Influence of Touch-Spun Nanofiber Diameter on Contact Guidance during Peripheral Nerve Repair.

Peripheral nerve regeneration across large gaps remains clinically challenging and scaffold design plays a key role in nerve tissue engineering. One strategy to encourage regeneration has utilized nanofibers or conduits to exploit contact guidance within the neural regenerative milieu. Herein, we report the effect of nanofiber topography on two key aspects of regeneration: Schwann cell migration and neurite extension. Substrates possessing distinct diameter distributions (300 ± 40 to 900 ± 70 nm) of highly aligned poly(ε-caprolactone) nanofibers were fabricated by touch-spinning. Cell migratory behavior and contact guidance were then evaluated both at the tissue level using dorsal root ganglion tissue explants and the cellular level using dissociated Schwann cells. Explant studies showed that Schwann cells emigrated significantly farther on fibers than control. However, both Schwann cells and neurites emigrated from the tissue explants directionally along the fibers regardless of their diameter, and the data were characterized by high variation. At the cellular level, dissociated Schwann cells demonstrated biased migration in the direction of fiber alignment and exhibited a significantly higher biased velocity (0.2790 ± 0.0959 µm·min-1) on 900 ± 70 nm fibers compared to other nanofiber groups and similar to the velocity found during explant emigration on 900 nm fibers. Therefore, aligned, nanofibrous scaffolds of larger diameters (900 ± 70 nm) may be promising materials to enhance various aspects of nerve regeneration via contact guidance alone. While cells track along with the fibers, this contact guidance is bidirectional along the fiber, moving in the plane of alignment. Therefore, the next critical step to direct regeneration is to uncover haptotactic cues that enhance directed migration.

Zwitterion Surface-Functionalized Thermoplastic Polyurethane for Antifouling Catheter Applications.

Immobilizing zwitterionic molecules on material surfaces has been a promising strategy for creating antifouling surfaces. Herein, we show the ability to surface derivatize an allyl-ether-functionalized thermoplastic polyurethane (TPU) with a zwitterionic thiol in a radically induced thiol-ene reaction. The thermoplastic polyurethane was synthesized to have an allyl-ether side functionality using a modified chain extender molecule. The zwitterion surface functionalization was achieved via thiol-ene reaction in aqueous conditions. The presence of chemically tethered zwitterion moieties on the TPU surface was confirmed using X-ray photoelectron spectroscopy (XPS). Protein adsorption experiments via quartz crystal microbalance (QCM) show reduced fibrinogen attachment for the zwitterion-derivatized TPU when compared to its nonfunctionalized controls. The Zwitterion-TPU also showed a log scale reduction in bacterial adherence. For Pseudomonas aeruginosa and Staphylococcus epidermidis, the Zwitterion-TPU resulted in around a 40 and 50% lower bacterial biomass accumulation, respectively, over the time scale of the experiment. The fibroblast cell viability of TPU remained unaffected by functionalization with zwitterion thiol. The results from our model experiments suggest that a zwitterion-modified TPU is a promising candidate for antifouling catheters.

Anti-adhesive bioresorbable elastomer-coated composite hernia mesh that reduce intraperitoneal adhesions.

Intraperitoneal adhesions (IAs) are a major complication arising from abdominal repair surgeries, including hernia repair procedures. Herein, we fabricated a composite mesh device using a macroporous monofilament polypropylene mesh and a degradable elastomer coating designed to meet the requirements of this clinical application. The degradable elastomer was synthesized using an organo-base catalyzed thiol-yne addition polymerization that affords independent control of degradation rate and mechanical properties. The elastomeric coating was further enhanced by the covalent tethering of antifouling zwitterion molecules. Mechanical testing demonstrated the elastomer forms a robust coating on the polypropylene mesh does not exhibit micro-fractures, cracks or mechanical delamination under cyclic fatigue testing that exceeds peak abdominal loads (50 N/cm). Quartz crystal microbalance measurements showed the zwitterionic functionalized elastomer further reduced fibrinogen adsorption by 73% in vitro when compared to unfunctionalized elastomer controls. The elastomer exhibited degradation with limited tissue response in a 10-week murine subcutaneous implantation model. We also evaluated the composite mesh in an 84-day study in a rabbit cecal abrasion hernia adhesion model. The zwitterionic composite mesh significantly reduced the extent and tenacity of IAs by 94% and 90% respectively with respect to uncoated polypropylene mesh. The resulting composite mesh device is an excellent candidate to reduce complications related to abdominal repair through suppressed fouling and adhesion formation, reduced tissue inflammation, and appropriate degradation rate.

Resorbable barrier polymers for flexible bioelectronics.

Resorbable, implantable bioelectronic devices are emerging as powerful tools to reliably monitor critical physiological parameters in real time over extended periods. While degradable magnesium-based electronics have pioneered this effort, relatively short functional lifetimes have slowed clinical translation. Barrier films that are both flexible and resorbable over predictable timelines would enable tunability in device lifetime and expand the viability of these devices. Herein, we present a library of stereocontrolled succinate-based copolyesters which leverage copolymer composition and processing method to afford tunability over thermomechanical, crystalline, and barrier properties. One copolymer composition within this library has extended the functional lifetime of transient bioelectronic prototypes over existing systems by several weeks-representing a considerable step towards translational devices.

Antibiotic eluting poly(ester urea) films for control of a model cardiac implantable electronic device infection.

Cardiac implantable electronic device (CIED) infections acquired during or after surgical procedures are a major complication that are challenging to treat therapeutically, resulting in chronic and sometimes fatal infections. Localized delivery of antibiotics at the surgical site could be used to supplement traditional systemic administration as a preventative measure. Herein, we investigate a cefazolin-eluting l-valine poly(ester urea) (PEU) films as a model system for localized antibiotic delivery for CIEDs. Poly(1-VAL-8) PEU was used to fabricate a series of antibiotic-loaded films with varied loading concentrations (2%, 5%, 10% wt/wt) and thicknesses (40 µm, 80 µm, 140 µm). In vitro release measurements show thickness and loading concentration influence the amount and rate of cefazolin release. Group 10%-140 µm (load-thickness) showed 22.5% release of active pharmaceutical ingredient (API) in the first 24 h and 81.2% of cumulative percent release through day 14 and was found most effective in bacterial clearance in vitro. This group was also effective in clearing a bacterial infection in a model in vivo rat study while eliciting a limited inflammatory response. Our results suggest the feasibility of cefazolin-loaded PEU films as an effective sustained release matrix for localized delivery of antibiotics. SIGNIFICANCE STATEMENT: Implant-associated infections acquired during surgical procedures are a major complication that have proven a challenge to treat clinically, resulting in chronic and sometimes fatal infections. In this manuscript, we investigate an antibiotic-eluting L-valine poly(ester urea) (PEU) films as a model system for localized delivery of cefazolin. Significantly, we demonstrate a wide variation in temporal delivery and dosing within this family of PEUs and show that the delivery can be extended by varying the film thickness. The in vivo results show efficacy in an infected wound model and suggest antibiotic loaded PEU films function as an effective sustained release matrix for localized delivery of antibiotics across a number of clinical indications.