An anterolateral thigh flap was utilized to supply: soft tissue for the forehead reconstruction, vascularized fascia lata for the dural repair, and to act vascular conduit to supply a distally placed latissmus dorsi flap for total scalp reconstruction. We believe this is the first time this combination of double-free, flow-through flap design has been published for the reconstruction of complex, composite scalp and calvarial defects. © 2011 Wiley-Liss, Inc. Microsurgery, 2011. “
“The use of unipedicled venous flaps has been limited due to their unconventional perfusion patterns and inconsistent survival. Further information regarding the optimal conditions

required for unipedicled venous flap coverage is needed to increase flap survival. The purpose of this study was to investigate the EX527 PD0325901 datasheet effect of the pedicle orientation and length on the viability of unipedicled venous flaps based on a review of our clinical experience. Thirty-one skin and soft tissue hand defects of 29 patients were treated with unipedicled venous flaps. Sixteen defects were treated with proximally pedicled flaps and 15 were treated with distally pedicled flaps. Five of the 16 proximally pedicled flaps and eight of the 15 distally pedicled flaps had pedicle lengths ≥ 5 cm. All proximally pedicled flaps survived, and distally pedicled flaps with pedicle lengths <5 cm (n = 7)

Interleukin-3 receptor also survived. Distally pedicled flaps with pedicle lengths ≥5 cm (n = 8) developed congestion within 1–2 days after surgery, and external bleeding was applied. Four of the eight flaps survived completely, and partial necrosis developed in the other four. The results demonstrate that proximally pedicled venous flaps of the hand can survive regardless of pedicle length. Distally pedicled venous flaps can also survive completely when pedicle length is <5 cm. Distally pedicled venous flaps with pedicle lengths ≥5 cm should be used with caution. © 2013 Wiley Periodicals, Inc. Microsurgery 34:197–202, 2014. "
“Despite confirmation of a reliable perforasome in

the dorsal scapular artery in an anatomic study, a true perforator flap has not been recommended in previous clinical studies because of concerns regarding insufficient perfusion in the distal region. In this report, we present two cases of reconstruction for occipital defects caused by tumor extirpation using pedicled dorsal scapular artery perforator flaps without a muscle component. To secure the perfusion of the dorsal scapular artery perforator flap, inclusion of an additional perforator was attempted for perfusion augmentation. The second dorsal scapular artery perforator was harvested in one case. In an additional case, the sixth dorsal intercostal artery perforator with a branch that directly connected with the dorsal scapular artery within the trapezius muscle was additionally harvested.