Surface Chemistry of LLZO Garnet Electrolytes with Sulfur in Electron Pair Donor Solvents.

Conventional Li-S batteries rely on liquid electrolytes based on LiNO3/DOL/DME mixtures that produce a quasistable interface with the lithium anode. Electron pair donor (EPD) solvents, also known as high donor number solvents, provide much higher polysulfide solubility and close-to-ideal sulfur utilization, making them solvents of choice for lean electrolyte Li-S cells. However, their instability to reduction requires incorporation of an ion-conductive membrane that is stable with Li-such as garnet LLZO and also stable with sulfur/polysulfides. We report that even trace amounts of LiOH on a LLTZO surface trigger a complex reaction with sulfur dissolved in typical EPD solvents (i.e., N,N-dimethylacetamide, DMA) to produce a highly resistive impedance layer that quickly grows with time from 1000 to 10,000 Ω cm2 over a few hours, thus impeding Li+ transport across the interface. Decorating the LLZO with protective phosphate groups to produce a modified surface provides a very low charge-transfer resistance of 40 Ω cm2 that is maintained over time and inhibits the reaction of LiOH and dissolved sulfur. Hybrid liquid-solid electrolyte cells constructed on this concept result in a high sulfur utilization of 1400 mAh g-1 which is 85% of theoretical and remains constant over cycling even with conventional, unoptimized carbon/sulfur cathodes.

Peripheral nerve growth within a hydrogel microchannel scaffold supported by a kink-resistant conduit.

Nerve repair in several mm-long nerve gaps often requires an interventional technology. Microchannel scaffolds have proven effective for bridging nerve gaps and guiding axons in the peripheral nervous system (PNS). Nonetheless, fabricating microchannel scaffolds at this length scale remains a challenge and/or is time consuming and cumbersome. In this work, a simple computer-aided microdrilling technique was used to fabricate 10 mm-long agarose scaffolds consisting of 300 µm-microchannels and 85 µm-thick walls in less than an hour. The agarose scaffolds alone, however, did not exhibit adequate stiffness and integrity to withstand the mechanical stresses during implantation and suturing. To provide mechanical support and enable suturing, poly caprolactone (PCL) conduits were fabricated and agarose scaffolds were placed inside. A modified salt-leaching technique was developed to introduce interconnected porosity in PCL conduits to allow for tuning of the mechanical properties such as elastic modulus and strain to failure. It was shown that the PCL conduits were effective in stabilizing the agarose scaffolds in 10 mm-long sciatic nerve gaps of rats for at least 8 weeks. Robust axon ingress and Schwann cell penetration were observed within the microchannel scaffolds without using growth factors. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 105A: 3392-3399, 2017.

Hierarchically Ordered Porous and High-Volume Polycaprolactone Microchannel Scaffolds Enhanced Axon Growth in Transected Spinal Cords.

The goal of this work was to design nerve guidance scaffolds with a unique architecture to maximize the open volume available for nerve growth. Polycaprolactone (PCL) was selected as the scaffold material based on its biocompatibility and month-long degradation. Yet, dense PCL does not exhibit suitable properties such as porosity, stiffness, strength, and cell adhesion to function as an effective nerve guidance scaffold. To address these shortcomings, PCL was processed using a modified salt-leaching technique to create uniquely controlled interconnected porosity. By controlling porosity, we demonstrated that the elastic modulus could be controlled between 2.09 and 182.1 MPa. In addition, introducing porosity and/or coating with fibronectin enhanced the PCL cell attachment properties. To produce PCL scaffolds with maximized open volume, porous PCL microtubes were fabricated and translated into scaffolds with 60 volume percent open volume. The scaffolds were tested in transected rat spinal cords. Linear axon growth within both the microtubes as well as the interstitial space between the tubes was observed, demonstrating that the entire open volume of the scaffold was available for nerve growth. Overall, a novel scaffold architecture and fabrication technique are presented. The scaffolds exhibit significantly higher volume than state-of-the-art scaffolds for promising spinal cord nerve repair.

