New results on the single molecule localization problem in two and three dimensions
New results on the single molecule localization problem in two and three dimensions
Fluorescence microscopy is an optical microscopy technique which has been extensively used to study specifically- labeled subcellular objects, such as proteins, and their functions. The best possible accuracy with which an object of interest can be localized when imaged using a fluorescence microscope is typically calculated using the Cramer- Rao lower bound (CRLB). The calculation of the CRLB, however, so far relied on an analytical expression for the image of the object. This can pose challenges in practice since it is often difficult to find appropriate analytical models for the images of general objects. Even if an appropriate analytical model is available, the lack of knowledge about the precise values of imaging parameters might also impose difficulties in the calculation of the CRLB. To address these challenges, we have developed an approach that directly uses an experimentally collected image set to calculate the best possible localization accuracy for a general subcellular object in two and three dimensions. In this approach, we fit smoothly connected piecewise polynomials, known as splines, to the experimentally collected image set to provide a continuous model of the object. This continuous model can then be used for the calculation of the best possible localization accuracy.
Cramér-Rao lower bound, Fisher information matrix, single molecule microscopy, splines
Tahmasbi, Amir
5a377bd3-4578-434f-919a-87804245791e
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
2015
Tahmasbi, Amir
5a377bd3-4578-434f-919a-87804245791e
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Tahmasbi, Amir, Ward, E. Sally and Ober, Raimund J.
(2015)
New results on the single molecule localization problem in two and three dimensions.
In Nanoimaging and Nanospectroscopy III.
vol. 9554,
SPIE..
(doi:10.1117/12.2192008).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Fluorescence microscopy is an optical microscopy technique which has been extensively used to study specifically- labeled subcellular objects, such as proteins, and their functions. The best possible accuracy with which an object of interest can be localized when imaged using a fluorescence microscope is typically calculated using the Cramer- Rao lower bound (CRLB). The calculation of the CRLB, however, so far relied on an analytical expression for the image of the object. This can pose challenges in practice since it is often difficult to find appropriate analytical models for the images of general objects. Even if an appropriate analytical model is available, the lack of knowledge about the precise values of imaging parameters might also impose difficulties in the calculation of the CRLB. To address these challenges, we have developed an approach that directly uses an experimentally collected image set to calculate the best possible localization accuracy for a general subcellular object in two and three dimensions. In this approach, we fit smoothly connected piecewise polynomials, known as splines, to the experimentally collected image set to provide a continuous model of the object. This continuous model can then be used for the calculation of the best possible localization accuracy.
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e-pub ahead of print date: 26 August 2015
Published date: 2015
Venue - Dates:
Nanoimaging and Nanospectroscopy III, , San Diego, United States, 2015-08-09 - 2015-08-12
Keywords:
Cramér-Rao lower bound, Fisher information matrix, single molecule microscopy, splines
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Local EPrints ID: 423664
URI: http://eprints.soton.ac.uk/id/eprint/423664
PURE UUID: 6e0b9ae1-0b7a-4a5d-ad6a-a6ad32fc49c7
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Date deposited: 27 Sep 2018 16:30
Last modified: 16 Mar 2024 04:37
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Author:
Amir Tahmasbi
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