Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging

Sara Abrahamsson; Rob Ilic; Jan Wisniewski; Brian Mehl; Liya Yu; Lei Chen; Marcelo Davanco; Laura Oudjedi; Jean Bernard Fiche; Bassam Hajj; Xin Jin; Joan Pulupa; Christine Cho; Mustafa Mir; Mohamed El Beheiry; Xavier Darzacq; Marcelo Nollmann; Maxime Dahan; Carl Wu; Timothée Lionnet; J. Alexander Liddle; Cornelia I. Bargmann

doi:10.1364/BOE.7.000855

Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging

Sara Abrahamsson, Rob Ilic, Jan Wisniewski, Brian Mehl, Liya Yu, Lei Chen, Marcelo Davanco, Laura Oudjedi, Jean Bernard Fiche, Bassam Hajj, Xin Jin, Joan Pulupa, Christine Cho, Mustafa Mir, Mohamed El Beheiry, Xavier Darzacq, Marcelo Nollmann, Maxime Dahan, Carl Wu, Timothée LionnetJ. Alexander Liddle, Cornelia I. Bargmann

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

49 Scopus citations

Abstract

Multifocus microscopy (MFM) allows high-resolution instantaneous three-dimensional (3D) imaging and has been applied to study biological specimens ranging from single molecules inside cells nuclei to entire embryos. We here describe pattern designs and nanofabrication methods for diffractive optics that optimize the lightefficiency of the central optical component of MFM: the diffractive multifocus grating (MFG). We also implement a “precise color” MFM layout with MFGs tailored to individual fluorophores in separate optical arms. The reported advancements enable faster and brighter volumetric time-lapse imaging of biological samples. In live microscopy applications, photon budget is a critical parameter and light-efficiency must be optimized to obtain the fastest possible frame rate while minimizing photodamage. We provide comprehensive descriptions and code for designing diffractive optical devices, and a detailed methods description for nanofabrication of devices. Theoretical efficiencies of reported designs is ≈90% and we have obtained efficiencies of > 80% in MFGs of our own manufacture. We demonstrate the performance of a multi-phase MFG in 3D functional neuronal imaging in living C. elegans.

Original language	English
Article number	253387
Pages (from-to)	855-869
Number of pages	15
Journal	Biomedical Optics Express
Volume	7
Issue number	3
DOIs	https://doi.org/10.1364/BOE.7.000855
State	Published - 16 Feb 2016
Externally published	Yes

Keywords

Diffractive optics
Fluorescence microscopy
Multiple imaging
Polarization
Three-dimensional microscopy

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10.1364/BOE.7.000855

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Abrahamsson, S., Ilic, R., Wisniewski, J., Mehl, B., Yu, L., Chen, L., Davanco, M., Oudjedi, L., Fiche, J. B., Hajj, B., Jin, X., Pulupa, J., Cho, C., Mir, M., El Beheiry, M., Darzacq, X., Nollmann, M., Dahan, M., Wu, C., ... Bargmann, C. I. (2016). Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging. Biomedical Optics Express, 7(3), 855-869. Article 253387. https://doi.org/10.1364/BOE.7.000855

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title = "Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging",

abstract = "Multifocus microscopy (MFM) allows high-resolution instantaneous three-dimensional (3D) imaging and has been applied to study biological specimens ranging from single molecules inside cells nuclei to entire embryos. We here describe pattern designs and nanofabrication methods for diffractive optics that optimize the lightefficiency of the central optical component of MFM: the diffractive multifocus grating (MFG). We also implement a “precise color” MFM layout with MFGs tailored to individual fluorophores in separate optical arms. The reported advancements enable faster and brighter volumetric time-lapse imaging of biological samples. In live microscopy applications, photon budget is a critical parameter and light-efficiency must be optimized to obtain the fastest possible frame rate while minimizing photodamage. We provide comprehensive descriptions and code for designing diffractive optical devices, and a detailed methods description for nanofabrication of devices. Theoretical efficiencies of reported designs is ≈90\% and we have obtained efficiencies of > 80\% in MFGs of our own manufacture. We demonstrate the performance of a multi-phase MFG in 3D functional neuronal imaging in living C. elegans.",

keywords = "Diffractive optics, Fluorescence microscopy, Multiple imaging, Polarization, Three-dimensional microscopy",

author = "Sara Abrahamsson and Rob Ilic and Jan Wisniewski and Brian Mehl and Liya Yu and Lei Chen and Marcelo Davanco and Laura Oudjedi and Fiche, \{Jean Bernard\} and Bassam Hajj and Xin Jin and Joan Pulupa and Christine Cho and Mustafa Mir and \{El Beheiry\}, Mohamed and Xavier Darzacq and Marcelo Nollmann and Maxime Dahan and Carl Wu and Timoth{\'e}e Lionnet and \{Alexander Liddle\}, J. and Bargmann, \{Cornelia I.\}",

