Fast fluorescence lifetime imaging techniques: A review on challenge and development

Liu, Xiongbo; Lin, Danying; Becker, Wolfgang; Niu, Jingjing; Yu, Bin; Liu, Liwei; Qu, Junle

doi:10.1142/s1793545819300039

Cited by 86 publications

(73 citation statements)

References 150 publications

(196 reference statements)

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“…For example, Liu et al reviewed the recent progress on fast FLIM technique from the following aspects: the biophysical and electronic characteristics limiting FLIM speed, di®erent imaging techniques for breaking the \speed limit" and di®erent analytical tools for fast imaging. 1 Wang et al comprehensively introduced the FRET-FLIM technology including the principle, detection method and data processing, which enables the study of dynamic proteinprotein interactions in biological¯eld. 2 Liu et al and Li et al reviewed the progress of FLIM-based skin cancer diagnosis 3 and the application of TP-FLIM in tumor detection, 4 respectively.…”

Section: Fluorescence Lifetime Imaging Microscopy (Flim)mentioning

confidence: 99%

Introduction to the Special Issue on Fluorescence Lifetime Imaging Microscopy (FLIM)

Liu

2019

J. Innov. Opt. Health Sci.

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Fluorescence Lifetime Imaging Microscopy (FLIM)is an advanced tool that enables the description of exponential decay rate distribution of°uorescent molecules in the samples. This technique has been broadly used in biomedicine, material science, chemistry, and other related research¯elds, due to its ability to illustrate both localization of speci¯c°u orophores and°uorophores' local microenvironment, and it is superior to°uorescence intensity based imaging. However, the FLIM imaging speed is inherently limited due to the long exponential decay collecting process, which may not be proper for monitoring fast dynamic biological processes in tissue, not to mention at single protein level. Excellent°uorescence labeling techniques, advanced imaging techniques and e±cient analytical tools together enable faster FLIM imaging. As the application of FLIM in biological¯eld progresses, new requirements for FLIM technique are proposed, such as protein-protein interaction, label-free detection, deep tissue imaging, and so on.In this Special Issue, four review papers and ve original research articles are presented. For example, Liu et al. reviewed the recent progress on fast FLIM technique from the following aspects: the biophysical and electronic characteristics limiting FLIM speed, di®erent imaging techniques for breaking the \speed limit" and di®erent analytical tools for fast imaging. 1 Wang et al. comprehensively introduced the FRET-FLIM technology including the principle, detection method and data processing, which enables the study of dynamic proteinprotein interactions in biological¯eld. 2 Liu et al. and Li et al. reviewed the progress of FLIM-based skin cancer diagnosis 3 and the application of TP-FLIM in tumor detection, 4 respectively. In addition, ve original studies presented in this issue range from FLIM-based cell death monitoring, 5 excellent°u orescent probes (QDs and 3P dye) for FLIM, 6,7 laser source for FLIM, 8 to label-free FLIM-based tumor diagnosis. 9 Overall, they present not only the FLIM technology itself, but also the application of FLIM in biological and biomedical¯elds, especially in protein-protein interactions and cancer diagnosis. Therefore, we strongly recommend this FLIM issue.

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Section: Fluorescence Lifetime Imaging Microscopy (Flim)mentioning

confidence: 99%

Introduction to the Special Issue on Fluorescence Lifetime Imaging Microscopy (FLIM)

Liu

2019

J. Innov. Opt. Health Sci.

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“…Fluorescence lifetime imaging (FLIM) is a well-established, robust technique for quantitative intracellular measurements of protein-protein interactions by Förster resonance energy transfer (FRET) [1][2][3][4] , and highly photon efficient FRET measurements are achieved using FLIM with time-correlated single photon counting (TCSPC) 5 . In order to follow intracellular interactions using FLIM of biosensors based on FRET, measurements must often be made on the timescale of seconds, thus it is highly desirable to increase FLIM frame rates 6 whilst preserving the spatial and temporal accuracy and retaining a modest light dose at the sample. Time-domain widefield FLIM based on gated cameras 7 , optical intensifiers [8][9][10] , and more recently TCSPC detection using crossed delay line anode detection 11 and single photon avalanche diode (SPAD) arrays 12 , have been demonstrated with high frame rates.…”

mentioning

confidence: 99%

Quantitative real-time imaging of intracellular FRET biosensor dynamics using rapid multi-beam confocal FLIM

