Topical α-gal nanoparticles accelerate diabetic wound healing.

An inadequate response from macrophages, key orchestrators of the wound healing process, has been implicated in the pathophysiology of impaired healing in diabetes. This study explored the utility of nanoparticles presenting the α-gal (Galα1-3Galß1-4GlcNAc-R) epitope to induce anti-Gal antibody-mediated local transient recruitment of macrophages to accelerate wound closure and healing in a diabetic murine model. α1,3galactosyltrasferase knockout mice were stimulated to produce anti-Gal antibodies and subsequently diabetes was induced by streptozotocin-induced ß-cell destruction. Six mm full-thickness skin wounds were made and α-gal nanoparticles (AGN) were topically applied on postwounding days 0 and 1. Wounds were analysed histologically for macrophage invasion and markers of wound healing, including epithelialization, vascularization and granulation tissue deposition through postoperative day 12. We found that application of AGN transiently but significantly increased macrophage recruitment into the wounds of diabetic mice. Treated wounds demonstrated more rapid closure and enhanced wound healing as demonstrated by significantly accelerated rates of epithelialization, vascularization and granulation tissue deposition. Thus, topical treatment of full-thickness wounds in diabetic mice with α-gal nanoparticles induced a transient but significant increase in macrophage recruitment resulting in an accelerated rate of wound healing. Using α-gal nanoparticles as a topical wound healing adjunct is a simple, safe and effective means of augmenting dysregulated macrophage recruitment present in the diabetic state.

Functional and Aesthetic Outcomes in Free Flap Reconstruction of Intraoral Defects With Lip-Split Versus Non-Lip-Split Incisions.

BACKGROUND: Traditional free flap reconstruction of complex intraoral defects often uses large lip-splitting incisions. To reduce morbidity and preserve aesthetics, we have adopted a more technically demanding visor technique obviating an incision through the lower lip through which the resection and reconstruction are performed. METHODS: A retrospective review was performed of patients who underwent free flap reconstruction of intraoral defects over 7 years by a single plastic surgeon (C.H.R.) at a single institution. Patients were included if they underwent a resection from the mandible, tongue, or floor of mouth followed by free tissue transfer as a reconstructive approach. Patients were excluded if they underwent reconstruction of an area that does not traditionally require a lip incision, such as a maxillectomy or laryngeal defect. An ablative approach was taken via a lip-split technique or visor technique. Wound complications, margins of resection, and functional outcomes were assessed. Two standardized questionnaires (Derriford Appearance Scale Short Form and Quality of Life Questionnaire for Head and Neck Cancer) were used to assess psychological distress and dysfunction from disfigurement, speech quality, and oral function. Preoperative and postoperative patient photos were evaluated. RESULTS: Of 27 patients (mean ± SD age, 58.33 ± 13.02 years), 52% (14) had visor reconstructions whereas 48% (13) had lip-splitting reconstructions. About 78.6% of visor patients had widely-free margins compared with 46.2% of the lip-split patients. No differences in surgical-site complications between the lip-split and visor group (38.5% vs 28.6%) or in operative times were observed. Ninety-three percent of visor patients versus 54% of lip-split patients tolerated oral feeds at 1 year. Lip-split patients rated their quality of eating and speech worse than the visor patients (Quality of Life Questionnaire for Head and Neck Cancer mean score, 2.2 vs 1.56). Patients and clinical staff deemed visor reconstructions resulted in less visible sequelae. CONCLUSIONS: A visor technique with no lip-split incision for intraoral free flap reconstruction is an oncologically safe technique to consider that may improve cosmetic and functional outcomes for head and neck reconstruction patients.

Antigen-Mediated, Macrophage-Stimulated, Accelerated Wound Healing Using α-Gal Nanoparticles.

