Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber

Sebastian A Vasquez-Lopez; Raphaël Turcotte; Vadim Koren; Martin Plöschner; Zahid Padamsey; Martin J Booth; Tomáš Čižmár; Nigel J Emptage

doi:10.1038/s41377-018-0111-0

Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber

Sebastian A Vasquez-Lopez, Raphaël Turcotte, Vadim Koren, Martin Plöschner, Zahid Padamsey, Martin J Booth, Tomáš Čižmár, Nigel J Emptage

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

Abstract

Achieving intravital optical imaging with diffraction-limited spatial resolution of deep-brain structures represents an important step toward the goal of understanding the mammalian central nervous system ^1,2,3,4. Advances in wavefront-shaping methods and computational power have recently allowed for a novel approach to high-resolution imaging, utilizing deterministic light propagation through optically complex media and, of particular importance for this work, multimode optical fibers (MMFs)^5,6,7. We report a compact and highly optimized approach for minimally invasive in vivo brain imaging applications. The volume of tissue lesion was reduced by more than 100-fold, while preserving diffraction-limited imaging performance utilizing wavefront control of light propagation through a single 50-μm-core MMF. Here, we demonstrated high-resolution fluorescence imaging of subcellular neuronal structures, dendrites and synaptic specializations, in deep-brain regions of living mice, as well as monitored stimulus-driven functional Ca²⁺ responses. These results represent a major breakthrough in the compromise between high-resolution imaging and tissue damage, heralding new possibilities for deep-brain imaging in vivo.

Original language	English
Article number	110
Number of pages	6
Journal	Light: Science & Applications
Volume	7
DOIs	https://doi.org/10.1038/s41377-018-0111-0
Publication status	Published - 19 Dec 2018

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Padamsey Z Subcellular spatial...
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title = "Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber",

abstract = "Achieving intravital optical imaging with diffraction-limited spatial resolution of deep-brain structures represents an important step toward the goal of understanding the mammalian central nervous system 1,2,3,4. Advances in wavefront-shaping methods and computational power have recently allowed for a novel approach to high-resolution imaging, utilizing deterministic light propagation through optically complex media and, of particular importance for this work, multimode optical fibers (MMFs)5,6,7. We report a compact and highly optimized approach for minimally invasive in vivo brain imaging applications. The volume of tissue lesion was reduced by more than 100-fold, while preserving diffraction-limited imaging performance utilizing wavefront control of light propagation through a single 50-μm-core MMF. Here, we demonstrated high-resolution fluorescence imaging of subcellular neuronal structures, dendrites and synaptic specializations, in deep-brain regions of living mice, as well as monitored stimulus-driven functional Ca2+ responses. These results represent a major breakthrough in the compromise between high-resolution imaging and tissue damage, heralding new possibilities for deep-brain imaging in vivo.",

author = "Vasquez-Lopez, {Sebastian A} and Rapha{\"e}l Turcotte and Vadim Koren and Martin Pl{\"o}schner and Zahid Padamsey and Booth, {Martin J} and Tom{\'a}{\v s} {\v C}i{\v z}m{\'a}r and Emptage, {Nigel J}",

year = "2018",

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doi = "10.1038/s41377-018-0111-0",

language = "English",

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T1 - Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber

AU - Vasquez-Lopez, Sebastian A

AU - Turcotte, Raphaël

AU - Koren, Vadim

AU - Plöschner, Martin

AU - Padamsey, Zahid

AU - Booth, Martin J

AU - Čižmár, Tomáš

AU - Emptage, Nigel J

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N2 - Achieving intravital optical imaging with diffraction-limited spatial resolution of deep-brain structures represents an important step toward the goal of understanding the mammalian central nervous system 1,2,3,4. Advances in wavefront-shaping methods and computational power have recently allowed for a novel approach to high-resolution imaging, utilizing deterministic light propagation through optically complex media and, of particular importance for this work, multimode optical fibers (MMFs)5,6,7. We report a compact and highly optimized approach for minimally invasive in vivo brain imaging applications. The volume of tissue lesion was reduced by more than 100-fold, while preserving diffraction-limited imaging performance utilizing wavefront control of light propagation through a single 50-μm-core MMF. Here, we demonstrated high-resolution fluorescence imaging of subcellular neuronal structures, dendrites and synaptic specializations, in deep-brain regions of living mice, as well as monitored stimulus-driven functional Ca2+ responses. These results represent a major breakthrough in the compromise between high-resolution imaging and tissue damage, heralding new possibilities for deep-brain imaging in vivo.

AB - Achieving intravital optical imaging with diffraction-limited spatial resolution of deep-brain structures represents an important step toward the goal of understanding the mammalian central nervous system 1,2,3,4. Advances in wavefront-shaping methods and computational power have recently allowed for a novel approach to high-resolution imaging, utilizing deterministic light propagation through optically complex media and, of particular importance for this work, multimode optical fibers (MMFs)5,6,7. We report a compact and highly optimized approach for minimally invasive in vivo brain imaging applications. The volume of tissue lesion was reduced by more than 100-fold, while preserving diffraction-limited imaging performance utilizing wavefront control of light propagation through a single 50-μm-core MMF. Here, we demonstrated high-resolution fluorescence imaging of subcellular neuronal structures, dendrites and synaptic specializations, in deep-brain regions of living mice, as well as monitored stimulus-driven functional Ca2+ responses. These results represent a major breakthrough in the compromise between high-resolution imaging and tissue damage, heralding new possibilities for deep-brain imaging in vivo.

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DO - 10.1038/s41377-018-0111-0

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SN - 2047-7538

VL - 7

JO - Light: Science & Applications

JF - Light: Science & Applications

M1 - 110

ER -

Subcellular spatial resolution achieved for deep-brain imaging in vivo using a minimally invasive multimode fiber

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