note = "Publisher Copyright: {\textcopyright} 2016 Optical Society of America.",

year = "2016",

month = feb,

day = "16",

doi = "10.1364/BOE.7.000855",

language = "英语",

volume = "7",

pages = "855--869",

journal = "Biomedical Optics Express",

issn = "2156-7085",

publisher = "Optica Publishing Group (formerly OSA)",

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Abrahamsson, S, Ilic, R, Wisniewski, J, Mehl, B, Yu, L, Chen, L, Davanco, M, Oudjedi, L, Fiche, JB, Hajj, B, Jin, X, Pulupa, J, Cho, C, Mir, M, El Beheiry, M, Darzacq, X, Nollmann, M, Dahan, M, Wu, C, Lionnet, T, Alexander Liddle, J & Bargmann, CI 2016, 'Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging', Biomedical Optics Express, vol. 7, no. 3, 253387, pp. 855-869. https://doi.org/10.1364/BOE.7.000855

TY - JOUR

T1 - Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging

AU - Abrahamsson, Sara

AU - Ilic, Rob

AU - Wisniewski, Jan

AU - Mehl, Brian

AU - Yu, Liya

AU - Chen, Lei

AU - Davanco, Marcelo

AU - Oudjedi, Laura

AU - Fiche, Jean Bernard

AU - Hajj, Bassam

AU - Jin, Xin

AU - Pulupa, Joan

AU - Cho, Christine

AU - Mir, Mustafa

AU - El Beheiry, Mohamed

AU - Darzacq, Xavier

AU - Nollmann, Marcelo

AU - Dahan, Maxime

AU - Wu, Carl

AU - Lionnet, Timothée

AU - Alexander Liddle, J.

AU - Bargmann, Cornelia I.

PY - 2016/2/16

Y1 - 2016/2/16

N2 - Multifocus microscopy (MFM) allows high-resolution instantaneous three-dimensional (3D) imaging and has been applied to study biological specimens ranging from single molecules inside cells nuclei to entire embryos. We here describe pattern designs and nanofabrication methods for diffractive optics that optimize the lightefficiency of the central optical component of MFM: the diffractive multifocus grating (MFG). We also implement a “precise color” MFM layout with MFGs tailored to individual fluorophores in separate optical arms. The reported advancements enable faster and brighter volumetric time-lapse imaging of biological samples. In live microscopy applications, photon budget is a critical parameter and light-efficiency must be optimized to obtain the fastest possible frame rate while minimizing photodamage. We provide comprehensive descriptions and code for designing diffractive optical devices, and a detailed methods description for nanofabrication of devices. Theoretical efficiencies of reported designs is ≈90% and we have obtained efficiencies of > 80% in MFGs of our own manufacture. We demonstrate the performance of a multi-phase MFG in 3D functional neuronal imaging in living C. elegans.

AB - Multifocus microscopy (MFM) allows high-resolution instantaneous three-dimensional (3D) imaging and has been applied to study biological specimens ranging from single molecules inside cells nuclei to entire embryos. We here describe pattern designs and nanofabrication methods for diffractive optics that optimize the lightefficiency of the central optical component of MFM: the diffractive multifocus grating (MFG). We also implement a “precise color” MFM layout with MFGs tailored to individual fluorophores in separate optical arms. The reported advancements enable faster and brighter volumetric time-lapse imaging of biological samples. In live microscopy applications, photon budget is a critical parameter and light-efficiency must be optimized to obtain the fastest possible frame rate while minimizing photodamage. We provide comprehensive descriptions and code for designing diffractive optical devices, and a detailed methods description for nanofabrication of devices. Theoretical efficiencies of reported designs is ≈90% and we have obtained efficiencies of > 80% in MFGs of our own manufacture. We demonstrate the performance of a multi-phase MFG in 3D functional neuronal imaging in living C. elegans.

KW - Diffractive optics

KW - Fluorescence microscopy

KW - Multiple imaging

KW - Polarization

KW - Three-dimensional microscopy

UR - https://www.scopus.com/pages/publications/84961653915

U2 - 10.1364/BOE.7.000855

DO - 10.1364/BOE.7.000855

M3 - 文章

AN - SCOPUS:84961653915

SN - 2156-7085

VL - 7

SP - 855

EP - 869

JO - Biomedical Optics Express

JF - Biomedical Optics Express

IS - 3

M1 - 253387

ER -

Multifocus microscopy with precise color multiphase diffractive optics applied in functional neuronal imaging

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