BACKGROUND: Macrophages are known to be crucial to timely and efficacious wound healing. They have been shown to modulate inflammation and the migration and proliferation of regenerative cells, promoting tissue deposition and wound closure. This study explored the use of the natural antigen Galα1-3Galß1-4GlcNAc-R (α-gal), present in lower mammals yet absent in Old World primates and humans, to induce a transiently enhanced macrophage response and thereby direct accelerated wound closure and healing in a standard murine model. METHODS: α1,3galactosyltransferase knockout mice were stimulated to produce anti-Gal antibodies at levels comparable with humans. α-Gal-containing micelle nanoparticles were generated and applied to full-thickness splinted wounds on the mice. At 1, 2, 3, 6, and 9 days postoperatively, mice were killed, and wounds were analyzed histologically for macrophage invasion, epithelialization, vascularization, and granulation tissue deposition. Flow cytometry of wound tissue was performed to quantify relative levels of proinflammatory M1 to anti-inflammatory M2 macrophage subtypes. RESULTS: Treatment of splinted full-thickness murine wounds with α-gal-containing nanoparticles led to accelerated wound healing and closure as demonstrated by accelerated rates of keratinization, vascular growth, and wound tissue deposition. Furthermore, treated wounds demonstrated early and enhanced macrophage invasion, as well as a lower M1-M2 ratio. CONCLUSION: Application of α-gal-containing nanoparticles to wounds stimulated a transiently increased inflammatory response, accelerating the rate of wound healing. Use of α-gal may be a simple and effective way to stimulate the wound healing response in both normal and pathologic wound beds.

A 3-Dimensional Biomimetic Platform to Interrogate the Safety of Autologous Fat Transfer in the Setting of Breast Cancer.

INTRODUCTION: Obesity is a known risk factor for the development and prognosis of breast cancer. Adipocytes have been identified as a source of exogenous lipids in other cancer types and may similarly provide energy to fuel malignant survival and growth in breast cancer. This relationship is of particular relevance to plastic surgery, because many reconstructions after oncologic mastectomy achieve optimal aesthetics and durability using adjunctive autologous fat transfer (AFT). Despite the increasing ubiquity and promise of AFT, many unanswered questions remain, including safety in the setting of breast cancer. Clinical studies to examine this question are underway, but an in vitro system is critical to elucidate the complex interplay between the cells that normally reside at the surgical recipient site. To study these interactions and characterize possible lipid transfer between adipocytes to breast cancer cells, we designed a 3-dimensional in vitro model using primary patient-derived tissues. METHODS: Breast adipose tissue was acquired from patients undergoing breast reduction surgery. The tissue was enzymatically digested and sorted to retrieve adipocytes and adipose stromal cells. Polydimethylsiloxane wells were filled with type I collagen-encapsulated adipocytes labeled with the fluorescent lipid dye boron dipyrromethene, as well as unlabeled adipose stromal cells. A monolayer of red fluorescently labeled MDA-MB-231 and MDA-MB-468 breast cancer cells was seeded on the surface of the construct. Lipid transfer at the interface between adipocytes and breast cancer cells was analyzed. RESULTS: Confocal microscopy revealed a dense culture of native adipocytes containing fluorescent lipid droplets in the 3-dimensional collagen culture platform. RFP-positive breast cancer cells were found in close proximity to lipid-laden adipocytes. Lipid transfer from adipocytes to breast cancer cells was observed by the presence of boron dipyrromethene-positive lipid droplets within RFP-labeled breast cancer cells. CONCLUSION: We have established a 3-dimensional model to study complex breast cancer-adipose tissue interactions. Direct transfer of fluorescently labeled lipids from adipocytes to breast cancer cells may indicate aberrant metabolism to fuel malignant growth and adaptive survival. Our novel platform can untangle the complex interplay within the breast cancer tumor microenvironment for high-throughput analysis and better elucidate the safety of AFT in postoncologic mastectomy.

In Search of a Murine Model of Radiation-Induced Periprosthetic Capsular Fibrosis.

