions using free tissue transfers and fluorescent indocyanine green angiography (Lifecell SPY Elite imaging, Lifecell Corporation, Bridgewater, NJ) at Walter Reed National Military Medical Center over a 24-month period. Data analyzed included flap type (myocutaneous, osteocutaneous, or fasciocutaneous), flap success and failure rates, and complications. These also were compared with data from the institution before the study period and the incorporation of SPY technology. RESULTS: Sixty-one free flaps, including 11 head and neck flaps, were performed. The head and neck flaps included 1 latissimus, 3 gracilis, 1 vastus lateralis, 4 anterior lateral thigh, and 2 fibular flaps. The overall success rate was 98.4%; 1 flap was lost (1.6%) and 2 flaps developed partial flap necrosis (3.3%). Where SPY Elite was used, there was no unpredicted partial flap necrosis. The only total flap loss was related to a hypercoagulable condition. CONCLUSIONS: Free tissue transfer can be technically challenging, especially in complex head and neck reconstruction. An algorithmic approach using SPY Elite imaging aids in pedicle location, angiosomal assessment, anastomotic flow visualization, and cutaneous and osteocutaneous flap perfusion assessment. This objective tool can assist the reconstructive surgeon in avoiding perfusion-related complications and total and partial flap losses, thus improving patient outcomes. Published by Elsevier Inc.
Authors: Brett T Phillips; Mitchell S Fourman; Andrew Rivara; Alexander B Dagum; Tara L Huston; Jason C Ganz; Duc T Bui; Sami U Khan Journal: Eplasty Date: 2014-12-05