Liquid Crystal Tunable Filter Raman Chemical Imaging

Morris, Hannah R.; Hoyt, Clifford; Miller, Peter J.; Treado, Patrick J.

doi:10.1366/0003702963905655

Cited by 122 publications

(69 citation statements)

References 17 publications

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“…Spatial resolution available with Raman microscopy is dependent on the wavelength of the excitation light and in theory is the same as other optical microscopies, such as luorescence (e.g., ∼250 nm lateral and ∼500 nm axial, for blue/green excitation). The addition of spatial resolution can be accomplished in several diferent ways: confocal point-scanning Raman microscopy [12,13], wide-ield Raman imaging [14], or Raman line scanning [15,16]. The relative advantages and disadvantages of each of these approaches have been reviewed elsewhere and will not be covered here [17].…”

Section: Introductionmentioning

confidence: 99%

Localizing and Quantifying Carotenoids in Intact Cells and Tissues

Timlin¹,

Collins²,

Beechem³

et al. 2017

Carotenoids

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Raman spectroscopy provides detailed information about the molecular structure of carotenoids. Advances in detector sensitivity and acquisition speed have driven the expansion of Raman spectroscopy from a bulk analytical tool to a powerful method for mapping carotenoid abundance in cells and tissues. In many applications, the technique is compatible with living organisms, providing highly speciic molecular structure information in intact cells and tissues with subcellular spatial resolution. This leads to spatial-temporalchemical resolution critical to understanding the complex processes in the life cycle of carotenoids and other biomolecules.

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Section: Introductionmentioning

confidence: 99%

Localizing and Quantifying Carotenoids in Intact Cells and Tissues

Timlin¹,

Collins²,

Beechem³

et al. 2017

Carotenoids

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“…Though Raman spectral signatures are much weaker than fluorescence emission spectra, it is possible to perform Raman spectral imaging at the single cell level with modern detection technologies. Hyperspectral Raman microscopy can be implemented in a variety of formats similar to those described for hyperspectral fluorescence microscopy (Christensen & Morris, 1998;Govil, et al, 1993;Morris, et al, 1996), however the most commonly utilized for visualizing endocytosis in living cells has been the confocal pointscanning method, due to its availability, high sensitivity, optical sectioning capability, and speed.…”

Section: Applications Of Raman Spectral Imaging In Endocytosismentioning

confidence: 99%

Advanced Optical Imaging of Endocytosis

Aaron¹,

Timlin²

2012

Molecular Regulation of Endocytosis

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“…The filter is based on the Lyot birefringent interferometer and provided continuous, random access wavelength selection from 400 to 720 nm with a stated wavelength-dependent bandwidth of 0.125 times the central wavelength (Morris et al 1994(Morris et al ,1996. Images collected over this wavelength range were free of distortion and wavelength-dependent translations or shifts.…”

Section: Imaging System and Proceduresmentioning

confidence: 99%

Analysis of Stained Objects in Histological Sections by Spectral Imaging and Differential Absorption

Ornberg

Woerner

Edwards

1999

J Histochem Cytochem.

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SUMMARYWe describe a new light microscopic imaging system and method to perform high through put color image analysis on histological tissue sections. The system features a computer-controlled, random-access liquid crystal tunable filter and high-resolution digital camera on a conventional brightfield microscope. For any combination of stains, the method determines the spectral transmittance of each stain on the slide and selects two or more wavelengths at which the differential absorption between stain and counterstain is greatest and the exposure time is reasonably short. Flatfield corrected digital images at these wavelengths are acquired and divided to produce a gray scale ratio image. The ratio image is calculated such that the stained features of interest are highlighted above a uniform background and the counterstained features are highlighted below background. Image threshold procedures using either visual inspection or a threshold value determined by the image mean intensity and standard deviation are used to segment the stained features of interest for subsequent morphometry. Results are presented for peroxidase-AEC-labeled tumor tissue and trichrome-stained biomaterial implant tissues. In principle, the method should work for any combination of colored stains. (J Histochem Cytochem 47:1307-1313, 1999)

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Liquid Crystal Tunable Filter Raman Chemical Imaging

Cited by 122 publications

References 17 publications

Localizing and Quantifying Carotenoids in Intact Cells and Tissues

Localizing and Quantifying Carotenoids in Intact Cells and Tissues

Advanced Optical Imaging of Endocytosis

Analysis of Stained Objects in Histological Sections by Spectral Imaging and Differential Absorption

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