Expanding the potential of standard flow cytometry by extracting fluorescence lifetimes from cytometric pulse shifts

Cao, Ruofan; Naivar, Mark A.; Wilder, Mark E.; Houston, Jessica P.

doi:10.1002/cyto.a.22574

Cited by 24 publications

(22 citation statements)

References 36 publications

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“…Even higher throughput could be achieved by measuring the phase shift of the fluorescence signal relative to the scatter signal. Both simulations and experimental data demonstrated that this parameter, called fluorescence pulse delay by the authors, reveals the fluorescence lifetime (10). Various FRET methods of common interest are listed in Table 1.…”

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confidence: 89%

“…An inventive approach to the latter has been implemented via converting a conventional inverted wide-field fluorescence microscope into a lifetime-measuring instrument by combining a microfluidics cell-handling system with time-correlated single photon counting. Both simulations and experimental data demonstrated that this parameter, called fluorescence pulse delay by the authors, reveals the fluorescence lifetime (10). Even higher throughput could be achieved by measuring the phase shift of the fluorescence signal relative to the scatter signal.…”

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confidence: 94%

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The flow of events: How the sequence of molecular interactions is seen by the latest, user‐friendly high throughput flow cytometric FRET

2016

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F€ orster (or less precisely Fluorescence) Resonance Energy Transfer (FRET) is widely used by biologists to study the clustering of biomolecules tagged appropriately with chromophores in order to decipher the inner workings of the cell. FRET is a collision-free interchromophoric relaxation process that transfers energy nonradiatively from an initially excited donor to a ground-state acceptor in a distance-dependent way. FRET occurs over interatomic distances due to resonance-based dipole-dipole interaction of chromophores without transmission of photons from donor to acceptor species. Therefore, it is inaccurate to use fluorescence with the acronym FRET, since fluorescence involves emission of photons. At distances below 1 nm, collisions between the donor and acceptor would prevail, whereas at distances higher than 10 nm, photon emission by the donor would dominate, so FRET occurs only in the near field, i.e., in the range of 1-10 nm (1-3). Measuring the efficiency of FRET can serve as a "spectroscopic ruler" within this range, and provide absolute quantitative data describing interand intramolecular interactions (4).The application of FRET in biological sciences has seen an incredible expansion lately with almost 9000 hits retrieved by PubMed using FRET as a unique keyword. While the number of published papers applying FRET fluctuated between zero and one annually before 1985, >1000 publications could be found in the PubMed database in the year of 2015. This stark contrast clearly demonstrates the astonishing expansion rate of FRET applications. Partly because of this tremendous increase in the number of FRET studies, two international discussion meetings were devoted solely to FRET in life sciences. The FRET1 meeting was held from the 27th till the 30th of March in 2011 (http://www.fret.uni-duesseldorf.de/cms/fret_1.html), and the FRET 2 conference took place between the 3rd and the 6th of April in 2016 (http://www.fret.uni-duesseldorf.de/cms), both of them in G€ ottingen. Both FRET meetings were very successful, and the participants of the first meeting compiled an excellent book about "FRET from theory to applications" (5).This enormous increase in the application of FRET in biological sciences is partially due to the increase in the number of methods for evaluating FRET quantitatively, including improvements in intensity-and lifetime-based FRET methods. The accuracy of the calculation of FRET efficiency based on intensity ratios could be increased computationally even in samples having low signal to noise ratios by applying maximum likelihood estimation (MLE) (6,7). The improvement occurs because the MLE method takes the Poisson statistics inherent to photon-based detection into consideration (6,7). Not only intensity ratios but changes in the fluorescence lifetime can be used to estimate the FRET efficiency. Fluorescence

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confidence: 89%

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confidence: 94%

The flow of events: How the sequence of molecular interactions is seen by the latest, user‐friendly high throughput flow cytometric FRET

2016

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“…We have demonstrated instruments that use digital laser modulation or pulsation, high speed data acquisition, and digital signal processing to provide fluorescence lifetime-based values for cell counting or sorting that operate at rates of thousands of cells per second [6][7][8][9]. These approaches for measuring fluorescence lifetimes with flow cytometers have involved both frequency-domain as well as time-domain methods.…”

Section: Introductionmentioning

confidence: 99%

“…We and others have demonstrated different versions of time-resolved flow cytometry [3,[7][8][9][10][11][12][13][14], and the main objective for augmenting flow cytometers to detect fluorescence lifetimes is to enhance cytometric data with a quantitative parameter that is independent of the measured fluorescence intensity [11,[15][16][17]. As a parameter, fluorescence lifetime can be used to discriminate among spectrally overlapping fluorescence signals as well as to validate the fluorescence intensity changes that arise from quenched fluorophores such as during Förster resonance energy transfer (FRET) events like those arising from changes in association state of tagged cytoplasmic proteins.…”

Section: Introductionmentioning

confidence: 99%

Phasor plotting with frequency-domain flow cytometry

et al. 2016

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Interest in time resolved flow cytometry is growing. In this paper, we collect time-resolved flow cytometry data and use it to create polar plots showing distributions that are a function of measured fluorescence decay rates from individual fluorescently-labeled cells and fluorescent microspheres. Phasor, or polar, graphics are commonly used in fluorescence lifetime imaging microscopy (FLIM). In FLIM measurements, the plotted points on a phasor graph represent the phase-shift and demodulation of the frequency-domain fluorescence signal collected by the imaging system for each image pixel. Here, we take a flow cytometry cell counting system, introduce into it frequency-domain optoelectronics, and process the data so that each point on a phasor plot represents the phase shift and demodulation of an individual cell or particle. In order to demonstrate the value of this technique, we show that phasor graphs can be used to discriminate among populations of (i) fluorescent microspheres, which are labeled with one fluorophore type; (ii) Chinese hamster ovary (CHO) cells labeled with one and two different fluorophore types; and (iii) Saccharomyces cerevisiae cells that express combinations of fluorescent proteins with different fluorescence lifetimes. The resulting phasor plots reveal differences in the fluorescence lifetimes within each sample and provide a distribution from which we can infer the number of cells expressing unique single or dual fluorescence lifetimes. These methods should facilitate analysis time resolved flow cytometry data to reveal complex fluorescence decay kinetics.

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“…For example, mass spectrometry combined with cytometry moves away from fluorescence‐based detection entirely by using antibodies tagged with rare earth metals, and in doing so easily achieves over 40 measured parameters per cell . Similarly, full spectral flow cytometry is pervasive, and ways in which fluorescence dynamics (i.e., fluorescence lifetimes) can be measured has gained acceptance in recent years . Again, not spatially dependent, these optical measurements add to the information content per‐cell in ways that alleviate issues with conventional systems.…”

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confidence: 99%