In Vivo Microcomputed Tomography of Nanocrystal-Doped Tissue Engineered Scaffolds.

Tissue engineered scaffolds (TES) hold promise for improving the outcome of cell-based therapeutic strategies for a variety of biomedical scenarios, including musculoskeletal injuries, soft tissue repair, and spinal cord injury. Key to TES research and development, and clinical use, is the ability to longitudinally monitor TES location, orientation, integrity, and microstructure following implantation. Here, we describe a strategy for using microcomputed tomography (microCT) to visualize TES following implantation into mice. TES were doped with highly radiopaque gadolinium oxide nanocrystals and were implanted into the hind limbs of mice. Mice underwent serial microCT over 23 weeks. TES were clearly visible over the entire time course. Alginate scaffolds underwent a 20% volume reduction over the first 6 weeks, stabilizing over the next 17 weeks. Agarose scaffold volumes were unchanged. TES attenuation was also unchanged over the entire time course, indicating a lack of nanocrystal dissolution or leakage. Histology at the implant site showed the presence of very mild inflammation, typical for a mild foreign body reaction. Blood work indicated marked elevation in liver enzymes, and hematology measured significant reduction in white blood cell counts. While extrapolation of the X-ray induced effects on hematopoiesis in these mice to humans is not straightforward, clearly this is an area for careful monitoring. Taken together, these data lend strong support that doping TES with radiopaque nanocrystals and performing microCT imaging, represents a possible strategy for enabling serial in vivo monitoring of TES.

Regeneration of long-tract axons through sites of spinal cord injury using templated agarose scaffolds.

Previously we reported that templated agarose scaffolds can orient and guide local spinal cord axons after injury. In the present study we examined whether growth of long-projecting spinal cord axons could also be promoted into, and then beyond, templated agarose scaffolds placed into a spinal cord lesion site. Ascending spinal cord dorsal column sensory axons were transected at the C4 level. Animals were then subjected to combinatorial therapies consisting of: 1) templated agarose scaffolds implanted into the lesion site, seeded with autologous bone marrow stromal cells expressing a growth factor, neurotrophin-3 (NT-3), 2) lentiviral vectors expressing NT-3 beyond the lesion site (to promote axonal emergence from the scaffold along chemotropic gradients of growth factors), and 3) priming lesions ("conditioning lesions") of the sensory neuronal cell body to stimulate the endogenous growth state of the injured neuron. Control groups received either non-organized, NT-3-expressing cell suspension grafts in the lesion site, or templated scaffolds plus one of the two components of the combination therapy. Among groups that received templated agarose scaffolds, long-tract sensory axonal regeneration occurred into the spinal cord lesion site, and the growth of these axons was remarkably organized and linear compared to non-organized cell suspension grafts. Axonal penetration was maximal in subjects that received combination therapies; further, 83 + 13% of axons entering the scaffolds in combination-treated subjects continued to grow the full length of the lesion cavity to reach the distal aspect of the scaffold, over a 2 mm distance. In contrast, axons regenerating into cell suspension grafts lacking guidance scaffolds exhibited a parabolic decay of growth as a function of distance, and only 22 + 6% of axons extended the length of the lesion cavity. Moreover, axonal regeneration beyond the lesion site occurred only among subjects that received full combinatorial treatments (p < 0.05). However, axon growth beyond the scaffold was constrained to a reactive cell layer that formed between the distal aspect of the scaffold and host tissue, and did not continue further to re-penetrate the host spinal cord. Thus, templated agarose scaffolds substantially enhance the organization and distance over which long-tract axons extend through a spinal cord lesion site in the presence of combinatorial therapies, but host-scaffold reactive interfaces limit axon re-penetration of the host. Further development must reduce reactive cellular interfaces to support effective axonal penetration of host parenchyma.