Statistical Deconvolution for Superresolution Fluorescence Microscopy

Statistical Deconvolution for Superresolution Fluorescence Microscopy

Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ∼10 nm but require a sparse distribution of simultaneously activated fluorophores in the field of view. Image analysis procedures for this approach typically discard data from cro...

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Published in:Biophysical journal Vol. 102; no. 10; pp. 2391 - 2400
Main Authors: Mukamel, Eran A., Babcock, Hazen, Zhuang, Xiaowei
Format: Journal Article
Language:English
Published: United States Elsevier Inc 16-05-2012
Biophysical Society
The Biophysical Society
Subjects:
Algorithms
cell structures
Computer Simulation
Correlation analysis
Fluorescence
fluorescence microscopy
image analysis
Immunohistochemistry
Maximum likelihood method
Microscopy, Fluorescence - methods
Microtubules - metabolism
Models, Statistical
Molecules
Simulation
Spectroscopy, Imaging, and Other Techniques
statistical models
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Abstract Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ∼10 nm but require a sparse distribution of simultaneously activated fluorophores in the field of view. Image analysis procedures for this approach typically discard data from crowded molecules with overlapping images, wasting valuable image information that is only partly degraded by overlap. A data analysis method that exploits all available fluorescence data, regardless of overlap, could increase the number of molecules processed per frame and thereby accelerate superresolution imaging speed, enabling the study of fast, dynamic biological processes. Here, we present a computational method, referred to as deconvolution-STORM (deconSTORM), which uses iterative image deconvolution in place of single- or multiemitter localization to estimate the sample. DeconSTORM approximates the maximum likelihood sample estimate under a realistic statistical model of fluorescence microscopy movies comprising numerous frames. The model incorporates Poisson-distributed photon-detection noise, the sparse spatial distribution of activated fluorophores, and temporal correlations between consecutive movie frames arising from intermittent fluorophore activation. We first quantitatively validated this approach with simulated fluorescence data and showed that deconSTORM accurately estimates superresolution images even at high densities of activated fluorophores where analysis by single- or multiemitter localization methods fails. We then applied the method to experimental data of cellular structures and demonstrated that deconSTORM enables an approximately fivefold or greater increase in imaging speed by allowing a higher density of activated fluorophores/frame.
AbstractList Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ∼10 nm but require a sparse distribution of simultaneously activated fluorophores in the field of view. Image analysis procedures for this approach typically discard data from crowded molecules with overlapping images, wasting valuable image information that is only partly degraded by overlap. A data analysis method that exploits all available fluorescence data, regardless of overlap, could increase the number of molecules processed per frame and thereby accelerate superresolution imaging speed, enabling the study of fast, dynamic biological processes. Here, we present a computational method, referred to as deconvolution-STORM (deconSTORM), which uses iterative image deconvolution in place of single- or multiemitter localization to estimate the sample. DeconSTORM approximates the maximum likelihood sample estimate under a realistic statistical model of fluorescence microscopy movies comprising numerous frames. The model incorporates Poisson-distributed photon-detection noise, the sparse spatial distribution of activated fluorophores, and temporal correlations between consecutive movie frames arising from intermittent fluorophore activation. We first quantitatively validated this approach with simulated fluorescence data and showed that deconSTORM accurately estimates superresolution images even at high densities of activated fluorophores where analysis by single- or multiemitter localization methods fails. We then applied the method to experimental data of cellular structures and demonstrated that deconSTORM enables an approximately fivefold or greater increase in imaging speed by allowing a higher density of activated fluorophores/frame.
Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ~10 nm but require a sparse distribution of simultaneously activated fluorophores in the field of view. Image analysis procedures for this approach typically discard data from crowded molecules with overlapping images, wasting valuable image information that is only partly degraded by overlap. A data analysis method that exploits all available fluorescence data, regardless of overlap, could increase the number of molecules processed per frame and thereby accelerate superresolution imaging speed, enabling the study of fast, dynamic biological processes. Here, we present a computational method, referred to as deconvolution-STORM (deconSTORM), which uses iterative image deconvolution in place of single- or multiemitter localization to estimate the sample. DeconSTORM approximates the maximum likelihood sample estimate under a realistic statistical model of fluorescence microscopy movies comprising numerous frames. The model incorporates Poisson-distributed photon-detection noise, the sparse spatial distribution of activated fluorophores, and temporal correlations between consecutive movie frames arising from intermittent fluorophore activation. We first quantitatively validated this approach with simulated fluorescence data and showed that deconSTORM accurately estimates superresolution images even at high densities of activated fluorophores where analysis by single- or multiemitter localization methods fails. We then applied the method to experimental data of cellular structures and demonstrated that deconSTORM enables an approximately fivefold or greater increase in imaging speed by allowing a higher density of activated fluorophores/frame. [PUBLICATION ABSTRACT]
Author Zhuang, Xiaowei
Mukamel, Eran A.
Babcock, Hazen
AuthorAffiliation Center for Brain Science, Harvard University, Cambridge, Massachusetts
Department of Chemistry and Chemical Biology, Department of Physics, and Howard Hughes Medical Institute, Harvard University, Cambridge, Massachusetts
AuthorAffiliation_xml – name: Department of Chemistry and Chemical Biology, Department of Physics, and Howard Hughes Medical Institute, Harvard University, Cambridge, Massachusetts
– name: Center for Brain Science, Harvard University, Cambridge, Massachusetts
Author_xml – sequence: 1
  givenname: Eran A.
  surname: Mukamel
  fullname: Mukamel, Eran A.
  email: eran@post.harvard.edu
  organization: Center for Brain Science, Harvard University, Cambridge, Massachusetts
– sequence: 2
  givenname: Hazen
  surname: Babcock
  fullname: Babcock, Hazen
  organization: Department of Chemistry and Chemical Biology, Department of Physics, and Howard Hughes Medical Institute, Harvard University, Cambridge, Massachusetts
– sequence: 3
  givenname: Xiaowei
  surname: Zhuang
  fullname: Zhuang, Xiaowei
  email: zhuang@chemistry.harvard.edu
  organization: Department of Chemistry and Chemical Biology, Department of Physics, and Howard Hughes Medical Institute, Harvard University, Cambridge, Massachusetts
BackLink https://www.ncbi.nlm.nih.gov/pubmed/22677393$$D View this record in MEDLINE/PubMed
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Snippet Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ∼10 nm but require a sparse...
Superresolution microscopy techniques based on the sequential activation of fluorophores can achieve image resolution of ~10 nm but require a sparse...
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SubjectTerms Algorithms
cell structures
Computer Simulation
Correlation analysis
Fluorescence
fluorescence microscopy
image analysis
Immunohistochemistry
Maximum likelihood method
Microscopy, Fluorescence - methods
Microtubules - metabolism
Models, Statistical
Molecules
Simulation
Spectroscopy, Imaging, and Other Techniques
statistical models
Title Statistical Deconvolution for Superresolution Fluorescence Microscopy
URI https://dx.doi.org/10.1016/j.bpj.2012.03.070
https://www.ncbi.nlm.nih.gov/pubmed/22677393
https://www.proquest.com/docview/1016007714
https://search.proquest.com/docview/1019613110
https://pubmed.ncbi.nlm.nih.gov/PMC3353000
Volume 102
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