Simple imaging protocol for autofluorescence elimination and optical sectioning in fluorescence endomicroscopy

Fiber-optic epifluorescence imaging with one-photon excitation benefits from its ease of use, cheap light sources, and full-frame acquisition, which enables it for favorable temporal resolution of image acquisition. However, it suffers from a lack of robustness against autofluorescence and light scattering. Moreover, it cannot easily eliminate the out-of-focus background, which generally results in low-contrast images. In order to overcome these limitations, we have implemented fast out-of-phase imaging after optical modulation (Speed OPIOM) for dynamic contrast in fluorescence endomicroscopy. Using a simple and cheap optical-fiber bundle-based endomicroscope integrating modulatable light sources, we first showed that Speed OPIOM provides intrinsic optical sectioning, which restricts the observation of fluorescent labels at targeted positions within a sample. We also demonstrated that this imaging protocol efficiently eliminates the interference of autofluorescence arising from both the fiber bundle and the specimen in several biological samples. Finally, we could perform multiplexed observations of two spectrally similar fluorophores differing by their photoswitching dynamics. Such attractive features of Speed OPIOM in fluorescence endomicroscopy should find applications in bioprocessing, clinical diagnostics, plant observation, and surface imaging.

[1]  F. Helmchen,et al.  Miniaturized two-photon microscope based on a flexible coherent fiber bundle and a gradient-index lens objective. , 2004, Optics letters.

[2]  Richard M Levenson,et al.  Autofluorescence removal, multiplexing, and automated analysis methods for in-vivo fluorescence imaging. , 2005, Journal of biomedical optics.

[3]  J. Widengren Fluorescence-based transient state monitoring for biomolecular spectroscopy and imaging , 2010, Journal of The Royal Society Interface.

[4]  P. Neveu,et al.  Resonant out-of-phase fluorescence microscopy and remote imaging overcome spectral limitations , 2017, Nature Communications.

[5]  R. Gordon,et al.  Development of a versatile two-photon endoscope for biological imaging , 2010, Biomedical optics express.

[6]  Jerome Mertz,et al.  Fast optically sectioned fluorescence HiLo endomicroscopy. , 2012, Journal of biomedical optics.

[7]  V. Adam,et al.  Reversible photoswitching in fluorescent proteins: A mechanistic view , 2012, IUBMB life.

[8]  Urs Utzinger,et al.  Spectral background and transmission characteristics of fiber optic imaging bundles. , 2008, Applied optics.

[9]  Weijian Yang,et al.  In vivo imaging of neural activity , 2017, Nature Methods.

[10]  Cleo Kontoravdi,et al.  Genetically-encoded biosensors for monitoring cellular stress in bioprocessing. , 2015, Current opinion in biotechnology.

[11]  S. Yun,et al.  Optical fibers for high-resolution in vivo microendoscopic fluorescence imaging , 2013 .

[12]  R. Richards-Kortum,et al.  Differential structured illumination microendoscopy for in vivo imaging of molecular contrast agents , 2016, Proceedings of the National Academy of Sciences.

[13]  D. Gweon,et al.  Endoscopic focal modulation microscopy , 2013, Journal of microscopy.

[14]  Min Gu,et al.  Fast handheld two-photon fluorescence microendoscope with a 475 μm × 475 μm field of view for in vivo imaging , 2008 .

[15]  Eric A. Owens,et al.  Tailoring cyanine dark states for improved optically modulated fluorescence recovery. , 2015, The journal of physical chemistry. B.

[16]  J. Geiselmann,et al.  Shared control of gene expression in bacteria by transcription factors and global physiology of the cell , 2013, Molecular systems biology.

[17]  P. Shankar,et al.  A review of fiber-optic biosensors , 2007 .

[18]  J. Lichtman,et al.  Optical sectioning microscopy , 2005, Nature Methods.

[19]  Christian Eggeling,et al.  1.8 A bright-state structure of the reversibly switchable fluorescent protein Dronpa guides the generation of fast switching variants. , 2007, The Biochemical journal.

[20]  B. Viellerobe,et al.  Fibered confocal spectroscopy and multicolor imaging system for in vivo fluorescence analysis. , 2007, Optics express.

[21]  N. Stuurman,et al.  Simultaneous imaging of Pseudomonas fluorescens WCS365 populations expressing three different autofluorescent proteins in the rhizosphere: new perspectives for studying microbial communities. , 2000, Molecular plant-microbe interactions : MPMI.

