Label-free nanoscale optical metrology on myelinated axons in vivo

Junhwan Kwon; Moonseok Kim; Hyejin Park; Bok Man Kang; Yongjae Jo; Jae Hwan Kim; Oliver James; Seok Hyun Yun; Seong Gi Kim; Minah Suh; Myunghwan Choi

doi:10.1038/s41467-017-01979-2

Label-free nanoscale optical metrology on myelinated axons in vivo

Junhwan Kwon, Moonseok Kim, Hyejin Park, Bok Man Kang, Yongjae Jo, Jae Hwan Kim, Oliver James, Seok Hyun Yun, Seong Gi Kim, Minah Suh, Myunghwan Choi

Department of Biomedical Engineering

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

27 Scopus citations

Abstract

In the mammalian nervous system, myelin provides electrical insulation for the neural circuit by forming a highly organized, multilayered thin film around the axon fibers. Here, we investigate the spectral reflectance from this subcellular nanostructure and devise a new label-free technique based on a spectroscopic analysis of reflected light, enabling nanoscale imaging of myelinated axons in their natural living state. Using this technique, we demonstrate three-dimensional mapping of the axon diameter and sensing of dynamic changes in the substructure of myelin at nanoscale. We further reveal the prevalence of axon bulging in the brain cortex in vivo after mild compressive trauma. Our novel tool opens new avenues of investigation by creating unprecedented access to the nanostructural dynamics of live myelinated axons in health and disease.

Original language	English
Article number	1832
Journal	Nature Communications
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-01979-2
State	Published - 1 Dec 2017

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title = "Label-free nanoscale optical metrology on myelinated axons in vivo",

abstract = "In the mammalian nervous system, myelin provides electrical insulation for the neural circuit by forming a highly organized, multilayered thin film around the axon fibers. Here, we investigate the spectral reflectance from this subcellular nanostructure and devise a new label-free technique based on a spectroscopic analysis of reflected light, enabling nanoscale imaging of myelinated axons in their natural living state. Using this technique, we demonstrate three-dimensional mapping of the axon diameter and sensing of dynamic changes in the substructure of myelin at nanoscale. We further reveal the prevalence of axon bulging in the brain cortex in vivo after mild compressive trauma. Our novel tool opens new avenues of investigation by creating unprecedented access to the nanostructural dynamics of live myelinated axons in health and disease.",

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AU - Kwon, Junhwan

AU - Kim, Moonseok

AU - Park, Hyejin

AU - Kang, Bok Man

AU - Jo, Yongjae

AU - Kim, Jae Hwan

AU - James, Oliver

AU - Yun, Seok Hyun

AU - Kim, Seong Gi

AU - Suh, Minah

AU - Choi, Myunghwan

PY - 2017/12/1

Y1 - 2017/12/1

N2 - In the mammalian nervous system, myelin provides electrical insulation for the neural circuit by forming a highly organized, multilayered thin film around the axon fibers. Here, we investigate the spectral reflectance from this subcellular nanostructure and devise a new label-free technique based on a spectroscopic analysis of reflected light, enabling nanoscale imaging of myelinated axons in their natural living state. Using this technique, we demonstrate three-dimensional mapping of the axon diameter and sensing of dynamic changes in the substructure of myelin at nanoscale. We further reveal the prevalence of axon bulging in the brain cortex in vivo after mild compressive trauma. Our novel tool opens new avenues of investigation by creating unprecedented access to the nanostructural dynamics of live myelinated axons in health and disease.

AB - In the mammalian nervous system, myelin provides electrical insulation for the neural circuit by forming a highly organized, multilayered thin film around the axon fibers. Here, we investigate the spectral reflectance from this subcellular nanostructure and devise a new label-free technique based on a spectroscopic analysis of reflected light, enabling nanoscale imaging of myelinated axons in their natural living state. Using this technique, we demonstrate three-dimensional mapping of the axon diameter and sensing of dynamic changes in the substructure of myelin at nanoscale. We further reveal the prevalence of axon bulging in the brain cortex in vivo after mild compressive trauma. Our novel tool opens new avenues of investigation by creating unprecedented access to the nanostructural dynamics of live myelinated axons in health and disease.

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DO - 10.1038/s41467-017-01979-2

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SN - 2041-1723

VL - 8

JO - Nature Communications

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Label-free nanoscale optical metrology on myelinated axons in vivo

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