INTRODUCTION: Capsular contracture after breast reconstruction is a morbid complication, occurring in 30.0% to 47.5% of patients undergoing postoperative radiotherapy. Although it is well known that radiation increases rate of capsular contracture, there are few well-established animal models that faithfully replicate standard-of-care clinical practice, that is, prosthesis placement at the time of mastectomy followed by delayed radiotherapy. To better recapitulate current clinical practice, we developed a murine model in which the implant sites were irradiated 10 days postoperatively, rather than at time of surgery. METHODS: Hemispherical implants were created from polydimethylsiloxane and implanted bilaterally in the subcutaneous dorsa of 20 C57Bl/6 mice. Mice were randomized to 5 treatment groups, differing in irradiation dose: 0 to 40 Gy. Ten days postoperatively, irradiation was performed using 250-kVp x-rays (XRAD225Cx, Precision X-ray, North Branford, Conn). In 1 mouse per group, dosimeters were placed subcutaneously to measure the delivered absorbed dose. Thirty-one days postoperatively, the mice were sacrificed and examined grossly, and periprosthetic tissues were removed for histologic analysis of periprosthetic capsule thickness and cellular deposition. RESULTS: Total radiation dose was calculated by the treatment planning software and confirmed by the in vivo dosimeters. Physical examination of the irradiated region demonstrated evidence of local radiation delivery, including circular patterns of hair blanching and thinning directly over the implants. Furthermore, histologic analysis of the irradiated epidermis demonstrated dose-dependent radiation changes including keratin whorls and patches of uneven epidermal thickness. There was no statistically significant difference in capsule thickness among the groups. Mice in the 30 and 40 Gy groups endured complications including shortness of breath, coagulopathy, and death, signs of systemic radiation poisoning. CONCLUSIONS: There was no evidence of increased periprosthetic capsule thickness with localized irradiation, irrespective of dose up to 20 Gy. These results differ from those previously published, which demonstrated increased capsule thickness with 10 Gy irradiation. Given the evidence of local radiation delivery, we believe that the lack of increase in capsule thickness observed in our experiment is a real phenomenon and demonstrate the difficulty in creating an easily reproducible rodent model that mimics the effects of postmastectomy implant-based reconstruction and irradiation.

An Antifibrotic Breast Implant Surface Coating Significantly Reduces Periprosthetic Capsule Formation.

BACKGROUND: The body responds to prosthetic materials with an inflammatory foreign body response and deposition of a fibrous capsule, which may be deleterious to the function of the device and cause significant discomfort for the patient. Capsular contracture (CC) is the most common complication of aesthetic and reconstructive breast surgery. The source of significant patient morbidity, it can result in pain, suboptimal aesthetic outcomes, implant failure, and increased costs. The underlying mechanism remains unknown. Treatment is limited to reoperation and capsule excision, but recurrence rates remain high. In this study, the authors altered the surface chemistry of silicone implants with a proprietary anti-inflammatory coating to reduce capsule formation. METHODS: Silicone implants were coated with Met-Z2-Y12, a biocompatible, anti-inflammatory surface modification. Uncoated and Met-Z2-Y12-coated implants were implanted in C57BL/6 mice. After 21, 90, or 180 days, periprosthetic tissue was removed for histologic analysis. RESULTS: The authors compared mean capsule thickness at three time points. At 21, 90, and 180 days, there was a statistically significant reduction in capsule thickness of Met-Z2-Y12-coated implants compared with uncoated implants ( P < 0.05). CONCLUSIONS: Coating the surface of silicone implants with Met-Z2-Y12 significantly reduced acute and chronic capsule formation in a mouse model for implant-based breast augmentation and reconstruction. As capsule formation obligatorily precedes CC, these results suggest contracture itself may be significantly attenuated. Furthermore, as periprosthetic capsule formation is a complication without anatomical boundaries, this chemistry may have additional applications beyond breast implants, to a myriad of other implantable medical devices. CLINICAL RELEVANCE STATEMENT: Coating of the silicone implant surface with Met-Z2-Y12 alters the periprosthetic capsule architecture and significantly reduces capsule thickness for at least 6 months postoperatively in a murine model. This is a promising step forward in the development of a therapy to prevent capsular contracture.

Explantation in Tissue Expander and Direct-to-Implant Reconstruction with Acellular Dermal Matrix: How to Avoid Early Reconstructive Failures.

