Your search keyword '"Redox ratio"' showing total 7 results

1. Selecting optimal spectral bands for improved detection of autofluorescent biomarkers in multiphoton microscopy

Author

Meyer, Björn-Ole, Stella, M. Pilar, Holst, Bjørn, Nielsen, Boye S., Holmstrøm, Kim, Andersen, Peter, Marti, Dominik, Meyer, Björn-Ole, Stella, M. Pilar, Holst, Bjørn, Nielsen, Boye S., Holmstrøm, Kim, Andersen, Peter, and Marti, Dominik

Abstract

SIGNIFICANCE: In multiphoton microscopy, two-photon excited fluorescence (TPEF) spectra carry valuable information on morphological and functional biological features. For measuring these biomarkers, separation of different parts of the fluorescence spectrum into channels is typically achieved by the use of optical band pass filters. However, spectra from different biomarkers can be unknown or overlapping, creating a crosstalk in between the channels. Previously, establishing these channels relied on prior knowledge or heuristic testing. AIM: The presented method aims to provide spectral bands with optimal separation between groups of specimens expressing different biomarkers. APPROACH: We have developed a system capable of resolving TPEF with high spectral resolution for the characterization of biomarkers. In addition, an algorithm is created to simulate and optimize optical band pass filters for fluorescence detection channels. To demonstrate the potential improvements in cell and tissue classification using these optimized channels, we recorded spectrally resolved images of cancerous (HT29) and normal epithelial colon cells (FHC), cultivated in 2D layers and in 3D to form spheroids. To provide an example of an application, we relate the results with the widely used redox ratio. RESULTS: We show that in the case of two detection channels, our system and algorithm enable the selection of optimized band pass filters without the need of knowing involved fluorophores. An improvement of 31,5% in separating different 2D cell cultures is achieved, compared to using established spectral bands that assume NAD(P)H and FAD as main contributors of autofluorescence. The compromise is a reduced SNR in the images. CONCLUSIONS: We show that the presented method has the ability to improve imaging contrast and can be used to tailor a given label-free optical imaging system using optical band pass filters targeting a specific biomarker or application.

Published

2020

2. Depth-resolved fluorescence of human ectocervical tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a portable confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of all ectocervical tissue samples, strong keratin fluorescence with the spectral characteristics similar to collagen was observed, which created serious interference in seeking the correlation between tissue fluorescence and tissue pathology. While from the underlying non-keratinizing epithelial layer, the measured NADH fluorescence induced by 355nm excitation and FAD fluorescence induced by 457nm excitation were strongly correlated to the tissue pathology. The ratios between NADH over FAD fluorescence increased statistically in the CIN epithelial relative to the normal and HPV epithelia, which indicated increased metabolic activity in precancerous tissue. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005

3. Depth-resolved fluorescence of biological tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of rabbit oral tissue, normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of oral and ectocervical tissue, strong keratin fluorescence with the spectral characteristics similar to collagen was observed. The fluorescence signal from epithelial tissue between the keratinizing layer and stroma can be well resolved. Furthermore, NADH and FAD fluorescence measured from the underlying non-keratinizing epithelial layer were strongly correlated to the tissue pathology. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005

4. Depth-resolved fluorescence of human ectocervical tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a portable confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of all ectocervical tissue samples, strong keratin fluorescence with the spectral characteristics similar to collagen was observed, which created serious interference in seeking the correlation between tissue fluorescence and tissue pathology. While from the underlying non-keratinizing epithelial layer, the measured NADH fluorescence induced by 355nm excitation and FAD fluorescence induced by 457nm excitation were strongly correlated to the tissue pathology. The ratios between NADH over FAD fluorescence increased statistically in the CIN epithelial relative to the normal and HPV epithelia, which indicated increased metabolic activity in precancerous tissue. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005

5. Depth-resolved fluorescence of biological tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of rabbit oral tissue, normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of oral and ectocervical tissue, strong keratin fluorescence with the spectral characteristics similar to collagen was observed. The fluorescence signal from epithelial tissue between the keratinizing layer and stroma can be well resolved. Furthermore, NADH and FAD fluorescence measured from the underlying non-keratinizing epithelial layer were strongly correlated to the tissue pathology. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005

6. Depth-resolved fluorescence of biological tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of rabbit oral tissue, normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of oral and ectocervical tissue, strong keratin fluorescence with the spectral characteristics similar to collagen was observed. The fluorescence signal from epithelial tissue between the keratinizing layer and stroma can be well resolved. Furthermore, NADH and FAD fluorescence measured from the underlying non-keratinizing epithelial layer were strongly correlated to the tissue pathology. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005

7. Depth-resolved fluorescence of human ectocervical tissue

Author

Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., Qu, J.Y., Wu, Y., Xi, P., Cheung, T.H., Yim, S.F., Yu, M.Y., and Qu, J.Y.

Abstract

The depth-resolved autofluorescence of normal and dysplastic human ectocervical tissue within 120um depth were investigated utilizing a portable confocal fluorescence spectroscopy with the excitations at 355nm and 457nm. From the topmost keratinizing layer of all ectocervical tissue samples, strong keratin fluorescence with the spectral characteristics similar to collagen was observed, which created serious interference in seeking the correlation between tissue fluorescence and tissue pathology. While from the underlying non-keratinizing epithelial layer, the measured NADH fluorescence induced by 355nm excitation and FAD fluorescence induced by 457nm excitation were strongly correlated to the tissue pathology. The ratios between NADH over FAD fluorescence increased statistically in the CIN epithelial relative to the normal and HPV epithelia, which indicated increased metabolic activity in precancerous tissue. This study demonstrates that the depth-resolved fluorescence spectroscopy can reveal fine structural information on epithelial tissue and potentially provide more accurate diagnostic information for determining tissue pathology.

Published

2005