TY - JOUR
T1 - Fourier transform multipixel spectroscopy for quantitative cytology
AU - Malik, Z.
AU - Cabib, D.
AU - Buckwald, R. A.
AU - Talmi, A.
AU - Garini, Y.
AU - Lipson, S. G.
PY - 1996
Y1 - 1996
N2 - A Fourier transform multipixel spectroscopy system was set up and applied to fluorescence microscopy of single living cells, Continuous fluorescence spectra for all pixels of the cell image were recorded simultaneously by the system. Multiple frames of data were first acquired and stored as a set of interferograms for each pixel of the image; they were then Fourier transformed and used as a spatially organized set of fluorescence spectra. Practical spectral resolution of 5 nm was achieved, typically, for 104 pixels in a single cell. The net: result was I(χ,γ,λ), the fluorescence intensity (I) for each pixel of the image (χ,γ), as function of wavelength (λ). The present study demonstrates that multipixel spectroscopy can reveal dynamic processes of the food-digestive cycle in the unicellular Paramecium vulgaris fed with algae. Spectral variability of fluorescence intensity at different cytoplasmic sites pinpointed the location of cellular deposits of chlorophyll (630 nm) and of pheophytin (695 nm), a digestive product of the chlorophyll. Localization of compartmental spectral changes was achieved using a 'similarity mapping' algorithm, followed by enhanced image construction. Similarity mapping based on the fluorescence spectrum of native chlorophyll revealed a highlighted image of the cell cytopharynx structure where algae were ingested. Phagolysosomes, migrating vacuoles and the cytoproct, each containing different ratios of pheophytin, were similarly imaged.
AB - A Fourier transform multipixel spectroscopy system was set up and applied to fluorescence microscopy of single living cells, Continuous fluorescence spectra for all pixels of the cell image were recorded simultaneously by the system. Multiple frames of data were first acquired and stored as a set of interferograms for each pixel of the image; they were then Fourier transformed and used as a spatially organized set of fluorescence spectra. Practical spectral resolution of 5 nm was achieved, typically, for 104 pixels in a single cell. The net: result was I(χ,γ,λ), the fluorescence intensity (I) for each pixel of the image (χ,γ), as function of wavelength (λ). The present study demonstrates that multipixel spectroscopy can reveal dynamic processes of the food-digestive cycle in the unicellular Paramecium vulgaris fed with algae. Spectral variability of fluorescence intensity at different cytoplasmic sites pinpointed the location of cellular deposits of chlorophyll (630 nm) and of pheophytin (695 nm), a digestive product of the chlorophyll. Localization of compartmental spectral changes was achieved using a 'similarity mapping' algorithm, followed by enhanced image construction. Similarity mapping based on the fluorescence spectrum of native chlorophyll revealed a highlighted image of the cell cytopharynx structure where algae were ingested. Phagolysosomes, migrating vacuoles and the cytoproct, each containing different ratios of pheophytin, were similarly imaged.
KW - Fourier transform imaging spectroscopy
KW - Image reconstruction
KW - Multipixel fluorescence spectroscopy
KW - Paramecium
KW - Spectral imaging
KW - Spectral imaging of living cells
KW - Spectral mapping
UR - http://www.scopus.com/inward/record.url?scp=0029971936&partnerID=8YFLogxK
U2 - 10.1046/j.1365-2818.1996.131411.x
DO - 10.1046/j.1365-2818.1996.131411.x
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AN - SCOPUS:0029971936
SN - 0022-2720
VL - 182
SP - 133
EP - 140
JO - Journal of Microscopy
JF - Journal of Microscopy
IS - 2
ER -