BACKGROUND: In the United States, approximately 57,000 tissue expander/implant-based breast reconstructions are performed each year. Complete submuscular tissue expander coverage affords the best protection against implant exposure but can restrict lower pole expansion. The benefits of using acellular dermal matrix are enticing, but questions remain as to whether or not its presence increases reconstructive failures. The purpose of this study was to investigate predictors of explantation in those patients with acellular dermal matrix reconstructions and to discuss salvage techniques. METHODS: An approved retrospective review was conducted of 137 patients undergoing 234 individual breast reconstructions over 4 years performed by a single plastic surgeon (J.D.) at a single institution. Patients who underwent implant-based reconstruction with either immediate placement of a tissue expander that was subsequently exchanged for a permanent implant at a second operation or immediate placement of a permanent implant when indicated were included. RESULTS: One hundred thirty-seven patients who underwent 234 implant-based breast reconstructions using acellular dermal matrix met criteria. There was an overall 23 percent complication rate, including any cellulitis, seroma, skin necrosis, and hematoma formation. Significant preoperative risk factors for any postoperative complication included body mass index greater than 25 kg/m2 and a history of radiation therapy before acellular dermal matrix placement. Radiation therapy was found to be a significant risk factor for postoperative skin necrosis. Of explantations, many fluid cultures grew Gram-negative bacteria. CONCLUSIONS: Skin necrosis is a serious risk factor for explantation in implant-based reconstruction with acellular dermal matrix. The reconstructive surgeon should consider early excision of any skin necrosis as soon as it is identified. CLINICAL QUESTION/LEVEL OF EVIDENCE: Risk, III.

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.

Microstructured hydrogel scaffolds containing differential density interfaces promote rapid cellular invasion and vascularization.

INTRODUCTION: Insufficient vascularization of currently available clinical biomaterials has limited their application to optimal wound beds. We designed a hydrogel scaffold with a unique internal microstructure of differential collagen densities to induce cellular invasion and neovascularization. METHODS: Microsphere scaffolds (MSS) were fabricated by encasing 1% (w/v) type 1 collagen microspheres 50-150 µm in diameter in 0.3% collagen bulk. 1% and 0.3% monophase collagen scaffolds and Integra® disks served as controls. Mechanical characterization as well as in vitro and in vivo invasion assays were performed. Cell number and depth of invasion were analyzed using Imaris™. Cell identity was assessed immunohistochemically. RESULTS: In vitro, MSS exhibited significantly greater average depth of cellular invasion than Integra® and monophase collagen controls. MSS also demonstrated significantly higher cell counts than controls. In vivo, MSS revealed significantly more cellular invasion spanning the entire scaffold depth at 14 days than Integra®. CD31+ expressing luminal structures suggestive of neovasculature were seen within MSS at 7 days and were more prevalent after 14 days. Multiphoton microscopy of MSS demonstrated erythrocytes within luminal structures after 14 days. CONCLUSION: By harnessing simple architectural cues to induce cellular migration, MSS holds great potential for clinical translation as the next generation dermal replacement product. STATEMENT OF SIGNIFICANCE: Large skin wounds require tissue engineered dermal substitutes in order to promote healing. Currently available dermal replacement products do not always adequately incorporate into the body, especially in complex wounds, due to poor neovascularization. In this paper, we present a hydrogel with an innovative microarchitecture that is composed of dense type I collagen microspheres suspended in a less-dense collagen bulk. We show that cell invasion into the scaffold is driven solely by mechanical cues inherent within this differential density interface, and that this induces robust vascular cell invasion both in vitro and in a rodent model. Our hydrogel performs favorably compared to the current clinical gold standard, Integra®. We believe this hydrogel scaffold may be the first of the next generation of dermal replacement products.

Male germ cells support long-term propagation of Zika virus.

Evidence of male-to-female sexual transmission of Zika virus (ZIKV) and viral RNA in semen and sperm months after infection supports a potential role for testicular cells in ZIKV propagation. Here, we demonstrate that germ cells (GCs) are most susceptible to ZIKV. We found that only GCs infected by ZIKV, but not those infected by dengue virus and yellow fever virus, produce high levels of infectious virus. This observation coincides with decreased expression of interferon-stimulated gene Ifi44l in ZIKV-infected GCs, and overexpression of Ifi44l results in reduced ZIKV production. Using primary human testicular tissue, we demonstrate that human GCs are also permissive for ZIKV infection and production. Finally, we identified berberine chloride as a potent inhibitor of ZIKV infection in both murine and human testes. Together, these studies identify a potential cellular source for propagation of ZIKV in testes and a candidate drug for preventing sexual transmission of ZIKV.

