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Three-dimensional single molecule tracking of quantum-dot labeled antibody molecules using multifocal plane microscopy

Three-dimensional single molecule tracking of quantum-dot labeled antibody molecules using multifocal plane microscopy
Three-dimensional single molecule tracking of quantum-dot labeled antibody molecules using multifocal plane microscopy

Single molecule tracking in three dimensions (3D) in a live cell environment promises to reveal important new insights into cell biological mechanisms. However, classical microscopy techniques suffer from poor depth discrimination which severely limits single molecule tracking in 3D with high temporal and spatial resolution. We introduced a novel imaging modality, multifocal plane microscopy (MUM) for the study of subcellular dynamics in 3D. We have shown that MUM provides a powerful approach with which single molecules can be tracked in 3D in live cells. MUM allows for the simultaneous imaging at different focal planes, thereby ensuring that trajectories can be imaged continuously at high temporal resolution. A critical requirement for 3D single molecule tracking as well as localization based 3D super-resolution imaging is high 3D localization accuracy. MUM overcomes the depth discrimination problem of classical microscopy based approaches and supports high accuracy 3D localization of singe molecule/particles. In this way, MUM opens the way for high precision 3D single molecule tracking and 3D super-resolution imaging within a live cell environment. We have used MUM to reveal complex intracellular pathways that could not be imaged with classical approaches. In particular we have tracked quantum dot labeled antibody molecules in the exo/endocytic pathway from the cell interior to the plasma membrane at the single molecule level. Here, we present a brief review of these results.

3D super-resolution microscopy, Fisher information matrix, Localization accuracy, Multifocal plane microscopy, Single molecule tracking
SPIE
Ram, Sripad
559bd560-3817-4e53-8c7a-2f08e4518412
Prabhat, Prashant
e79cffdb-4de8-42cc-b0f7-6d28f6d3c82e
Chao, Jerry
550e20b0-8365-42e3-a6fc-1048eb8c2e47
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36
Ram, Sripad
559bd560-3817-4e53-8c7a-2f08e4518412
Prabhat, Prashant
e79cffdb-4de8-42cc-b0f7-6d28f6d3c82e
Chao, Jerry
550e20b0-8365-42e3-a6fc-1048eb8c2e47
Ward, E. Sally
b31c0877-8abe-485f-b800-244a9d3cd6cc
Ober, Raimund J.
31f4d47f-fb49-44f5-8ff6-87fc4aff3d36

Ram, Sripad, Prabhat, Prashant, Chao, Jerry, Ward, E. Sally and Ober, Raimund J. (2010) Three-dimensional single molecule tracking of quantum-dot labeled antibody molecules using multifocal plane microscopy. In Colloidal Quantum Dots for Biomedical Applications V. vol. 7575, SPIE.. (doi:10.1117/12.848940).

Record type: Conference or Workshop Item (Paper)

Abstract

Single molecule tracking in three dimensions (3D) in a live cell environment promises to reveal important new insights into cell biological mechanisms. However, classical microscopy techniques suffer from poor depth discrimination which severely limits single molecule tracking in 3D with high temporal and spatial resolution. We introduced a novel imaging modality, multifocal plane microscopy (MUM) for the study of subcellular dynamics in 3D. We have shown that MUM provides a powerful approach with which single molecules can be tracked in 3D in live cells. MUM allows for the simultaneous imaging at different focal planes, thereby ensuring that trajectories can be imaged continuously at high temporal resolution. A critical requirement for 3D single molecule tracking as well as localization based 3D super-resolution imaging is high 3D localization accuracy. MUM overcomes the depth discrimination problem of classical microscopy based approaches and supports high accuracy 3D localization of singe molecule/particles. In this way, MUM opens the way for high precision 3D single molecule tracking and 3D super-resolution imaging within a live cell environment. We have used MUM to reveal complex intracellular pathways that could not be imaged with classical approaches. In particular we have tracked quantum dot labeled antibody molecules in the exo/endocytic pathway from the cell interior to the plasma membrane at the single molecule level. Here, we present a brief review of these results.

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More information

Published date: 2010
Venue - Dates: Colloidal Quantum Dots for Biomedical Applications V, , San Francisco, CA, United States, 2010-01-23 - 2010-01-25
Keywords: 3D super-resolution microscopy, Fisher information matrix, Localization accuracy, Multifocal plane microscopy, Single molecule tracking

Identifiers

Local EPrints ID: 423620
URI: http://eprints.soton.ac.uk/id/eprint/423620
DOI: doi:10.1117/12.848940
PURE UUID: 122afdb5-d728-4338-a3b6-30a77632ed82
ORCID for E. Sally Ward: ORCID iD orcid.org/0000-0003-3232-7238
ORCID for Raimund J. Ober: ORCID iD orcid.org/0000-0002-1290-7430

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Date deposited: 27 Sep 2018 16:30
Last modified: 16 Mar 2024 04:37

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Contributors

Author: Sripad Ram
Author: Prashant Prabhat
Author: Jerry Chao
Author: E. Sally Ward ORCID iD
Author: Raimund J. Ober ORCID iD

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