Your search keyword '"Supper, Paul"' showing total 3 results

1. Comments on "Use of sliced or minced peripheral nerve segments for nerve regeneration through a biodegradable nerve conduit: A preliminary study in the rat".

Author

Supper P, Semmler L, and Radtke C

Subjects

Animals, Humans, Peripheral Nerves surgery, Rats, Nerve Regeneration physiology, Nerve Tissue

Published

2022

2. Defining the regenerative effects of native spider silk fibers on primary Schwann cells, sensory neurons, and nerve-associated fibroblasts.

Author

Millesi F, Weiss T, Mann A, Haertinger M, Semmler L, Supper P, Pils D, Naghilou A, and Radtke C

Subjects

Animals, Cell Movement, Cells, Cultured, Female, Fibroblasts physiology, Male, Neuronal Outgrowth, Rats, Rats, Sprague-Dawley, Schwann Cells physiology, Sensory Receptor Cells physiology, Spiders, Fibroblasts drug effects, Nerve Regeneration, Schwann Cells drug effects, Sensory Receptor Cells drug effects, Silk pharmacology

Abstract

The search for a suitable material to promote regeneration after long-distance peripheral nerve defects turned the spotlight on spider silk. Nerve conduits enriched with native spider silk fibers as internal guiding structures previously demonstrated a regenerative outcome similar to autologous nerve grafts in animal studies. Nevertheless, spider silk is a natural material with associated limitations for clinical use. A promising alternative is the production of recombinant silk fibers that should mimic the outstanding properties of their native counterpart. However, in vitro data on the regenerative features that native silk fibers provide for cells involved in nerve regeneration are scarce. Thus, there is a lack of reference parameters to evaluate whether recombinant silk fiber candidates will be eligible for nerve repair in vivo. To gain insight into the regenerative effect of native spider silk, our study aims to define the behavioral response of primary Schwann cells (SCs), nerve-associated fibroblasts (FBs), and dorsal root ganglion (DRG) neurons cultured on native dragline silk from the genus Nephila and on laminin coated dishes. The established multi-color immunostaining panels together with confocal microscopy and live cell imaging enabled the analysis of cell identity, morphology, proliferation, and migration on both substrates in detail. Our findings demonstrated that native spider silk rivals laminin coating as it allowed attachment and proliferation and supported the characteristic behavior of all tested cell types. Axonal out-growth of DRG neurons occurred along longitudinally aligned SCs that formed sustained bundled structures resembling Bungner bands present in regenerating nerves. The migration of SCs along the silk fibers achieved the reported distance of regenerating axons of about 1 mm per day, but lacked directionality. Furthermore, rFBs significantly reduced the velocity of rSCs in co-cultures on silk fibers. In summary, this study (a) reveals features recombinant silk must possess and what modifications or combinations could be useful for enhanced nerve repair and (b) provides assays to evaluate the regenerative performance of silk fibers in vitro before being applied as internal guiding structure in nerve conduits in vivo., (© 2020 The Authors. The FASEB Journal published by Wiley Periodicals LLC on behalf of Federation of American Societies for Experimental Biology.)

Published

2021

3. Correlating the secondary protein structure of natural spider silk with its guiding properties for Schwann cells.

Author

Naghilou, Aida, Pöttschacher, Lena, Millesi, Flavia, Mann, Anda, Supper, Paul, Semmler, Lorenz, Weiss, Tamara, Backus, Ellen H.G., and Radtke, Christine

Subjects

*SPIDER silk, *SCHWANN cells, *PROTEIN structure, *SPIDER venom, *BRIDGE defects, *NERVE grafting, *PROTEIN conformation

Abstract

The successful reconstruction of supercritical peripheral nerve injuries remains a major challenge in modern medicine. Progress in tissue engineering has enabled the development of nerve guidance conduits as an alternative to autologous nerve transplantation and the enrichment of conduits with fibrous materials or hydrogels has shown great potential in bridging nerve defects. The application of the dragline silk of spider genus Nephila as a filament for nerve guidance conduits has led to promising results. However, the use of spider silk has been phenomenological so far and the reasons for its success are still not identified. This renders a targeted tuning of synthetic fibrous luminal fillings such as recombinant silk out of reach. In this work the existing research was extended and in addition to dragline, the cocoon silk of Nephila edulis , as well as the connecting and attaching silk of Avicularia avicularia were investigated. Scanning electron microscopy revealed a difference in size and morphology of the spider silks. However, in vitro experiments indicated that Schwann cells adhere to the four fibers, independent of these two attributes. Raman spectroscopy in native state and aqueous environment demonstrated similar secondary protein structures for dragline, cocoon, and connecting silk. In contrast, the attaching silk showed a significant lower conformation of β-sheets, crucial for the stiffness of the silk. This was in line with the in vitro experiments, where the flexible attaching silk fibers adhered to each other when placed in liquid. This resulted in their inability to guide Schwann cells, leading to the generation of cell agglomerations. This direct comparison demonstrated the crucial role of β-sheets conformation for the guidance properties of natural spider silk, providing essential insights into the necessary material properties for the integration of fibrous luminal fillings in nerve guidance conduits. Unlabelled Image • The diameter and the morphology of spider silk does not affect the adhesion of rat Schwann cells • Secondary protein structure of connecting silk from A. avicularia is similar to dragline and cocoon silk from N. edulis • The attaching silk of A. avicularia has a smaller β-sheets conformation • The β-sheets are crucial for the guiding properties of natural spider silk [ABSTRACT FROM AUTHOR]

Published

2020