Beyond Rayleigh's criterion: A resolution measure with application to single-molecule microscopy
Beyond Rayleigh's criterion: A resolution measure with application to single-molecule microscopy
Rayleigh's criterion is extensively used in optical microscopy for determining the resolution of microscopes. This criterion imposes a resolution limit that has long been held as an impediment for studying nanoscale biological phenomenon through an optical microscope. However, it is well known that Rayleigh's criterion is based on intuitive notions. For example, Rayleigh's criterion is formulated in a deterministic setting that neglects the photon statistics of the acquired data. Hence it does not take into account the number of detected photons, which, in turn, raises concern over the use of Rayleigh's criterion in photon-counting techniques such as single-molecule microscopy. Here, we re-examine the resolution problem by adopting a stochastic framework and present a resolution measure that overcomes the limitations of Rayleigh's criterion. This resolution measure predicts that the resolution of optical microscopes is not limited and that it can be improved by increasing the number of detected photons. Experimental verification of the resolution measure is carried out by imaging single-molecule pairs with different distances of separation. The resolution measure provides a quantitative tool for designing and evaluating single-molecule experiments that probe biomolecular interactions.
Cramer-Rao lower bound, Fisher information matrix, Fluorescence microscopy, Photon statistics
4457-4462
Ram, Sripad
559bd560-3817-4e53-8c7a-2f08e4518412
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
21 March 2006
Ram, Sripad
559bd560-3817-4e53-8c7a-2f08e4518412
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Ram, Sripad, Ward, E. Sally and Ober, Raimund J.
(2006)
Beyond Rayleigh's criterion: A resolution measure with application to single-molecule microscopy.
Proceedings of the National Academy of Sciences of the United States of America, 103 (12), .
(doi:10.1073/pnas.0508047103).
Abstract
Rayleigh's criterion is extensively used in optical microscopy for determining the resolution of microscopes. This criterion imposes a resolution limit that has long been held as an impediment for studying nanoscale biological phenomenon through an optical microscope. However, it is well known that Rayleigh's criterion is based on intuitive notions. For example, Rayleigh's criterion is formulated in a deterministic setting that neglects the photon statistics of the acquired data. Hence it does not take into account the number of detected photons, which, in turn, raises concern over the use of Rayleigh's criterion in photon-counting techniques such as single-molecule microscopy. Here, we re-examine the resolution problem by adopting a stochastic framework and present a resolution measure that overcomes the limitations of Rayleigh's criterion. This resolution measure predicts that the resolution of optical microscopes is not limited and that it can be improved by increasing the number of detected photons. Experimental verification of the resolution measure is carried out by imaging single-molecule pairs with different distances of separation. The resolution measure provides a quantitative tool for designing and evaluating single-molecule experiments that probe biomolecular interactions.
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e-pub ahead of print date: 1 March 2006
Published date: 21 March 2006
Keywords:
Cramer-Rao lower bound, Fisher information matrix, Fluorescence microscopy, Photon statistics
Identifiers
Local EPrints ID: 423584
URI: http://eprints.soton.ac.uk/id/eprint/423584
ISSN: 0027-8424
PURE UUID: e133ef3f-8df2-414e-b83e-f60e52c38911
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Date deposited: 27 Sep 2018 16:30
Last modified: 16 Mar 2024 04:37
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Author:
Sripad Ram
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