Breaking resolution limits: Advances and challenges in single molecule microscopy
Breaking resolution limits: Advances and challenges in single molecule microscopy
The resolution of an optical system is a measure of its ability to distinguish two closely spaced point sources. In optical microscopy, Rayleigh's criterion has been extensively used to determine the resolution of microscopes. Despite its widespread use, it is well known that this criterion is based on heuristic notions that are not suited to modern imaging approaches. Formulated within a deterministic framework, this criterion neglects the stochastic nature of photon emission and therefore does not take into account the total number of detected photons. In fact, recent single molecule experi-ments have shown that this criterion can be surpassed in a regular optical microscope thereby illustrating that Rayleigh's criterion is inadequate for current microscopy techniques. This inadequacy of Rayleigh's criterion has, in turn, necessitated a reassessment of the resolution limits of optical microscopes. By adopting an information-theoretic framework and using the theory concerning the Fisher information matrix, we recently proposed a new resolution measure that overcomes the limitations of Rayleigh's criterion. Here, we provide a review of this and other related results. The new resolution measure predicts that distances well below Rayleigh's limit can be resolved in an optical microscope. The effect of deteriorating experimental factors on the new resolution measure is also investigated. Further, it is experimentally verified that distances well below Rayleigh's limit can be measured from images of closely spaced fluorescent single molecules with an accuracy as predicted by the new resolution measure. We have also addressed an important problem in single molecule microscopy that concerns the accuracy with which the location of a single molecule can be determined. In particular, by using the theory concerning the Fisher information matrix we have derived analytical expressions for the limit to the 2D/3D localization accuracy of a single molecule.
1284-1287
Ram, Sripad
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Chao, Jerry
550e20b0-8365-42e3-a6fc-1048eb8c2e47
Prabhat, Prashant
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Abraham, Anish V.
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Ward, E. Sally
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Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
2007
Ram, Sripad
559bd560-3817-4e53-8c7a-2f08e4518412
Chao, Jerry
550e20b0-8365-42e3-a6fc-1048eb8c2e47
Prabhat, Prashant
e79cffdb-4de8-42cc-b0f7-6d28f6d3c82e
Abraham, Anish V.
4f71ee5b-b0b1-4e0e-8f64-5cea9ae8f0e0
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Ram, Sripad, Chao, Jerry, Prabhat, Prashant, Abraham, Anish V., Ward, E. Sally and Ober, Raimund J.
(2007)
Breaking resolution limits: Advances and challenges in single molecule microscopy.
In Conference Record of the 41st Asilomar Conference on Signals, Systems and Computers, ACSSC.
IEEE.
.
(doi:10.1109/ACSSC.2007.4487433).
Record type:
Conference or Workshop Item
(Paper)
Abstract
The resolution of an optical system is a measure of its ability to distinguish two closely spaced point sources. In optical microscopy, Rayleigh's criterion has been extensively used to determine the resolution of microscopes. Despite its widespread use, it is well known that this criterion is based on heuristic notions that are not suited to modern imaging approaches. Formulated within a deterministic framework, this criterion neglects the stochastic nature of photon emission and therefore does not take into account the total number of detected photons. In fact, recent single molecule experi-ments have shown that this criterion can be surpassed in a regular optical microscope thereby illustrating that Rayleigh's criterion is inadequate for current microscopy techniques. This inadequacy of Rayleigh's criterion has, in turn, necessitated a reassessment of the resolution limits of optical microscopes. By adopting an information-theoretic framework and using the theory concerning the Fisher information matrix, we recently proposed a new resolution measure that overcomes the limitations of Rayleigh's criterion. Here, we provide a review of this and other related results. The new resolution measure predicts that distances well below Rayleigh's limit can be resolved in an optical microscope. The effect of deteriorating experimental factors on the new resolution measure is also investigated. Further, it is experimentally verified that distances well below Rayleigh's limit can be measured from images of closely spaced fluorescent single molecules with an accuracy as predicted by the new resolution measure. We have also addressed an important problem in single molecule microscopy that concerns the accuracy with which the location of a single molecule can be determined. In particular, by using the theory concerning the Fisher information matrix we have derived analytical expressions for the limit to the 2D/3D localization accuracy of a single molecule.
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Published date: 2007
Venue - Dates:
41st Asilomar Conference on Signals, Systems and Computers, ACSSC, , Pacific Grove, CA, United States, 2007-11-04 - 2007-11-07
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Local EPrints ID: 423587
URI: http://eprints.soton.ac.uk/id/eprint/423587
PURE UUID: de717afe-081a-4fa5-8307-52b47d253698
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Date deposited: 27 Sep 2018 16:30
Last modified: 06 Jun 2024 02:04
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Author:
Sripad Ram
Author:
Jerry Chao
Author:
Prashant Prabhat
Author:
Anish V. Abraham
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