Tag Archives: DWI – Leibniz Institute for Interactive Materials

Accurate spatial orientation for regenerating cells

German scientists have developed a system that helps guide nerve cells into proper spatial alignmentswhen they are regenerating according to an April 5, 2017 news item on Nanowerk,

In many tissues of the human body, such as nerve tissue, the spatial organization of cells plays an important role. Nerve cells and their long protrusions assemble into nerve tracts and transport information throughout the body. When such a tissue is injured, an accurate spatial orientation of the cells facilitates the healing process. Scientists from the DWI – Leibniz Institute for Interactive Materials in Aachen developed an injectable gel, which can act as a guidance system for nerve cells.

An April 5, 2017 Leibniz Institute press release, which originated the news item, explains more about the research,

Inside the body, an extracellular matrix surrounds the cells. It provides mechanical support and promotes spatial tissue organization. In order to regenerate damaged tissue, an artificial matrix can temporally replace the natural extracellular matrix. This matrix needs to mimic the natural cell environment in order to efficiently stimulate the regenerative potential of the surrounding tissue. Solid implants, however, may impair remaining healthy tissue whereas soft, injectable materials allow for a minimal invasive therapy, which is particularly beneficial for sensitive tissues, such as the spinal cord. Unfortunately, up to now, artificial soft materials did not yet reproduce the complex structures and spatial properties of natural tissues.

A team of scientists, headed by Dr. Laura De Laporte from the DWI – Leibniz Institute for Interactive Materials, developed a new, minimal invasive material termed ‘Anisogel’. “If you aim to enhance the regeneration of damaged spinal cord tissue, you need to come up with a new material concept,” says Jonas Rose. He is a PhD student working on the Anisogel project. “We use micrometer-sized building blocks and assemble them into 3D hierarchically organized structures.” Anisogel consists of two gel components. Many, microscopically small, soft rod-shaped gels, incorporated with a low amount of magnetic nanoparticles, are the first component. Using a weak magnetic field, scientists can orient the gel rods, after which a very soft surrounding gel matrix is crosslinked, forming the structural guidance system. The gel rods, being stabilized by the gel matrix, maintain their orientation, even after removal of the magnetic field. Using cell culture experiments, the researchers demonstrate that cells can easily migrate through this gel matrix, and that nerve cells and fibroblasts orient along the paths provided by this guidance system.  A low amount of one percent gel rods inside the entire Anisogel volume is proven to be sufficient to induce linear nerve growth. The material, developed by the Aachen-based scientists, is the first injectable biomaterial, which assembles into a controlled oriented structure after injection and provides a functional guidance system for cells. “To meet the complex requirements of this approach, the project team includes researchers with very different areas of expertise,” says Laura De Laporte, whose research is supported by a Starting Grant of the European Research Council. “This interdisciplinary work is what makes this project so fascinating.”

“Although our cell culture experiments were successful, we are prepared to go a long way to translate our Anisogel into a medical therapy. In collaboration with the Uniklinik RWTH Aachen, we currently plan pre-clinical studies to further test and optimize this material,” Laura De Laporte explains.

Here’s a link to and a citation for the paper,

Nerve Cells Decide to Orient inside an Injectable Hydrogel with Minimal Structural Guidance  by Jonas C. Rose, María Cámara-Torres, Khosrow Rahimi, Jens Köhler, Martin Möller, and Laura De Laporte. Nano Lett., Article ASAP DOI: 10.1021/acs.nanolett.7b01123 Publication Date (Web): March 22, 2017

Copyright © 2017 American Chemical Society

This paper is behind a paywall.