The cause of venous compromise is multifactorial, with the current study showing that preoperative computed tomographic angiography may predict venous problems during flap harvest, by demonstrating perforator diameter, midline crossover, and deep-superficial venous communications.
Background: The previously described ''perfusion zones'' of the abdominal wall vasculature are based on filling of the deep inferior epigastric artery (DIEA) and all its branches simultaneously. With the advent of the DIEA perforator flap, only a single or several perforators are included in supply to the flap. As such, a new model for abdominal wall perfusion has become necessary. The concept of a ''perforator angiosome'' is thus explored. Methods: A clinical and cadaveric study of 155 abdominal walls was undertaken. This comprised the use of 10 whole, unembalmed cadaveric abdominal walls for angiographic studies, and 145 abdominal wall computed tomographic angiograms (CTAs) in patients undergoing preoperative imaging of the abdominal wall vasculature. The evaluation of the subcutaneous branching pattern and zone of perfusion of individual DIEA perforators was explored, particularly exploring differences between medial and lateral row perforators. Results: Fundamental differences exist between medial row and lateral row perforators, with medial row perforators larger (1.3 mm vs. 1 mm) and more likely to ramify in the subcutaneous fat toward the contralateral hemiabdomen (98% of cases vs. 2% of cases). A model for the perfusion of the abdominal wall based on a single perforator is presented. Conclusion: The ''perforator angiosome'' is dependent on perforator location, and can mapped individually with the use of preoperative imaging.
The nerves innervating the vastus lateralis are intimately related to the vascular pedicle of the anterolateral thigh flap. These nerves may be damaged during flap harvest and may contribute to donor-site morbidity after anterolateral thigh flap surgery.
An actual and accurate lymphatic map of the head and neck lymphatic drainage patterns is presented to upgrade our anatomical knowledge. This map will be of benefit for the clinical management of trauma and malignancies in this region.
Previously little has been written about the morphology of the human lymphatic vessels since Sappey (Sappey [1874] Anatomie, Physiologie, Pathologie des Vaisseaux Lymphatiques, Paris: Adrien Delahaye) over 100 years ago. There needs to be an accurate re-evaluation of scientific observations to aid clinical management. Forty-nine combinations of tissue from the head and neck of 20 unembalmed human cadavers were studied. Six percent hydrogen peroxide was used to find the vessels. They were injected with radio-opaque mixture, dissected, photographed, and radiographed. Final results were transferred to the computer for analysis. Different sized lymphatic valves were found in the precollecting and collecting lymph vessels, the lymphatic trunks, and ducts. The intervals between the valves were of various lengths. Diverse lymphatic ampullae and diverticula were seen in precollecting and collecting lymph vessels. Initial lymph vessels arose from the dermis, the galea, and the mucosal membrane. The vasculature of the direct and indirect precollecting and collecting lymph vessels, lymphatic trunks, and ducts was recorded. The morphology of the human lymphatic vessels in the head and neck has been described and recorded using radiographs and photographs.
Zones of hypovascularity are thought to exist in several tendons of the shoulder, contributing to localized tendon weakness and subsequent rupture in clinical practice. Although these zones have been demonstrated in many frequently ruptured tendons, the existence of a similar area in the often ruptured long head of biceps (LHB) tendon is largely unknown. Twenty cadaveric upper limb specimens were dissected after injection with either a radio-opaque lead oxide/milk mixture or India ink, followed by histological sectioning of the tendons. The LHB tendon was consistently supplied via its osteotendinous and musculotendinous junctions by branches of the thoracoacromial and brachial arteries respectively. In two specimens, additional branches from the anterior circumflex humeral artery travelling in a mesotenon vascularized the midsection of tendon. These source arteries divided the LHB tendon into either two or three vascular territories, depending upon the presence of the mesotenon-derived vascular supply. A zone of hypovascularity was consistently found in the region of the LHB tendon most frequently prone to rupture. This zone covered an area 1.2-3 cm from the tendon origin, extending from midway through the glenohumeral joint to the proximal inter-tubercular groove. This hypovascular region occurred on the border of two adjacent vascular territories, where reduced caliber choke vessels provide limited arterial supply. While it is probable that the limited arterial supply contributes to the susceptibility of this area to rupture, similar to other tendons the true pathogenesis is likely to be a combination of both vascular and mechanical factors.
The breast contains an extensive venous network. To avoid necrosis of the nipple-areola complex, this venous network should be preserved. The superomedial/medial and inferior pedicles contain the most extensive and more reliable venous drainage patterns.
Perioperative blood loss during and following breast reconstruction surgery can have substantial impact on free flap survival and patient morbidity. Transfusion rates of up to 95% have been reported following transverse rectus abdominis myocutaneous flap breast reconstruction, with blood loss described as significant in most cases. However, there has been little reported of such requirements in patients undergoing deep inferior epigastric perforator (DIEP) flap breast reconstruction. We present the transfusion requirements of 152 consecutive patients who underwent DIEP flap breast reconstruction, with a view to quantifying transfusion requirements and identifying risk factors for such loss. In this cohort, 80.3% of patients required blood transfusion, with a mean volume of 3.9 U per patient. There was a statistically significant correlation for increased transfusion requirement in patients with preoperative anemia ( P < 0.001) and in bilateral cases ( P < 0.001), but not for cases of immediate reconstruction ( P = 0.72). Although blood loss in breast reconstructive surgery is rarely large enough to be life-threatening, relative anemia does have significant effect on flap survival and patient morbidity. With risk factors for increased transfusion requirements identified in the current study, high-risk patients can be predicted preoperatively.
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