Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: KEGG:D02011 (FAD)
 5,530 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Autofluorescence of rabbit and human epithelial tissues were studied by using a depth-resolved fluorescence spectroscopy system with multiple excitations. Keratinization was found to be common in the squamous epithelium. Strong keratin fluorescence with excitation and emission characteristics similar to collagen were observed in the topmost layer of the keratinized squamous epithelium. The keratin signal created interference in the assessment of the endogenous fluorescence signals (NADH/FAD fluorescence in epithelium and collagen fluorescence in stroma) associated with the development of epithelial precancer. Furthermore, the keratinized epithelial layer attenuated the excitation light and reduced the fluorescence signals from underlying tissue layers. The autofluorescence of columnar epithelium was found to be dominated by NADH and FAD signals, identical to the autofluorescence measured from nonkeratinized squamous epithelium. The study also demonstrated that a fluorescence signal excited at 355 nm produced sufficient contrast to resolve the layered structure of epithelial tissue, while the signal excited at 405 nm provided the information for a good estimation of epithelial redox ratios that are directly related to tissue metabolism. Overall, the depth-resolved measurements are crucial to isolate the fluorescence signals from different sublayers of the epithelial tissue and provide more accurate information for the tissue diagnosis.
 ...
PMID:Autofluorescence spectroscopy of epithelial tissues. 1709 72

The layered-resolved microstructure and spectroscopy of mouse oral mucosa are obtained using a combination of multiphoton imaging and spectral analysis with different excitation wavelengths. In the keratinizing layer, the keratinocytes microstructure can be characterized and the keratinizing thickness can be measured. The keratin fluorescence signal can be further characterized by emission maxima at 510 nm. In the epithelium, the cellular microstructure can be quantitatively visualized with depth and the epithelium thickness can be determined by multiphoton imaging excited at 730 nm. The study also shows that the epithelial spectra excited at 810 nm, showing a combination of NADH and FAD fluorescence, can be used for the estimation of the metabolic state in epithelium. Interestingly, a second-harmonic generation (SHG) signal from DNA was observed for the first time within the epithelial layer in backscattering geometry and provides the possibility of analyzing the chromatin structure. In the stroma, the combination of multiphoton imaging and spectral analysis excited at 850 nm in tandem can obtain quantitative information regarding the biomorphology and biochemistry of stroma. Specifically, the microstructure of collagen, minor salivary glands and elastic fibers, and the optical property of the stroma can be quantitatively displayed. Overall, these results suggest that the combination of multiphoton imaging and spectral analysis with different excitation wavelengths has the potential to provide important and comprehensive information for early diagnosis of oral cancer.
 ...
PMID:The layered-resolved microstructure and spectroscopy of mouse oral mucosa using multiphoton microscopy. 1767 47

A portable confocal system with the excitations at 355nm and 457nm was instrumented to investigate the depth-resolved fluorescence of cervical tissue. The study focused on extracting biochemical and morphological information carried in the depth-resolved signals measured from the normal squamous epithelial tissue and squamous intraepithelial lesions. Strong keratin fluorescence with the spectral characteristics similar to collagen were observed from the topmost keratinizing layer of all tissue samples. It was found that 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 potentially provide more accurate diagnostic information for determining tissue pathology.
 ...
PMID:Depth-resolved fluorescence spectroscopy of normal and dysplastic cervical tissue. 1948 64

There are increased interests on using multiphoton imaging and spectroscopy for skin tissue characterization and diagnosis. However, most studies have been done with just a few excitation wavelengths. Our objective is to perform a systematic study of the two-photon fluorescence (TPF) properties of skin fluorophores, normal skin, and diseased skin tissues. A nonlinear excitation-emission-matrix (EEM) spectroscopy system with multiphoton imaging guidance was constructed. A tunable femtosecond laser was used to vary excitation wavelengths from 730 to 920 nm for EEM data acquisition. EEM measurements were performed on excised fresh normal skin tissues, seborrheic keratosis tissue samples, and skin fluorophores including: NADH, FAD, keratin, melanin, collagen, and elastin. We found that in the stratum corneum and upper epidermis of normal skin, the cells have large sizes and the TPF originates from keratin. In the lower epidermis, cells are smaller and TPF is dominated by NADH contributions. In the dermis, TPF is dominated by elastin components. The depth resolved EEM measurements also demonstrated that keratin structure has intruded into the middle sublayers of the epidermal part of the seborrheic keratosis lesion. These results suggest that the imaging guided TPF EEM spectroscopy provides useful information for the development of multiphoton clinical devices for skin disease diagnosis.
 ...
PMID:Imaging-guided two-photon excitation-emission-matrix measurements of human skin tissues. 2289 17

Skin contains many autofluorescent components that can be studied using spectral imaging. We employed a spectral phasor method to analyse two photon excited autofluorescence and second harmonic generation images of in vivo human skin. This method allows segmentation of images based on spectral features. Various structures in the skin could be distinguished, including Stratum Corneum, epidermal cells and dermis. The spectral phasor analysis allowed investigation of their fluorescence composition and identification of signals from NADH, keratin, FAD, melanin, collagen and elastin. Interestingly, two populations of epidermal cells could be distinguished with different melanin content.
 ...
PMID:Phasor analysis of multiphoton spectral images distinguishes autofluorescence components of in vivo human skin. 2357 7