The "Superior Ledge": a Modification of the Standard Superomedial Pedicle Reduction Mammoplasty to Accentuate Nipple-Areola Complex Projection.

BACKGROUND: The superomedial pedicle parenchymal excision pattern for reduction mammaplasty has the benefits of a reproducible breast shape and improved superomedial fullness, but is limited by a susceptibility to nipple retraction. The senior author of this paper has formalized the "superior ledge" modification of the superomedial pedicle technique (SL-SMP) to address these limitations. OBJECTIVE: To describe the technical details of the SL-SMP breast reduction technique and to analyze patient outcomes. METHODS: The technique involves only partial-thickness parenchymal excision superolateral to the pedicle, thereby leaving a "superior ledge" of parenchyma on top of which the nipple-areola complex (NAC) rests in a tension-free manner. Postoperative photographs were recorded; and patient demographics, intraoperative details, complications, and outcomes were recorded and analyzed. RESULTS: One hundred seven patients underwent SL-SMP reduction mammaplasty between 2007 and 2013. Complications included wound-healing complications (9.3 %), infection (2.8 %), seroma (1.9 %), and hematoma (1.9 %). Mean follow-up was 44.6 months (Range: 17-72), and during that period no incidence of clinically relevant NAC retraction was noted by either the patient or surgical team. CONCLUSIONS: Maintenance of a distinct superior ledge underlying the final position of the NAC is an important modification to stress, to prevent nipple retraction. Importantly, the height of the ledge can be personalized for each patient. We feel it is a valuable addition to the plastic surgeon's armamentarium to optimize outcomes for patients seeking relief from excessive breast tissue. LEVEL OF EVIDENCE V: This journal requires that authors assign a level of evidence to each article. For a full description of these Evidence-Based Medicine ratings, please refer to the Table of Contents or the online Instructions to Authors www.springer.com/00266 .

Facilitated self-assembly of a prevascularized dermal/epidermal collagen scaffold.

Introduction: Resurfacing complex full thickness wounds requires free tissue transfer which creates donor site morbidity. We describe a method to fabricate a skin flap equivalent with a hierarchical microvascular network. Materials & methods: We fabricated a flap of skin-like tissue containing a hierarchical vascular network by sacrificing Pluronic® F127 macrofibers and interwoven microfibers within collagen encapsulating human pericytes and fibroblasts. Channels were seeded with smooth muscle and endothelial cells. Constructs were topically seeded with keratinocytes. Results: After 28 days in culture, multiphoton microscopy revealed a hierarchical interconnected network of macro- and micro-vessels; larger vessels (>100 µm) were lined with a monolayer endothelial neointima and a subendothelial smooth muscle neomedia. Neoangiogenic sprouts formed in the collagen protodermis and pericytes self-assembled around both fabricated vessels and neoangiogenic sprouts. Conclusion: We fabricated a prevascularized scaffold containing a hierarchical 3D network of interconnected macro- and microchannels within a collagen protodermis subjacent to an overlying protoepidermis with the potential for recipient microvascular anastomosis.

Fabrication of capillary-like structures with Pluronic F127® and Kerria lacca resin (shellac) in biocompatible tissue-engineered constructs.

The fabrication of large cellular tissue-engineered constructs is currently limited by an inability to manufacture internal vasculature that can be anastomosed to the host circulatory system. Creation of synthetic tissues with microvascular networks that adequately mimic the size and density of in vivo capillaries remains one of the foremost challenges within tissue engineering, as cells must reside within 200-300 µm of vasculature for long-term survival. In our previous work, we used a sacrificial microfibre technique whereby Pluronic® F127 fibres were embedded and then sacrificed within a collagen matrix, leaving behind a patent channel, which was subsequently seeded with endothelial and smooth muscle cells, forming a neointima and neomedia. We now have extended our technique and describe two approaches to synthesize a biocompatible tissue-engineered construct with macro-inlet and -outlet vessels, bridged by a dense network of cellularized microvessels, recapitulating the hierarchical organization of an arteriole, venule and capillary bed, respectively. Copyright © 2016 John Wiley & Sons, Ltd.