3D Snapshot Microscopy of Extended Objects
Volumetric biological imaging often involves compromising high temporal resolution at the expense of high spatial resolution when popular scanning methods are used to capture 3D information. We introduce an integrated experimental and image reconstruction method for capturing dynamic 3D fluorescent...
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| creator | Huang, Xiang Selewa, Alan Wang, Xiaolei Daddysman, Matthew K Gdor, Itay Wilton, Rosemarie Kemner, Kenneth M Yoo, Seunghwan Katsaggelos, Aggelos K He, Kuan Cossairt, Oliver Ferrier, Nicola J Hereld, Mark Scherer, Norbert F |
| description | Volumetric biological imaging often involves compromising high temporal
resolution at the expense of high spatial resolution when popular scanning
methods are used to capture 3D information. We introduce an integrated
experimental and image reconstruction method for capturing dynamic 3D
fluorescent extended objects as a series of synchronously measured 3D snapshots
taken at the frame rate of the imaging camera. We employ multifocal microscopy
(MFM) to simultaneously image at 25 focal planes and process this depth-encoded
image to recover the 3D structure of extended objects, such as bacteria, using
a sparsity-based reconstruction approach. The combined experimental and
computational method produces image quality similar to confocal microscopy in a
fraction of the acquisition time. In addition, our computational image
reconstruction approach allows a simplified MFM optical design by correcting
aberrations using the measured response to point sources. This "compressive"
MFM acquisition and reconstruction method, where an image volume with roughly 8
million voxels is recovered from a single 1-megapixel captured image, enables
straightforward study of dynamic processes in 3D, and as a simultaneous
snapshot advances the state of the art in dynamic 3D microscopy. |
| doi_str_mv | 10.48550/arxiv.1802.01565 |
| format | Article |
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resolution at the expense of high spatial resolution when popular scanning
methods are used to capture 3D information. We introduce an integrated
experimental and image reconstruction method for capturing dynamic 3D
fluorescent extended objects as a series of synchronously measured 3D snapshots
taken at the frame rate of the imaging camera. We employ multifocal microscopy
(MFM) to simultaneously image at 25 focal planes and process this depth-encoded
image to recover the 3D structure of extended objects, such as bacteria, using
a sparsity-based reconstruction approach. The combined experimental and
computational method produces image quality similar to confocal microscopy in a
fraction of the acquisition time. In addition, our computational image
reconstruction approach allows a simplified MFM optical design by correcting
aberrations using the measured response to point sources. This "compressive"
MFM acquisition and reconstruction method, where an image volume with roughly 8
million voxels is recovered from a single 1-megapixel captured image, enables
straightforward study of dynamic processes in 3D, and as a simultaneous
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resolution at the expense of high spatial resolution when popular scanning
methods are used to capture 3D information. We introduce an integrated
experimental and image reconstruction method for capturing dynamic 3D
fluorescent extended objects as a series of synchronously measured 3D snapshots
taken at the frame rate of the imaging camera. We employ multifocal microscopy
(MFM) to simultaneously image at 25 focal planes and process this depth-encoded
image to recover the 3D structure of extended objects, such as bacteria, using
a sparsity-based reconstruction approach. The combined experimental and
computational method produces image quality similar to confocal microscopy in a
fraction of the acquisition time. In addition, our computational image
reconstruction approach allows a simplified MFM optical design by correcting
aberrations using the measured response to point sources. This "compressive"
MFM acquisition and reconstruction method, where an image volume with roughly 8
million voxels is recovered from a single 1-megapixel captured image, enables
straightforward study of dynamic processes in 3D, and as a simultaneous
