Current therapeutic angiogenesis strategies are focused on the development of biologically responsive scaffolds that can deliver multiple angiogenic cytokines and/or cells in ischemic regions. Herein, we report on a novel electrospinning approach to fabricate cytokine-containing nanofibrous scaffolds with tunable architecture to promote angiogenesis. Fiber diameter and uniformity were controlled by varying the concentration of the polymeric (i.e. gelatin) solution, the feed rate, needle to collector distance, and electric field potential between the collector plate and injection needle. Scaffold fiber orientation (random vs. aligned) was achieved by alternating the polarity of two parallel electrodes placed on the collector plate thus dictating fiber deposition patterns. Basic fibroblast growth factor (bFGF) was physically immobilized within the gelatin scaffolds at variable concentrations and human umbilical vein endothelial cells (HUVEC) were seeded on the top of the scaffolds. Cell proliferation and migration was assessed as a function of growth factor loading and scaffold architecture. HUVECs successfully adhered onto gelatin B scaffolds and cell proliferation was directly proportional to the loading concentrations of the growth factor (0–100 bFGF ng/mL). Fiber orientation had a pronounced effect on cell morphology and orientation. Cells were spread along the fibers of the electrospun scaffolds with the aligned orientation and developed a spindle-like morphology parallel to the scaffold's fibers. In contrast, cells seeded onto the scaffolds with random fiber orientation, did not demonstrate any directionality and appeared to have a rounder shape. Capillary formation (i.e. sprouts length and number of sprouts per bead), assessed in a 3-D in vitro angiogenesis assay, was a function of bFGF loading concentration (0 ng, 50 ng and 100 ng per scaffold) for both types of electrospun scaffolds (i.e. with aligned or random fiber orientation).
Retinal degenerative diseases, such as glaucoma and macular degeneration, affect millions of people worldwide and ultimately lead to retinal cell death and blindness. Cell transplantation therapies for photoreceptors demonstrate integration and restoration of function, but transplantation into the ganglion cell layer is more complex, requiring guidance of axons from transplanted cells to the optic nerve head in order to reach targets in the brain. Here we create a biodegradable electrospun (ES) scaffold designed to direct the growth of retinal ganglion cell (RGC) axons radially, mimicking axon orientation in the retina. Using this scaffold we observed an increase in RGC survival and no significant change in their electrophysiological properties. When analyzed for alignment, 81% of RGCs were observed to project axons radially along the scaffold fibers, with no difference in alignment compared to the nerve fiber layer of retinal explants. When transplanted onto retinal explants, RGCs on ES scaffolds followed the radial pattern of the host retinal nerve fibers, whereas RGCs transplanted directly grew axons in a random pattern. Thus, the use of this scaffold as a cell delivery device represents a significant step towards the use of cell transplant therapies for the treatment of glaucoma and other retinal degenerative diseases.
Peripheral vascular disease is one of the major vascular complications in individuals suffering from diabetes and in the elderly that is associated with significant burden in terms of morbidity and mortality. Stem cell therapy is being tested as an attractive alternative to traditional surgery to prevent and treat this disorder. The goal of this study was to enhance the protective and reparative potential of marrow-isolated adult multilineage inducible (MIAMI) cells by incorporating them within a bio-inspired construct (BIC) made of 2 layers of gelatin B electrospun nanofibers. We hypothesized that the BIC would enhance MIAMI cell survival and engraftment, ultimately leading to a better functional recovery of the injured limb in our mouse model of critical limb ischemia compared to MIAMI cells used alone. Our study demonstrated that MIAMI cell-seeded BIC resulted in a wide range of positive outcomes with an almost full recovery of blood flow in the injured limb, thereby limiting the extent of ischemia and necrosis. Functional recovery was also the greatest when MIAMI cells were combined with BICs, compared to MIAMI cells alone or BICs in the absence of cells. Histology was performed 28 days after grafting the animals to explore the mechanisms at the source of these positive outcomes. We observed that our critical limb ischemia model induces an extensive loss of muscular fibers that are replaced by intermuscular adipose tissue (IMAT), together with a highly disorganized vascular structure. The use of MIAMI cells-seeded BIC prevented IMAT infiltration with some clear evidence of muscular fibers regeneration.
Acinetobacter baumannii has recently emerged as an important pathogen among wounded soldiers in Iraq. Because of its ability to develop resistance to antimicrobial agents, wound infections with A. baumannii are difficult to treat and can lead to septicemia and even death. Use of appropriate topical antimicrobial agents in these circumstances could be one of the first steps in the prevention of A. baumannii wound infections. In this study, we present the in vitro effects of seven common topical antimicrobial creams and dressings on A. baumannii. A. baumannii was subjected to sensitivity tests with mupirocin, silver sulfadiazine, mafenide acetate, a double-antibiotic combination of polymyxin and bacitracin, a triple-antibiotic combination of neomycin, bacitracin, and polymyxin, and two silver-containing dressings. Zones of inhibition were measured after 24 hours of incubation. Of the evaluated antimicrobial agents, mafenide acetate was the most efficacious, followed by mupirocin and triple- and double-antibiotic combinations (in decreasing order). The silver-containing dressings yielded smaller zones of inhibition, compared to the previously mentioned agents, and no zone of inhibition was observed with silver sulfadiazine. Further in vivo studies on the effects of antimicrobial agents against A. baumannii are necessary to substantiate these findings and to determine the potential clinical relevance of these therapies.
The field of therapeutic angiogenesis has been predominantly concentrated in modalities that incorporate pro-angiogenic growth factors and/or cells within polymeric constructs that are implanted into the ischemic region. There is growing evidence that construct architecture can significantly affect growth factor activity, cellular viability and differentiation potential. Electrospinning is an attractive but simple scaffold fabrication technique that offers several advantages over traditional fabrication approaches to prepare highly organized structures for therapeutic angiogenesis applications. We recently described the fabrication of nanofibrous scaffolds with aligned fiber orientation that directed cell migration and orientation (i.e. human umbilical vein endothelial cells). Herein we demonstrate the ability of bFGF containing nanofibrous gelatin B scaffolds with controlled fiber orientation to promote capillary formation in vivo. Aligned scaffolds loaded with bFGF induced the highest levels of reperfusion (73% increased in LDPI ratios by day 21 post ischemia induction) in comparison to all other groups including scaffolds with random fiber orientation. Furthermore, the newly formed vasculature, assessed by confocal microscopy, had a parallel alignment along the axis of the scaffold's fibers. In contrast, no vessel directionality was observed in the animals treated with scaffolds with random fiber orientation in the presence or absence of bFGF.
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