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Literature DB >> 26023359

FLIM-FRET for Cancer Applications.

Shilpi Rajoria¹, Lingling Zhao², Xavier Intes², Margarida Barroso¹.

Abstract

Optical imaging assays, especially fluorescence molecular assays, are minimally invasive if not completely noninvasive, and thus an ideal technique to be applied to live specimens. These fluorescence imaging assays are a powerful tool in biomedical sciences as they allow the study of a wide range of molecular and physiological events occurring in biological systems. Furthermore, optical imaging assays bridge the gap between the in vitro cell-based analysis of subcellular processes and in vivo study of disease mechanisms in small animal models. In particular, the application of Förster resonance energy transfer (FRET) and fluorescence lifetime imaging (FLIM), well-known techniques widely used in microscopy, to the optical imaging assay toolbox, will have a significant impact in the molecular study of protein-protein interactions during cancer progression. This review article describes the application of FLIM-FRET to the field of optical imaging and addresses their various applications, both current and potential, to anti-cancer drug delivery and cancer research.

Entities: CellLine Chemical Disease Gene Species

Keywords: Cancer therapy; Förster resonance energy transfer (FRET); diagnostics; fluorescence lifetime imaging (FLIM); in vivo imaging; lifetime; near infra-red (NIR)

Year: 2014 PMID： 26023359 PMCID： PMC4443864 DOI： 10.2174/2211555203666141117221111

Source DB: PubMed Journal: Curr Mol Imaging

99 in total

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Authors: Sunil Kumar; Dominic Alibhai; Anca Margineanu; Romain Laine; Gordon Kennedy; James McGinty; Sean Warren; Douglas Kelly; Yuriy Alexandrov; Ian Munro; Clifford Talbot; Daniel W Stuckey; Christopher Kimberly; Bertrand Viellerobe; Francois Lacombe; Eric W-F Lam; Harriet Taylor; Margaret J Dallman; Gordon Stamp; Edward J Murray; Frank Stuhmeier; Alessandro Sardini; Matilda Katan; Daniel S Elson; Mark A A Neil; Chris Dunsby; Paul M W French
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23 in total

1. Assessing patterns for compressive fluorescence lifetime imaging.

Authors: M Ochoa; Q Pian; R Yao; N Ducros; X Intes
Journal: Opt Lett Date: 2018-09-15 Impact factor: 3.776

2. Improving mesoscopic fluorescence molecular tomography via preconditioning and regularization.

Authors: Fugang Yang; Ruoyang Yao; Mehmet Ozturk; Denzel Faulkner; Qinglan Qu; Xavier Intes
Journal: Biomed Opt Express Date: 2018-05-23 Impact factor: 3.732

3. Reduced temporal sampling effect on accuracy of time-domain fluorescence lifetime Förster resonance energy transfer.

Authors: Travis Omer; Lingling Zhao; Xavier Intes; Juergen Hahn
Journal: J Biomed Opt Date: 2014-08 Impact factor: 3.170

4. High compression deep learning based single-pixel hyperspectral macroscopic fluorescence lifetime imaging in vivo.

Authors: M Ochoa; A Rudkouskaya; R Yao; P Yan; M Barroso; X Intes
Journal: Biomed Opt Express Date: 2020-09-02 Impact factor: 3.732

5. UNMIX-ME: spectral and lifetime fluorescence unmixing via deep learning.

Authors: Jason T Smith; Marien Ochoa; Xavier Intes
Journal: Biomed Opt Express Date: 2020-06-19 Impact factor: 3.732

6. The metabolic interaction of cancer cells and fibroblasts - coupling between NAD(P)H and FAD, intracellular pH and hydrogen peroxide.

Authors: Irina N Druzhkova; Marina V Shirmanova; Maria M Lukina; Varvara V Dudenkova; Nataliya M Mishina; Elena V Zagaynova
Journal: Cell Cycle Date: 2016-05-02 Impact factor: 4.534