Fiber optic distributed sensing network for shape sensing-assisted epidural needle guidance

Aida Amantayeva; Nargiz Adilzhanova; Aizhan Issatayeva; Wilfried Blanc; Carlo Molardi; Daniele Tosi

doi:10.3390/bios11110446

Fiber optic distributed sensing network for shape sensing-assisted epidural needle guidance

Aida Amantayeva, Nargiz Adilzhanova, Aizhan Issatayeva, Wilfried Blanc, Carlo Molardi, Daniele Tosi

School of Engineering and Digital Sciences

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

Epidural anesthesia is a pain management process that requires the insertion of a miniature needle through the epidural space located within lumbar vertebrae. The use of a guidance system for manual insertion can reduce failure rates and provide increased efficiency in the process. In this work, we present and experimentally assess a guidance system based on a network of fiber optic distributed sensors. The fibers are mounted externally to the needle, without blocking its inner channel, and through a strain-to-shape detection method reconstruct the silhouette of the epidural device in real time (1 s). We experimentally assessed the shape sensing methods over 25 experiments performed in a phantom, and we observed that the sensing system correctly identified bending patterns typical in epidural insertions, characterized by the different stiffness of the tissues. By studying metrics related to the curvatures and their temporal changes, we provide identifiers that can potentially serve for the (in)correct identification of the epidural space, and support the operator through the insertion process by recognizing the bending patterns.

Original language	English
Article number	446
Journal	Biosensors
Volume	11
Issue number	11
DOIs	https://doi.org/10.3390/bios11110446
Publication status	Published - Nov 2021

Funding

Funding: The research was funded through Nazarbayev University under grants SMARTER (code: 091019CRP2117), EPICGuide (code: 240919FD3908), and Distributed Measurement of Bite Force by Fiber-Optic Sensorized Dental Guard (021220FD1851), and the grant Nanoslim ANR-17-CE08-0002-05 project granted by The French National Research Agency. The authors would like to acknowledge the support of NPO Young Researchers Alliance and the Nazarbayev University Corporate “Social Development Fund” for a grant under their Fostering Research and Innovation Potential Program.

Keywords

Distributed sensors
Epidural anesthesia
Epidural needle
Fiber-optic shape sensors
Optical fiber sensor
Smart surgical instruments

ASJC Scopus subject areas

Analytical Chemistry
Biotechnology
Biomedical Engineering
Instrumentation
Engineering (miscellaneous)
Clinical Biochemistry

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10.3390/bios11110446

Cite this

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title = "Fiber optic distributed sensing network for shape sensing-assisted epidural needle guidance",

abstract = "Epidural anesthesia is a pain management process that requires the insertion of a miniature needle through the epidural space located within lumbar vertebrae. The use of a guidance system for manual insertion can reduce failure rates and provide increased efficiency in the process. In this work, we present and experimentally assess a guidance system based on a network of fiber optic distributed sensors. The fibers are mounted externally to the needle, without blocking its inner channel, and through a strain-to-shape detection method reconstruct the silhouette of the epidural device in real time (1 s). We experimentally assessed the shape sensing methods over 25 experiments performed in a phantom, and we observed that the sensing system correctly identified bending patterns typical in epidural insertions, characterized by the different stiffness of the tissues. By studying metrics related to the curvatures and their temporal changes, we provide identifiers that can potentially serve for the (in)correct identification of the epidural space, and support the operator through the insertion process by recognizing the bending patterns.",

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AU - Adilzhanova, Nargiz

AU - Issatayeva, Aizhan

AU - Blanc, Wilfried

AU - Molardi, Carlo

AU - Tosi, Daniele

PY - 2021/11

Y1 - 2021/11

N2 - Epidural anesthesia is a pain management process that requires the insertion of a miniature needle through the epidural space located within lumbar vertebrae. The use of a guidance system for manual insertion can reduce failure rates and provide increased efficiency in the process. In this work, we present and experimentally assess a guidance system based on a network of fiber optic distributed sensors. The fibers are mounted externally to the needle, without blocking its inner channel, and through a strain-to-shape detection method reconstruct the silhouette of the epidural device in real time (1 s). We experimentally assessed the shape sensing methods over 25 experiments performed in a phantom, and we observed that the sensing system correctly identified bending patterns typical in epidural insertions, characterized by the different stiffness of the tissues. By studying metrics related to the curvatures and their temporal changes, we provide identifiers that can potentially serve for the (in)correct identification of the epidural space, and support the operator through the insertion process by recognizing the bending patterns.

AB - Epidural anesthesia is a pain management process that requires the insertion of a miniature needle through the epidural space located within lumbar vertebrae. The use of a guidance system for manual insertion can reduce failure rates and provide increased efficiency in the process. In this work, we present and experimentally assess a guidance system based on a network of fiber optic distributed sensors. The fibers are mounted externally to the needle, without blocking its inner channel, and through a strain-to-shape detection method reconstruct the silhouette of the epidural device in real time (1 s). We experimentally assessed the shape sensing methods over 25 experiments performed in a phantom, and we observed that the sensing system correctly identified bending patterns typical in epidural insertions, characterized by the different stiffness of the tissues. By studying metrics related to the curvatures and their temporal changes, we provide identifiers that can potentially serve for the (in)correct identification of the epidural space, and support the operator through the insertion process by recognizing the bending patterns.

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KW - Epidural needle

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KW - Optical fiber sensor

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Fiber optic distributed sensing network for shape sensing-assisted epidural needle guidance

Abstract

Funding

Keywords

ASJC Scopus subject areas

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