Computational Tissue Volume Reconstruction of a Peripheral Nerve Using High-Resolution Light-Microscopy and Reconstruct

Mortimer Gierthmuehlen,Alexandra Mueller,Dennis T T Plachta,Thomas M Freiman,Kirsten Haastert-Talini,Jan Kaminsky,Thomas Stieglitz,Wulfila Gronenberg

doi:10.1371/journal.pone.0066191

Abstract

The development of neural cuff-electrodes requires several in vivo studies and revisions of the electrode design before the electrode is completely adapted to its target nerve. It is therefore favorable to simulate many of the steps involved in this process to reduce costs and animal testing. As the restoration of motor function is one of the most interesting applications of cuff-electrodes, the position and trajectories of myelinated fibers in the simulated nerve are important. In this paper, we investigate a method for building a precise neuroanatomical model of myelinated fibers in a peripheral nerve based on images obtained using high-resolution light microscopy. This anatomical model describes the first aim of our “Virtual workbench” project to establish a method for creating realistic neural simulation models based on image datasets. The imaging, processing, segmentation and technical limitations are described, and the steps involved in the transition into a simulation model are presented. The results showed that the position and trajectories of the myelinated axons were traced and virtualized using our technique, and small nerves could be reliably modeled based on of light microscopy images using low-cost OpenSource software and standard hardware. The anatomical model will be released to the scientific community.

Highlights

The recent development of neuroprostheses generated different concepts for the interaction between electrodes and the peripheral nervous system [1,2,3]
Based on the segmentation of single axons in a large confocal image set using Reconstruct software [18], this study addressed the following questions: (1) Is an image stack of consecutive light microscopy images sufficient to segment the myelinated portion of a peripheral nerve; (2) Could OpenSource software be used to create a realistic anatomical nerve model from this dataset; (3) Could this method be applied for larger and longer nerve segments; and (4) How can the model be simplified for transformation into a simulation model without losing valuable precision?
The simplification filter of maximal 0.4 (%) resulted in a reduction of vertices to 38%

Summary

Introduction

The recent development of neuroprostheses generated different concepts for the interaction between electrodes and the peripheral nervous system [1,2,3] These electrodes must offer the selective discrimination of the electrical activity inside the nerve and facilitate local fiber- or fascicle-specific stimulation without damaging neural integrity [4]. Multichannel cuff electrodes are one approach to this dilemma [5,6] These electrodes feature a large number of spaced contacts surrounding the nerve as an array of tripoles with a cathode in the middle of two anodes. It would be favorable to move as much as possible of the electrode development into the computer and perform simulation studies to reduce costs and animal testing

Methods

Results

Conclusion