The anatomical (angiosome) and clinical territories of cutaneous perforating arteries: development of the concept and designing safe flaps.

BACKGROUND: Island "perforator flaps" have become state of the art for free-skin flap transfer. Recent articles by Saint-Cyr et al. and Rozen et al. have focused on the anatomical and the clinical territories of individual cutaneous perforating arteries in flap planning, and it is timely to compare this work with our angiosome concept. METHODS: The angiosome concept, published in 1987, was reviewed and correlated with key experimental and clinical work by the authors, published subsequently at different times in different journals. In addition, new data are introduced to define these anatomical and clinical territories of the cutaneous perforators and to aid in the planning of safe skin flaps for local and free-flap transfer. RESULTS: The anatomical territory of a cutaneous perforator was defined in the pig, dog, guinea pig, and rabbit by a line drawn through its perimeter of anastomotic vessels that link it with adjacent perforators in all directions. The safe clinical territory of that perforator, seen not only in the same range of animals but also in the human using either the Doppler probe or computed tomography angiography to locate the vessels, was found reliably to extend to include the anatomical territory of the next adjacent cutaneous perforator, situated radially in any direction. CONCLUSION: The data provided by Saint-Cyr et al. and Rozen et al., coupled with the authors' own original work on the vascular territories of the body and their subsequent studies, reinforce the angiosome concept and provide the basis for the design of safe flaps for patient benefit.

Neurovascular anatomy of sartorius muscle flaps: implications for local transposition and facial reanimation.

BACKGROUND: The sartorius muscle is a superficial muscle of the thigh that possesses highly suitable qualities for many uses in local transposition and free muscle transfer. However, a paucity of description of the neurovascular anatomy of the sartorius has contributed to its infrequent use in these roles. METHODS: Both human and canine studies were undertaken to delineate the neurovascular anatomy of the sartorius and to determine the role for surgical delay clinically. Fifty-five human cadaveric sartorius muscles and 30 canine cadaveric sartorius muscles underwent angiographic and dissection studies, and the location and course of the vessels and nerves supplying sartorius are described. A subsequent study was undertaken in two live canines in which the vascular supply to the sartorius was evaluated before and after surgical delay. RESULTS: The sartorius is supplied by an average of six or seven vascular pedicles, the size, location, and course of which are described. The nerve supply to the sartorius enters at its proximal end and uniformly arises from a branch of the femoral nerve. Variations in branching patterns and course of nerves and vessels are described. Living canine studies demonstrated the dilatation of intramuscular vessels following surgical delay, with the contrast injection of a single remaining vascular pedicle shown to vascularize the entire length of the sartorius muscle. CONCLUSIONS: The sartorius is highly suitable for local transposition and free muscle transfer for facial reanimation. The neurovascular anatomy is reliable, and the use of surgical delay can augment its vascular supply and increase the arc of rotation for local transposition.