Towards metabolic mapping of the human retina

Schweitzer, Dietrich; Schenke, S.; Hammer, Martin; Schweitzer, Frank; Jentsch, Susanne; Birckner, Eckhard; Becker, Wolfgang; Bergmann, Axel

doi:10.1002/jemt.20427

Cited by 200 publications

(255 citation statements)

References 38 publications

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“…5(c)), partly because free NADH has lower fluorescence quantum yield (0.02) as compared to bound NADH (0.1) [39,40]. This is consistent with earlier reports that more than 80% of total NADH fluorescence is due to bound NADH [41,42]. Figure 5(b) shows the variations of mean cellular fluorescence intensity of free NAD(P)H versus FCCP concentration.…”

Section: Hyperspectral Imaging and Unmixing Resultssupporting

confidence: 89%

Fluorescence quenching of free and bound NADH in HeLa cells determined by hyperspectral imaging and unmixing of cell autofluorescence

Rehman¹,

Anwer²,

Gosnell³

et al. 2017

Biomed. Opt. Express

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Carbonyl cyanide-p-trifluoro methoxyphenylhydrazone (FCCP) is a well-known mitochondrial uncoupling agent. We examined FCCP-induced fluorescence quenching of reduced nicotinamide adenine dinucleotide / nicotinamide adenine dinucleotide phosphate (NAD(P)H) in solution and in cultured HeLa cells in a wide range of FCCP concentrations from 50 to 1000µM. A non-invasive label-free method of hyperspectral imaging of cell autofluorescence combined with unsupervised unmixing was used to separately isolate the emissions of free and bound NAD(P)H from cell autofluorescence. Hyperspectral image analysis of FCCP-treated HeLa cells confirms that this agent selectively quenches fluorescence of free and bound NAD(P)H in a broad range of concentrations. This is confirmed by the measurements of average NAD/NADH and NADP/NADPH content in cells. FCCP quenching of free NAD(P)H in cells and in solution is found to be similar, but quenching of bound NAD(P)H in cells is attenuated compared to solution quenching possibly due to a contribution from the metabolic and/or antioxidant response in cells. Chemical quenching of NAD(P)H fluorescence by FCCP validates the results of unsupervised unmixing of cell autofluorescence. Hidalgo, "Ultraviolet excitation fluorescence spectroscopy: a noninvasive method for the measurement of redox changes in ischemic myocutaneous flaps," Plast. Reconstr. Surg. 96(3), 673-680 (1995). 31. J. Eng, R. M. Lynch, and R. S. Balaban, "Nicotinamide adenine dinucleotide fluorescence spectroscopy and imaging of isolated cardiac myocytes," Biophys. J. 55(4), 621-630 (1989). 32. A. S. Galkin, V. G. Grivennikova, and A. D. Vinogradov, "→H+/2e-stoichiometry in NADH-quinone reductase reactions catalyzed by bovine heart submitochondrial particles," FEBS Lett. 451(2), 157-161 (1999). 33. J. P. Brennan, R. G. Berry, M. Baghai, M. R. Duchen, and M. J. Shattock, "FCCP is cardioprotective at concentrations that cause mitochondrial oxidation without detectable depolarisation," Cardiovasc.

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Section: Hyperspectral Imaging and Unmixing Resultssupporting

confidence: 89%

Fluorescence quenching of free and bound NADH in HeLa cells determined by hyperspectral imaging and unmixing of cell autofluorescence

Rehman¹,

Anwer²,

Gosnell³

et al. 2017

Biomed. Opt. Express

View full text Add to dashboard Cite

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“…For 435 nm excitation we expect the dominant fluorescence signal to be due to intracellular flavins within the mucosa with perhaps some additional signal from mucosal collagen, which can be excited at this wavelength [66]. The fluorescence emission spectra peak measured in this study at ~530 nm is broadly consistent with the emission spectra of flavins [67] and collagen [66].…”

Section: Discussionsupporting

confidence: 77%

Fluorescence lifetime spectroscopy of tissue autofluorescence in normal and diseased colon measured ex vivo using a fiber-optic probe

Coda¹,

Thompson²,

Kennedy³

et al. 2014

Biomed. Opt. Express

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Abstract:We present an ex vivo study of temporally and spectrally resolved autofluorescence in a total of 47 endoscopic excision biopsy/resection specimens from colon, using pulsed excitation laser sources operating at wavelengths of 375 nm and 435 nm. A paired analysis of normal and neoplastic (adenomatous polyp) tissue specimens obtained from the same patient yielded a significant difference in the mean spectrally averaged autofluorescence lifetime −570 ± 740 ps (p = 0.021, n = 12). We also investigated the fluorescence signature of non-neoplastic polyps (n = 6) and inflammatory bowel disease (n = 4) compared to normal tissue in a small number of specimens. References and links1. R. Lambert, H. Saito, and Y. Saito, "High-resolution endoscopy and early gastrointestinal cancer...dawn in the East," Endoscopy 39(3), 232-237 (2007

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“…interactions between proteins in living cells 48,[82][83][84][85][86] , photophysics of complexes involved in plant photosynthesis 87 or the redox metabolism 38,50,[88][89][90] . In the last years, FLIM gained on interest in the biomedicine, as well 27,49,78,[91][92][93][94][95][96] .…”

Section: Bioscientific Applicationsmentioning

confidence: 99%

Fluorescence lifetime imaging in biosciences: technologies and applications

Niesner

Gericke

2008

Front. Phys. China

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The biosciences require the development of methods, which allow a non-invasive and rapid investigation of biological systems. In this frame high-end imaging techniques allow an intravital microscopy in real-time, providing information on a molecular basis. Far-field fluorescence imaging techniques are some of the most adequate methods for such investigations. However, there are great differences between the common fluorescence imaging techniques, i.e. wide-field, confocal one-photon and two-photon microscopy, respectively, as far as their applicability in diverse bioscientific research areas is concerned. In the first part of this work, we briefly compare these techniques. Standard methods used in the biosciences, i.e. steady-state techniques based on the analysis of the total fluorescence signal originating from the sample, can successfully be employed in the study of cell, tissue and organ morphology as well as in monitoring the macroscopic tissue function. However, they are mostly inadequate for the quantitative investigation of the cellular function at molecular level. The intrinsic disadvantages of steady-state techniques are counteracted by using time-resolved techniques. Among these the fluorescence lifetime imaging (FLIM) is currently the most common. Different FLIM principles as well as applications of particular relevance for the biosciences, especially for fast intravital studies are discussed in this work.

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Towards metabolic mapping of the human retina

Cited by 200 publications

References 38 publications

Fluorescence quenching of free and bound NADH in HeLa cells determined by hyperspectral imaging and unmixing of cell autofluorescence

Fluorescence quenching of free and bound NADH in HeLa cells determined by hyperspectral imaging and unmixing of cell autofluorescence

Fluorescence lifetime spectroscopy of tissue autofluorescence in normal and diseased colon measured ex vivo using a fiber-optic probe

Fluorescence lifetime imaging in biosciences: technologies and applications

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