Transient phase behavior of an elastomeric biomaterial applied to abdominal laparotomy closure.

Secure closure of the fascial layers after entry into the peritoneal cavity is crucial to prevent incisional hernia, yet appropriate purchase of the tissue can be challenging due to the proximity of the underlying protuberant bowel which may become punctured by the surgical needle or strangulated by the suture itself. Devices currently employed to provide visceral protection during abdominal closure, such as the metal malleable retractor and Glassman Visceral Retainer, are unable to provide complete protection as they must be removed prior to complete closure. A puncture resistant, biocompatible, and degradable matrix that can be left in place without need for removal would facilitate rapid and safe abdominal closure. We describe a novel elastomer (CC-DHA) that undergoes a rapid but controlled solid-to-liquid phase transition through the application of a destabilized carbonate cross-linked network. The elastomer is comprised of a polycarbonate cross-linked network of dihydroxyacetone, glycerol ethoxylate, and tri(ethylene glycol). The ketone functionality of the dihydroxyacetone facilitates hydrolytic cleavage of the carbonate linkages resulting in a rapidly degrading barrier that can be left in situ to facilitate abdominal fascial closure. Using a murine laparotomy model we demonstrated rapid dissolution and metabolism of the elastomer without evidence of toxicity or intraabdominal scarring. Furthermore, needle puncture and mechanical properties demonstrated the material to be both compliant and sufficiently puncture resistant. These unique characteristics make the biomaterial extraordinarily useful as a physical barrier to prevent inadvertent bowel injury during fascial closure, with the potential for wider application across a variety of medical and surgical applications. STATEMENT OF SIGNIFICANCE: Fascial closure after abdominal surgery requires delicate maneuvers to prevent incisional hernia while minimizing risk for inadvertent bowel injury. We describe a novel biocompatible and biodegradable polycarbonate elastomer (CC-DHA) comprised of dihydroxyacetone, glycerol ethoxylate, and tri(ethylene glycol), for use as a rapidly degrading protective visceral barrier to aid in abdominal closure. Rapid polymer dissolution and metabolism was demonstrated using a murine laparotomy model without evidence of toxicity or intraabdominal scarring. Furthermore, mechanical studies showed the material to be sufficiently puncture resistant and compliant. Overall, this new biomaterial is extraordinary useful as a physical barrier to prevent inadvertent bowel injury during fascial closure, with the potential for wider application across a variety of medical and surgical applications.

Toward Microsurgical Correction of Cleft Lip Ex Utero through Restoration of Craniofacial Developmental Programs.

BACKGROUND: Cleft lip with or without cleft palate is present in approximately one in 500 to 700 live births, representing the most common congenital craniofacial anomaly. Previously, the authors developed a unique murine model with compound Pbx deficiency that exhibits fully penetrant cleft lip with or without cleft palate. To investigate the possibility of tissue repair at an early gestational stage, the authors designed a minimally invasive surgical approach suitable for intrauterine repair using Wnt9b-soaked collagen microspheres to restore craniofacial developmental programs for cleft correction. METHODS: Collagen microspheres with diameters ranging from 20 to 50 µm were fabricated to serve as a delivery vehicle for Wnt9b. At gestational day 11.5, wild-type and Pbx-deficient murine embryos were isolated. Microspheres soaked in murine purified Wnt9b protein were microsurgically implanted at the midface lambdoidal junction. Embryos were cultured in a 37°C modified whole-embryo culture system. RESULTS: Targeted release of Wnt9b resulted in augmented Wnt expression at the lambdoidal junction. Microsurgical implantation of Wnt9b-soaked microspheres resulted in cleft correction in 27.1 percent of the Pbx-deficient embryos. The difference in the ratio of the areas of clefting between implanted and nonimplanted embryos was significant (p < 0.05). CONCLUSIONS: Ex utero correction of cleft lip with or without cleft palate in the authors' murine model by means of microsurgical intervention and targeted delivery of Wnt proteins is an innovative and promising strategy. Although further refinement and optimization of this technique will be required to improve efficacy, the authors believe that this approach will open new avenues toward unconventional prenatal interventions for patients with cleft lip with or without cleft palate, and provide future approaches for prenatal repair of other congenital head and neck disorders.