Growth factor-functionalized silk membranes support wound healing in vitro.

Chronic wounds represent a serious problem in daily medical routine requiring improved wound care. Silk of the domesticated silkworm (Bombyx mori) has been used to form a variety of biomaterials for medical applications. We genetically engineered B. mori to produce silk functionalized with growth factors to promote wound healing in vitro. In this study FGF-, EGF-, KGF-, PDGF- or VEGF-functionalized silk membranes were compared to native B. mori silk membranes without growth factors for their ability to support wound healing in vitro. All silk membranes were cytocompatible and supported macrophage secretion of neutrophil recruiting factor CXCL1 and monocyte chemoattractant protein 1 (MCP-1). VEGF-functionalized silk significantly outperformed other growth factor-functionalized silk membranes, but not native silk in angiogenesis assays. In addition, EGF- and VEGF-functionalized silk membranes slightly enhanced macrophage adhesion compared to silk without growth factors. In wound healing assays in vitro (reduction of wound lesion), dermal equivalents showed a higher wound healing capacity when covered with EGF-, FGF- or VEGF-functionalized silk membranes compared to native, KGF- or PDGF-functionalized silk membranes. Keratinocyte migration and growth is overstimulated by KGF- and VEGF-functionalized silk membranes. In conclusion, growth factor-functionalized silk membranes prepared from genetically engineered silk worm glands are promising wound dressings for future wound healing therapies.

Mesenchymal stem cells can be recruited to wounded tissue via hepatocyte growth factor-loaded biomaterials.

Mesenchymal stem cells (MSC) are precursor cells of mesodermal tissue and, because of their trophic phenotype, they are known to play beneficial roles in wound healing. In addition, various tissue engineering strategies are based on MSC/biomaterial constructs. As the isolation and expansion of MSCs is a long-term process, a major goal is to develop an endogenous stem cell recruitment system that circumvents all ex vivo steps generally used for tissue engineering. Therefore collagen and silk fibroin were loaded with hepatocyte growth factor (HGF), a chemoattractant for MSCs. Collagen was mixed with HGF during polymerization, while silk fibroin and HGF were produced as fusion proteins by transgenic silkworms. To demonstrate release of active HGF, enzyme-linked immunosorbent assay, in vitro migration assays and animal studies were performed to demonstrate MSC migration in vivo, followed by detailed examinations of the immunological effects of the biomaterials. Hepatocyte growth factor was released burst-like, both from silk fibroin and collagen during the first 8 h and gradually for up to 168 h in vitro. Directed migration in vitro was demonstrated when MSCs were exposed to HGF. In vivo, HGF-loaded collagen and silk fibroin were tolerated as subcutaneous implants. In addition, it was proved that endogenous MSCs were recruited from the local environment. These results show for the first time recruitment of endogenous MSCs to HGF-loaded collagen (fast degradable) and silk fibroin scaffolds (long-term degradable) in vitro and in vivo. This knowledge could be applied to make off-the-shelf, readily available constructs for use in patients with chronic wound or burns. Copyright © 2016 John Wiley & Sons, Ltd.