Real‐time fiber‐based fluorescence lifetime imaging with synchronous external illumination: A new path for clinical translation

Lagarto, João L.; Shcheslavskiy, Vladislav I.; Pavone, Francesco S.; Cicchi, Riccardo

doi:10.1002/jbio.201960119

Cited by 19 publications

(23 citation statements)

References 56 publications

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“…2) reveal a well-demarcated region that is coincident with the area of collagen digestion, yielding shorter lifetime relative to non-digested areas. These results are in close agreement with previous studies of cartilage digestion 46,47,53 . The decrease in autofluorescence lifetime is more prominent in channels 1 and 2, i.e.…”

Section: Discussionsupporting

confidence: 93%

“…For two references fluorophores (POPOP in ethanol and flavin adenine dinucleotide (FAD) in purified water) we measured fluorescence lifetimes of 1.36 ± 0.04 ns and 4.02 ± 0.08 ns, respectively. These are comparable to fluorescence lifetimes of 1.32 ± 0.03 ns and 3.79 ± 0.06 ns measured in a TCSPC setup 46 .…”

Section: Data Analysis Fluorescence Lifetime Datasupporting

confidence: 85%

“…In a previous study, we introduced a technique employing TCSPC and hybrid photon counting detectors to realize single-channel fibre-based fluorescence lifetime imaging from single-point measurements in real-time and under bright illumination of the FOV 46 . Here, we aimed to expand this technique by employing SPAD array detectors to provide multispectral resolution to the lifetime measurement and thus increase the specificity of the fluorescence output.…”

Section: Discussionmentioning

confidence: 99%

“…Augmented fluorescence lifetime and spectral imaging in real time. To generate autofluorescence lifetime and intensity maps out of single-point measurements, we used the aiming beam approach that was previously described by others 30 and expanded by our group in the context of TCSPC measurements 46 . In brief, fluorescence measurements are realized by moving the fibre probe freely across the specimen.…”

mentioning

confidence: 99%

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Real-time multispectral fluorescence lifetime imaging using Single Photon Avalanche Diode arrays

Lagarto

Villa

Tisa

et al. 2020

Sci Rep

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Autofluorescence spectroscopy has emerged in recent years as a powerful tool to report label-free contrast between normal and diseased tissues, both in vivo and ex vivo. We report the development of an instrument employing Single Photon Avalanche Diode (SPAD) arrays to realize real-time multispectral autofluorescence lifetime imaging at a macroscopic scale using handheld single-point fibre optic probes, under bright background conditions. At the detection end, the fluorescence signal is passed through a transmission grating and both spectral and temporal information are encoded in the SPAD array. This configuration allows interrogation in the spectral range of interest in real time. Spatial information is provided by an external camera together with a guiding beam that provides a visual reference that is tracked in real-time. Through fast image processing and data analysis, fluorescence lifetime maps are augmented on white light images to provide feedback of the measurements in realtime. We validate and demonstrate the practicality of this technique in the reference fluorophores and in articular cartilage samples mimicking the degradation that occurs in osteoarthritis. Our results demonstrate that SPADs together with fibre probes can offer means to report autofluorescence spectral and lifetime contrast in real-time and thus are suitable candidates for in situ tissue diagnostics.

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Section: Discussionsupporting

confidence: 93%

Section: Data Analysis Fluorescence Lifetime Datasupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Real-time multispectral fluorescence lifetime imaging using Single Photon Avalanche Diode arrays

Lagarto

Villa

Tisa

et al. 2020

Sci Rep

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“…However, the known literature and this study suggest that a multimodal approach-e.g., combining reflectance with laser spectroscopy-is crucial for improving sensitivity and specificity in tumor detection beyond the capability of each single technique. Further, multimodal spectroscopy could be exploited for scanning large brain areas upon implementation within real-time fiber probes 46 or imaging systems. 47 In conclusion, the in vivo results presented here represents an additional, although preliminary, encouraging step toward clinical translation and deployment of Raman and reflectance spectroscopies for a fast, label-free detection, and delineation of human brain tumors.…”

Section: Discussionmentioning

confidence: 99%

In vivo detection of murine glioblastoma through Raman and reflectance fiber-probe spectroscopies

et al. 2020

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Significance: Glioblastoma (GBM) is the most common and aggressive malignant brain tumor in adults. With a worldwide incidence rate of 2 to 3 per 100,000 people, it accounts for more than 60% of all brain cancers; currently, its 5-year survival rate is <5%. GBM treatment relies mainly on surgical resection. In this framework, multimodal optical spectroscopy could provide a fast and label-free tool for improving tumor detection and guiding the removal of diseased tissues. Aim: Discriminating healthy brain from GBM tissues in an animal model through the combination of Raman and reflectance spectroscopies. Approach: EGFP-GL261 cells were injected into the brains of eight laboratory mice for inducing murine GBM in these animals. A multimodal optical fiber probe combining fluorescence, Raman, and reflectance spectroscopy was used to localize in vivo healthy and tumor brain areas and to collect their spectral information. Results: Tumor areas were localized through the detection of EGFP fluorescence emission. Then, Raman and reflectance spectra were collected from healthy and tumor tissues, and later analyzed through principal component analysis and linear discriminant analysis in order to develop a classification algorithm. Raman and reflectance spectra resulted in 92% and 93% classification accuracy, respectively. Combining together these techniques allowed improving the discrimination between healthy and tumor tissues up to 97%. Conclusions: These preliminary results demonstrate the potential of multimodal fiber-probe spectroscopy for in vivo label-free detection and delineation of brain tumors, and thus represent an additional, encouraging step toward clinical translation and deployment of fiber-probe spectroscopy.

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Mesoscopic fluorescence lifetime imaging: Fundamental principles, clinical applications and future directions

Alfonso-García

Bec

Weyers

et al. 2021

Journal of Biophotonics

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Fluorescence lifetime imaging (FLIm) is an optical spectroscopic imaging technique capable of real‐time assessments of tissue properties in clinical settings. Label‐free FLIm is sensitive to changes in tissue structure and biochemistry resulting from pathological conditions, thus providing optical contrast to identify and monitor the progression of disease. Technical and methodological advances over the last two decades have enabled the development of FLIm instrumentation for real‐time, in situ, mesoscopic imaging compatible with standard clinical workflows. Herein, we review the fundamental working principles of mesoscopic FLIm, discuss the technical characteristics of current clinical FLIm instrumentation, highlight the most commonly used analytical methods to interpret fluorescence lifetime data and discuss the recent applications of FLIm in surgical oncology and cardiovascular diagnostics. Finally, we conclude with an outlook on the future directions of clinical FLIm.

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Real‐time fiber‐based fluorescence lifetime imaging with synchronous external illumination: A new path for clinical translation

Cited by 19 publications

References 56 publications

Real-time multispectral fluorescence lifetime imaging using Single Photon Avalanche Diode arrays

Real-time multispectral fluorescence lifetime imaging using Single Photon Avalanche Diode arrays

In vivo detection of murine glioblastoma through Raman and reflectance fiber-probe spectroscopies

Mesoscopic fluorescence lifetime imaging: Fundamental principles, clinical applications and future directions

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