Proceedings Paper
Hyperspectral imaging fluorescence excitation scanning (HIFEX) microscopy for live cell imaging| Format | Member Price | Non-Member Price |
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Paper Abstract
In the past two decades, spectral imaging technologies have expanded the capacity of fluorescence microscopy for accurate detection of multiple labels, separation of labels from cellular and tissue autofluorescence, and analysis of autofluorescence signatures. These technologies have been implemented using a range of optical techniques, such as tunable filters, diffraction gratings, prisms, interferometry, and custom Bayer filters. Each of these techniques has associated strengths and weaknesses with regard to spectral resolution, spatial resolution, temporal resolution, and signal-to-noise characteristics. We have previously shown that spectral scanning of the fluorescence excitation spectrum can provide greatly increased signal strength compared to traditional emission-scanning approaches. Here, we present results from utilizing a Hyperspectral Imaging Fluorescence Excitation Scanning (HIFEX) microscope system for live cell imaging. Live cell signaling studies were performed using HEK 293 and rat pulmonary microvascular endothelial cells (PMVECs), transfected with either a cAMP FRET reporter or a Ca2+ reporter. Cells were further labeled to visualize subcellular structures (nuclei, membrane, mitochondria, etc.). Spectral images were acquired using a custom inverted microscope (TE2000, Nikon Instruments) equipped with a 300W Xe arc lamp and tunable excitation filter (VF- 5, Sutter Instrument Co., equipped with VersaChrome filters, Semrock), and run through MicroManager. Timelapse spectral images were acquired from 350-550 nm, in 5 nm increments. Spectral image data were linearly unmixed using custom MATLAB scripts. Results indicate that the HIFEX microscope system can acquire live cell image data at acquisition speeds of 8 ms/wavelength band with minimal photobleaching, sufficient for studying moderate speed cAMP and Ca2+ events.
Paper Details
Date Published: 21 February 2019
PDF: 7 pages
Proc. SPIE 10883, Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XXVI, 108831A (21 February 2019); doi: 10.1117/12.2510562
Published in SPIE Proceedings Vol. 10883:
Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XXVI
Thomas G. Brown; Tony Wilson, Editor(s)
PDF: 7 pages
Proc. SPIE 10883, Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XXVI, 108831A (21 February 2019); doi: 10.1117/12.2510562
Show Author Affiliations
Silas J. Leavesley, Univ. of South Alabama (United States)
John Robert Griswold, Univ. of South Alabama (United States)
Joshua Deal, Univ. of South Alabama (United States)
Kathleen McAlister, Univ. of South Alabama (United States)
Sam Mayes, Univ. of South Alabama (United States)
John Robert Griswold, Univ. of South Alabama (United States)
Joshua Deal, Univ. of South Alabama (United States)
Kathleen McAlister, Univ. of South Alabama (United States)
Sam Mayes, Univ. of South Alabama (United States)
Craig Browning, Univ. of South Alabama (United States)
Marina Parker, Univ. of South Alabama (United States)
Samantha Gunn Mayes, Univ. of South Alabama (United States)
Thomas C. Rich, Univ. of South Alabama (United States)
Marina Parker, Univ. of South Alabama (United States)
Samantha Gunn Mayes, Univ. of South Alabama (United States)
Thomas C. Rich, Univ. of South Alabama (United States)
Published in SPIE Proceedings Vol. 10883:
Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XXVI
Thomas G. Brown; Tony Wilson, Editor(s)
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