snapshot advances the state of the art in dynamic 3D microscopy.</description><subject>Physics - Instrumentation and Detectors</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNotzr1uwjAUQGEvDBX0ATrVM1LSa8fXdsaK0h8JxFD26PraFkGURElUwdtXpZ3OdvQJ8aCgNB4Rnmi4tN-l8qBLUGjxTiyrF_l5pn48dJPctjx0I3f9VXZZri9TOscU5S4cE0_jQswyncZ0_9-52L-u96v3YrN7-1g9bwqyDouQGZULHLNytScdUlLAtSYD7KM36NkpzCYiAUVQtXEh6GTRWrYauJqLx7_tDdv0Q_tFw7X5RTc3dPUDPBg7YA</recordid><startdate>20180205</startdate><enddate>20180205</enddate><creator>Huang, Xiang</creator><creator>Selewa, Alan</creator><creator>Wang, Xiaolei</creator><creator>Daddysman, Matthew K</creator><creator>Gdor, Itay</creator><creator>Wilton, Rosemarie</creator><creator>Kemner, Kenneth M</creator><creator>Yoo, Seunghwan</creator><creator>Katsaggelos, Aggelos K</creator><creator>He, Kuan</creator><creator>Cossairt, Oliver</creator><creator>Ferrier, Nicola J</creator><creator>Hereld, Mark</creator><creator>Scherer, Norbert F</creator><scope>GOX</scope></search><sort><creationdate>20180205</creationdate><title>3D Snapshot Microscopy of Extended Objects</title><author>Huang, Xiang ; Selewa, Alan ; Wang, Xiaolei ; Daddysman, Matthew K ; Gdor, Itay ; Wilton, Rosemarie ; Kemner, Kenneth M ; Yoo, Seunghwan ; Katsaggelos, Aggelos K ; He, Kuan ; Cossairt, Oliver ; Ferrier, Nicola J ; Hereld, Mark ; Scherer, Norbert F</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a675-bfc517bcdf1798a2bee10c92a40c8d8458c715f4d5a0ad01947bb2e6566c620c3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Physics - Instrumentation and Detectors</topic><toplevel>online_resources</toplevel><creatorcontrib>Huang, Xiang</creatorcontrib><creatorcontrib>Selewa, Alan</creatorcontrib><creatorcontrib>Wang, Xiaolei</creatorcontrib><creatorcontrib>Daddysman, Matthew K</creatorcontrib><creatorcontrib>Gdor, Itay</creatorcontrib><creatorcontrib>Wilton, Rosemarie</creatorcontrib><creatorcontrib>Kemner, Kenneth M</creatorcontrib><creatorcontrib>Yoo, Seunghwan</creatorcontrib><creatorcontrib>Katsaggelos, Aggelos K</creatorcontrib><creatorcontrib>He, Kuan</creatorcontrib><creatorcontrib>Cossairt, Oliver</creatorcontrib><creatorcontrib>Ferrier, Nicola J</creatorcontrib><creatorcontrib>Hereld, Mark</creatorcontrib><creatorcontrib>Scherer, Norbert F</creatorcontrib><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Huang, Xiang</au><au>Selewa, Alan</au><au>Wang, Xiaolei</au><au>Daddysman, Matthew K</au><au>Gdor, Itay</au><au>Wilton, Rosemarie</au><au>Kemner, Kenneth M</au><au>Yoo, Seunghwan</au><au>Katsaggelos, Aggelos K</au><au>He, Kuan</au><au>Cossairt, Oliver</au><au>Ferrier, Nicola J</au><au>Hereld, Mark</au><au>Scherer, Norbert F</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>3D Snapshot Microscopy of Extended Objects</atitle><date>2018-02-05</date><risdate>2018</risdate><abstract>Volumetric biological imaging often involves compromising high temporal
resolution at the expense of high spatial resolution when popular scanning
methods are used to capture 3D information. We introduce an integrated
experimental and image reconstruction method for capturing dynamic 3D
fluorescent extended objects as a series of synchronously measured 3D snapshots
taken at the frame rate of the imaging camera. We employ multifocal microscopy
(MFM) to simultaneously image at 25 focal planes and process this depth-encoded
image to recover the 3D structure of extended objects, such as bacteria, using
a sparsity-based reconstruction approach. The combined experimental and
computational method produces image quality similar to confocal microscopy in a
fraction of the acquisition time. In addition, our computational image
reconstruction approach allows a simplified MFM optical design by correcting
aberrations using the measured response to point sources. This "compressive"
MFM acquisition and reconstruction method, where an image volume with roughly 8
million voxels is recovered from a single 1-megapixel captured image, enables
straightforward study of dynamic processes in 3D, and as a simultaneous
snapshot advances the state of the art in dynamic 3D microscopy.</abstract><doi>10.48550/arxiv.1802.01565</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Instrumentation and Detectors |
| title | 3D Snapshot Microscopy of Extended Objects |
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