Instrumented spinal cord surrogate using optical fiber: Role of the fiber's location

2017 13th IASTED International Conference on Biomedical Engineering (BioMed) Pub Date : 2017-01-01 DOI:10.2316/P.2017.852-028

Yann Facchinello, E. Wagnac, B. Ung, Y. Petit, Prabin Pradhan, Louis-Marie Peyrache, J. Mac-Thiong

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引用次数: 1

Abstract

In vitro replication of traumatic spinal cord injury is necessary to understand its biomechanics and to improve prevention devices and care. During the trauma, the spinal cord withstands an impaction at high velocity. In order to fully assess spinal cord compression, a physical spinal cord surrogate instrumented with bare optical fibers is a promising avenue. The sensing is based on light transmission loss observed in optical fibers subjected to bending. In this paper, the role of the fibers' position within the surrogate is presented and discussed. The closer the fiber from the surface of the spinal cord, the more sensitive it is to small compression magnitude. A threshold value of 15 % was observed for the fiber located at the upper surface of the surrogate. However, this fiber was not able to record compression over 40 %. Another fiber located in the middle of the surrogate was needed to record compression between 40 % to 85 %. Using two fibers allows continuous recording of compressions ranging from 15 % to 85 %. This study shows the relevance of using multiple fibers in order to fully assess the compression of the spinal cord surrogate.

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使用光纤仪器化脊髓替代物:光纤位置的作用

体外复制外伤性脊髓损伤是了解其生物力学和改进预防装置和护理的必要条件。在创伤过程中，脊髓承受高速撞击。为了充分评估脊髓压迫，裸光纤物理脊髓替代仪器是一种很有前途的途径。传感是基于在光纤中观察到的受弯曲的光传输损耗。在本文中，纤维的位置在代理提出和讨论的作用。纤维离脊髓表面越近，对小的压缩幅度越敏感。对于位于代孕体上表面的纤维，观察到的阈值为15%。然而，这种纤维不能记录超过40%的压缩。另一根位于代孕体中间的纤维需要记录40%到85%的压缩。使用两根纤维可以连续记录从15%到85%的压缩。这项研究表明，为了充分评估脊髓替代物的压迫，使用多种纤维的相关性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 13th IASTED International Conference on Biomedical Engineering (BioMed)

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