TY - JOUR
T1 - Hyperspectral confocal fluorescence imaging
T2 - Exploring alternative multivariate curve resolution approaches
AU - Haaland, David M.
AU - Jones, Howland D.T.
AU - Van Benthem, Mark H.
AU - Sinclair, Michael B.
AU - Melgaard, David K.
AU - Stork, Christopher L.
AU - Pedroso, Maria C.
AU - Liu, Ping
AU - Brasier, Allan R.
AU - Andrews, Nicholas L.
AU - Lidke, Diane S.
PY - 2009/3
Y1 - 2009/3
N2 - Hyperspectral confocal fluorescence microscopy, when combined with multivariate curve resolution (MCR), provides a powerful new tool for improved quantitative imaging of multi-fluorophore samples. Generally, fully non-negatively constrained models are used in the constrained alternating least squares MCR analyses of hyperspectral images since real emission components are expected to have non-negative pure emission spectra and concentrations. However, in this paper, we demonstrate four separate cases in which partially constrained models are preferred over the fully constrained MCR models. These partially constrained MCR models can sometimes be preferred when system artifacts are present in the data or where small perturbations of the major emission components are present due to environmental effects or small geometric changes in the fluorescing species. Here we demonstrate that in the cases of hyperspectral images obtained from multicomponent spherical beads, autofluorescence from fixed lung epithelial cells, fluorescence of quantum dots in aqueous solutions, and images of mercurochrome-stained endosperm portions of a wild-type corn seed, these alternative, partially constrained MCR analyses provide improved interpretability of the MCR solutions. Often the system artifacts or environmental effects are more readily described as first and/or second derivatives of the main emission components in these alternative MCR solutions since they indicate spectral shifts and/or spectral broadening or narrowing of the emission bands, respectively. Thus, this paper serves to demonstrate the need to test alternative partially constrained models when analyzing hyperspectral images with MCR methods.
AB - Hyperspectral confocal fluorescence microscopy, when combined with multivariate curve resolution (MCR), provides a powerful new tool for improved quantitative imaging of multi-fluorophore samples. Generally, fully non-negatively constrained models are used in the constrained alternating least squares MCR analyses of hyperspectral images since real emission components are expected to have non-negative pure emission spectra and concentrations. However, in this paper, we demonstrate four separate cases in which partially constrained models are preferred over the fully constrained MCR models. These partially constrained MCR models can sometimes be preferred when system artifacts are present in the data or where small perturbations of the major emission components are present due to environmental effects or small geometric changes in the fluorescing species. Here we demonstrate that in the cases of hyperspectral images obtained from multicomponent spherical beads, autofluorescence from fixed lung epithelial cells, fluorescence of quantum dots in aqueous solutions, and images of mercurochrome-stained endosperm portions of a wild-type corn seed, these alternative, partially constrained MCR analyses provide improved interpretability of the MCR solutions. Often the system artifacts or environmental effects are more readily described as first and/or second derivatives of the main emission components in these alternative MCR solutions since they indicate spectral shifts and/or spectral broadening or narrowing of the emission bands, respectively. Thus, this paper serves to demonstrate the need to test alternative partially constrained models when analyzing hyperspectral images with MCR methods.
KW - ALS
KW - Autofluorescence
KW - Corn endosperm
KW - Fluorescence imaging
KW - Hyperspectral confocal microscope
KW - MCR
KW - Multivariate curve resolution
KW - Partially constrained alternating least squares
KW - Quantum dots
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U2 - 10.1366/000370209787598843
DO - 10.1366/000370209787598843
M3 - Article
C2 - 19281642
AN - SCOPUS:62849125632
SN - 0003-7028
VL - 63
SP - 271
EP - 279
JO - Applied Spectroscopy
JF - Applied Spectroscopy
IS - 3
ER -