Levitt

Poland

Krstajić

et al. 2020

Sci Rep

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Fluorescence lifetime imaging (FLIM) is a quantitative, intensity-independent microscopical method for measurement of diverse biochemical and physical properties in cell biology. It is a highly effective method for measurements of Förster resonance energy transfer (FRET), and for quantification of protein-protein interactions in cells. Time-domain FLIM-FRET measurements of these dynamic interactions are particularly challenging, since the technique requires excellent photon statistics to derive experimental parameters from the complex decay kinetics often observed from fluorophores in living cells. Here we present a new time-domain multi-confocal FLIM instrument with an array of 64 visible beamlets to achieve parallelised excitation and detection with average excitation powers of ~ 1-2 μW per beamlet. We exemplify this instrument with up to 0.5 frames per second time-lapse FLIM measurements of cAMP levels using an Epac-based fluorescent biosensor in live HeLa cells with nanometer spatial and picosecond temporal resolution. We demonstrate the use of time-dependent phasor plots to determine parameterisation for multi-exponential decay fitting to monitor the fractional contribution of the activated conformation of the biosensor. Our parallelised confocal approach avoids having to compromise on speed, noise, accuracy in lifetime measurements and provides powerful means to quantify biochemical dynamics in living cells.

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“…Lifetime retrieval. Irrespective of the imaging modality used for FLIM measurements, extracting lifetime information is not a trivial matter [32]. The measured signal, f (t), is the convolution of the impulse response function (IRF) and the fluorescence decay of the fluorophore, g(t), can be expressed as:…”

mentioning

confidence: 99%

“…where t i is the time of the i-th sampling of the signal. A plethora of algorithms have been developed in order to tackle the problem of retrieving fluorescence decay (reviewed in [32]), with perhaps the most common being least-squares (LSQ) deconvolution (sometimes referred to as 'reconvolution'). In this approach a model of the fluorescence decay is convolved with the IRF and compared to the measured data using LSQ minimisation.…”

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confidence: 99%

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Wide-field Fluorescence Lifetime Imaging Microscopy with a High-Speed Mega-pixel SPAD Camera

Žičkus

Morimoto

et al. 2020

Preprint

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Fluorescence lifetime imaging microscopy (FLIM) is a key technology that provides direct insight into cell metabolism, cell dynamics and protein activity. However, determining the lifetimes of different fluorescent proteins requires the detection of a relatively large number of photons, hence slowing down total acquisition times. Moreover, there are many cases, for example in studies of cell collectives, where wide-field imaging is desired. We report scan-less wide-field FLIM based on a 0.5 Megapixel resolution, time-gated Single Photon Avalanche Diode (SPAD) camera, with acquisition rates up to 1 Hz. Fluorescence lifetime estimation is performed via a pre-trained artificial neural network with 1000-fold improvement in processing times compared to standard least squares fitting techniques. We utilised our system to image HT1080 -human fibrosarcoma cell line as well as Convallaria. The results show promise for real-time FLIM and a viable route towards multi-megapixel fluorescence lifetime images, with a proof-of-principle mosaic image shown with 3.6 megapixels.

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Fast fluorescence lifetime imaging techniques: A review on challenge and development

Cited by 86 publications

References 150 publications

Introduction to the Special Issue on Fluorescence Lifetime Imaging Microscopy (FLIM)

Introduction to the Special Issue on Fluorescence Lifetime Imaging Microscopy (FLIM)

Quantitative real-time imaging of intracellular FRET biosensor dynamics using rapid multi-beam confocal FLIM

Wide-field Fluorescence Lifetime Imaging Microscopy with a High-Speed Mega-pixel SPAD Camera

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