Confocal Fluorescence-Lifetime Single-Molecule Localization Microscopy

Thiele, Jan C.; Helmerich, Dominic A.; Oleksiievets, Nazar; Tsukanov, Roman; Butkevich, Eugenia; Sauer, Markus; Nevskyi, Oleksii; Enderlein, Joerg

doi:10.1021/acsnano.0c07322

Cited by 88 publications

(96 citation statements)

References 49 publications

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“…In FLI-based approaches, lifetime signatures can be successfully discriminated from unwanted spectrally overlapping autofluorescence signals (Rudkouskaya et al, 2020b;del Rosal and Benayas, 2018;Okkelman et al, 2017bOkkelman et al, , 2020cRich et al, 2013). FLIM as a contrast enhancement methodology has become more popular with the advent of super-resolution microscopy (Auksorius et al, 2008;Bückers et al, 2011;Hell and Wichmann, 1994;Niehörster et al, 2016;Masullo et al, 2020;Thiele et al, 2020), providing a new way to multiplex fluorescence imaging. 3D FLIM for contrast enhancement has been demonstrated in proof-ofconcept light-sheet microscopy with optically cleared and fixed samples Greger et al, 2011;Favreau et al, 2020;Funane et al, 2018;Mitchell et al, 2017;Weber et al, 2015;Li et al, 2020;Birch et al, 2016).…”

Section: Contrast Enhancement For High-performance 3d Imaging and Super-resolution Microscopymentioning

confidence: 99%

Luminescence lifetime imaging of three-dimensional biological objects

Dmitriev

Intes

Barroso

2021

Journal of Cell Science

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A major focus of current biological studies is to fill the knowledge gaps between cell, tissue and organism scales. To this end, a wide array of contemporary optical analytical tools enable multiparameter quantitative imaging of live and fixed cells, three-dimensional (3D) systems, tissues, organs and organisms in the context of their complex spatiotemporal biological and molecular features. In particular, the modalities of luminescence lifetime imaging, comprising fluorescence lifetime imaging (FLI) and phosphorescence lifetime imaging microscopy (PLIM), in synergy with Förster resonance energy transfer (FRET) assays, provide a wealth of information. On the application side, the luminescence lifetime of endogenous molecules inside cells and tissues, overexpressed fluorescent protein fusion biosensor constructs or probes delivered externally provide molecular insights at multiple scales into protein–protein interaction networks, cellular metabolism, dynamics of molecular oxygen and hypoxia, physiologically important ions, and other physical and physiological parameters. Luminescence lifetime imaging offers a unique window into the physiological and structural environment of cells and tissues, enabling a new level of functional and molecular analysis in addition to providing 3D spatially resolved and longitudinal measurements that can range from microscopic to macroscopic scale. We provide an overview of luminescence lifetime imaging and summarize key biological applications from cells and tissues to organisms.

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Section: Contrast Enhancement For High-performance 3d Imaging and Super-resolution Microscopymentioning

confidence: 99%

Luminescence lifetime imaging of three-dimensional biological objects

Dmitriev

Intes

Barroso

2021

Journal of Cell Science

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“…A super-resolution microscope that can also acquire lifetime data is advantageous for detecting fluorophores with similar spectral properties and for lifetime-based Förster resonance energy transfer (FRET) measurements. Thiele et al 11 two-channel images. Super-resolved separation of two species was achieved by Baysian pattern matching on confocal FLIM data.…”

Section: Single-molecule Flimmentioning

confidence: 99%

Recent innovations in fluorescence lifetime imaging microscopy for biology and medicine

et al. 2021

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Significance: Fluorescence lifetime imaging microscopy (FLIM) measures the decay rate of fluorophores, thus providing insights into molecular interactions. FLIM is a powerful molecular imaging technique that is widely used in biology and medicine.Aim: This perspective highlights some of the major advances in FLIM instrumentation, analysis, and biological and clinical applications that we have found impactful over the last year.Approach: Innovations in FLIM instrumentation resulted in faster acquisition speeds, rapid imaging over large fields of view, and integration with complementary modalities such as singlemolecule microscopy or light-sheet microscopy. There were significant developments in FLIM analysis with machine learning approaches to enhance processing speeds, fit-free techniques to analyze images without a priori knowledge, and open-source analysis resources. The advantages and limitations of these recent instrumentation and analysis techniques are summarized. Finally, applications of FLIM in the last year include label-free imaging in biology, ophthalmology, and intraoperative imaging, FLIM of new fluorescent probes, and lifetime-based Förster resonance energy transfer measurements.Conclusions: A large number of high-quality publications over the last year signifies the growing interest in FLIM and ensures continued technological improvements and expanding applications in biomedical research.

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“…This excitation light is passed through confocally aligned pinholes, which results in a small volume (200 nm × 200 nm × 500 nm in dimension) being illuminated, and the emission light from that volume being detected while excluding out-of-focus sources of signal [93] , [94] . The traditional approach to confocal microscopy utilises ‘optical sectioning’, whereby the laser is scanned through a sample in all three spatial dimensions (depths of up to 500 nm can typically be achieved), and a three-dimensional image of the sample (such as a cell) is obtained [95] , [96] .…”

Section: Single-molecule Techniquesmentioning

confidence: 99%

“…An alternative use of a confocal microscope is to place the confocal volume inside an aqueous solution, detecting the transient bursts of fluorescence originating from individual labelled species as they diffuse through the excitation volume [97] . Following excitation of a fluorophore, photons emitted from the molecule can be detected (typically using single-photon detector arrays), thus providing single-molecule sensitivity [96] , [98] . In contrast to TIRF microscopy ( Fig.…”

Section: Single-molecule Techniquesmentioning

confidence: 99%

“…Common methods that employ this approach include (i) fluorescence correlation spectroscopy (FCS), in which the apparent sizes of molecules as they pass through the confocal volume are calculated by analysis of their diffusion, and (ii) two-colour coincidence detection (TCCD), in which the simultaneous detection of two fluorescent signals within the confocal volume is used to detect biomolecular associations. Experiments that couple confocal microscopy with time-resolved single-photon detection enable the collection of data on fluorescence lifetimes [96] , and fast dynamics via Förster resonance energy transfer (FRET) based applications [96] , [100] , [101] vastly increase the information that can be obtained from single-molecule confocal imaging approaches. A limitation of confocal microscopy is the size of the confocal volume: molecules can only be monitored for the period of time they remain in the confocal volume (often data acquisition has to occur on the nano- to milli-second time scales) [102] .…”

Section: Single-molecule Techniquesmentioning

confidence: 99%

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