期刊名称:ePlasty: Open Access Journal of Plastic and Reconstructive Surgery
印刷版ISSN:1937-5719
出版年度:2017
卷号:17
语种:English
出版社:Open Science Co. LLC
摘要:DESCRIPTIONA 39-year-old woman presented with a twice-recurrent, full-thickness left chest and abdominal wall metaplastic sarcomatoid carcinoma (MSC). Two additional radical resections of the tumor left a defect measuring 30 × 40 cm. An anterolateral thigh (ALT) free flap with anastomosis to the right gastroepiploic vessels was chosen for reconstruction.QUESTIONSWhat are the local reconstructive options for chest and abdominal wall reconstruction?What are the free flap options?What considerations were made in the reconstruction of a patient with a large defect and vital organ exposure?Which vessels are used as a recipient in free tissue transfer in abdominal reconstruction?DISCUSSIONAdvances in reconstructive surgery over the past 2 decades have permitted the oncologist to proceed with radical cancer resection and ensure negative margins without the fear of causing an irreparable defect. Local options in defect reconstruction include primary closure, skin grafting, tissue expansion, negative pressure-assisted closure, the components separation technique, prosthetic mesh, and pedicled flaps.1,2Primary closure and skin grafting are methods suitable for smaller, partial-thickness defects. For full-thickness coverage, serial tissue expansions can provide reliable coverage with excellent aesthetic outcomes.2,3Negative pressure–assisted closure can be used for temporary coverage in delayed reconstruction as well as stimulation of healing by secondary intention.4It also allows delay of the ultimate reconstruction by ensuring negative margins in a sarcoma excision. Component separation with or without mesh provides tissue strength, but regional or local flaps would also need to be utilized for the superficial fascial layer reconstruction.5Prosthetic mesh or human acellular matrix utilization is important in attaining chest wall stability.6Free flaps are indicated when there is a massive loss of local tissues or when the defect size exceeds the reach or coverage of a pedicled flap.7Free flaps include the latissimus dorsi, the omentum, the tensor fascia lata, the rectus femoris muscle flap, and the ALT flap. Latissimus dorsi flap limitations include limited upper extremity motion, donor site morbidity, and the need for skin grafts. The use of omentum provides the benefits of visceral protection and a reliable blood supply, but it often requires skin grafting and repair of a potential hernia. A tensor fascia lata flap is the preferred flap in the reconstruction of defects involving the lower two-thirds of the abdominal wall due to the strength it provides to that area. A free ATL flap with gastroepiploic artery anastomosis is capable of reliably reconstructing complex, full-thickness chest and abdomen defects in a single stage without the use of vein grafts. In addition, a free ALT flap has low donor site morbidity and allows the surgeon to harvest it with minimal amounts of skin, fascia, and muscle necessary.2Our patient was a 39-year-old woman who presented with a twice-recurrent, full-thickness, left chest and upper abdominal wall MSC involving the costal margin and costochondral junctions of multiple lower ribs (Fig 1). The patient underwent radical resection of the 18 × 20-cm ulcerated tumor with en bloc removal of skin, subcutaneous tissues, costal margin, and left rectus margin. Upon positive margins, she further underwent reexcision of the deep superior and deep lateral margins, leaving a defect measuring 30 × 40 cm (Figs 2aandb). In planning reconstruction, the extensive musculofascial damage and defect dimensions precluded our use of the rectus abdominis and the latissimus dorsi, respectively, so we chose to proceed with a free flap consisting of the contralateral ALT and a part of the vastus lateralis muscle. Incorporation of the vastus lateralis allowed for a larger skin paddle and its added bulk is beneficial for dead space obliteration.7Since the internal mammary artery was sacrificed during dissection along the lower ribs, the right gastroepiploic vessels were identified as the most optimal recipient vessels as they had already been exposed during dissection (Fig 2c). The descending branch of the circumflex femoral artery was anastomosed to the right gastroepiploic artery through an opening on the posterior rectus sheath, over the liver, so as to avoid any undue tension or hernia formation (Figs 3and4).In abdominal reconstruction, recipient vessels typically utilized are the extraperitoneal vessels, including the deep epigastric vessels, the internal mammary vessels, and the saphenous vein loop graft; however, intraperitoneal vessels, such as the gastroepiploic vessels, may also be used.7,8The intraperitoneal vessels, due to their location immediately deep to the defect, allow for the use of free flaps with short pedicles or wide and flat flaps. In addition, they allow for a tight, continuous, circumferential fascial closure that is not topologically achievable with extraperitoneal vessels. The intraperitoneal gastroepiploic vessels, in particular, have high flow rates, diameters of 2 to 3 mm, and are easily identified and dissected.8Successful reconstruction is contingent on fully addressing the anatomical, functional, and cosmetic deformities of a defect. Our case demonstrated reconstruction of a complex wound in a single stage using the gastroepiploic artery for anastomosis.