[22]  Eric J Seibel,et al.  Unique features of optical scanning, single fiber endoscopy * ** , 2002, Lasers in surgery and medicine.

[23]  Yaniv Ziv,et al.  Miniature microscopes for large-scale imaging of neuronal activity in freely behaving rodents , 2015, Current Opinion in Neurobiology.

[24]  Alison G. Tebo,et al.  Macroscale fluorescence imaging against autofluorescence under ambient light , 2018, Light: Science & Applications.

[25]  W. O'Neill,et al.  Controlling the optical fiber output beam profile by focused ion beam machining of a phase hologram on fiber tip. , 2015, Applied optics.

[26]  A. Gmitro,et al.  Confocal microscopy through a fiber-optic imaging bundle. , 1993, Optics letters.

[27]  Karen M Polizzi,et al.  Sense and sensitivity in bioprocessing-detecting cellular metabolites with biosensors. , 2017, Current opinion in chemical biology.

[28]  Joel N. Bixler,et al.  Confocal Endomicroscopy: Instrumentation and Medical Applications , 2012, Annals of Biomedical Engineering.

[29]  E. Cocker,et al.  In vivo brain imaging using a portable 3.9 gram two-photon fluorescence microendoscope. , 2005, Optics letters.

[30]  P. Choyke,et al.  Fluorescence-Guided Surgery , 2017, Front. Oncol..

[31]  R. Richards-Kortum,et al.  Fiber optic probes for biomedical optical spectroscopy. , 2003, Journal of biomedical optics.

[32]  E. Cocker,et al.  Fiber-optic fluorescence imaging , 2005, Nature Methods.

[33]  Timothy J Muldoon,et al.  Noninvasive imaging of oral neoplasia with a high-resolution fiber-optic microendoscope , 2012, Head & neck.

[34]  D. Jocham,et al.  A FLUORESCENCE IMAGING DEVICE FOR ENDOSCOPIC DETECTION OF EARLY STAGE CANCER – INSTRUMENTAL and EXPERIMENTAL STUDIES , 1987, Photochemistry and photobiology.

[35]  W. Denk,et al.  Deep tissue two-photon microscopy , 2005, Nature Methods.

[36]  Joel N. Bixler,et al.  Intravital Fluorescence Excitation in Whole-Animal Optical Imaging , 2016, PloS one.

[37]  Jerome Mertz,et al.  Optically sectioned fluorescence endomicroscopy with hybrid-illumination imaging through a flexible fiber bundle. , 2009, Journal of biomedical optics.

[38]  U. Alon,et al.  A comprehensive library of fluorescent transcriptional reporters for Escherichia coli , 2006, Nature Methods.

[39]  J. Vos,et al.  Estimation of root densities by observation tubes and endoscope , 1983, Plant and Soil.

[40]  S. Lukyanov,et al.  Fluorescent proteins and their applications in imaging living cells and tissues. , 2010, Physiological reviews.

[41]  R. S. Rodrigues Ribeiro,et al.  Optical fibers as beam shapers: from Gaussian beams to optical vortices. , 2016, Optics letters.

[42]  Ivan B. N. Clark,et al.  Unmixing of fluorescence spectra to resolve quantitative time-series measurements of gene expression in plate readers , 2014, BMC Biotechnology.

[43]  G. Calafiore,et al.  Nanoimprint of a 3D structure on an optical fiber for light wavefront manipulation , 2016, Nanotechnology.

[44]  R. Dickson,et al.  Synchronously amplified fluorescence image recovery (SAFIRe). , 2010, The journal of physical chemistry. B.

[45]  R Richards-Kortum,et al.  Fiber-optic confocal microscopy using a spatial light modulator. , 2000, Optics letters.

[46]  Charles P. Lin,et al.  In vivo confocal and multiphoton microendoscopy. , 2008, Journal of biomedical optics.

[47]  Corinne Pinel,et al.  Green autofluorescence, a double edged monitoring tool for bacterial growth and activity in micro-plates , 2015, Physical biology.

[48]  Miriam Athmann,et al.  Root growth in biopores—evaluation with in situ endoscopy , 2013, Plant and Soil.

[49]  Daniel J. Gould,et al.  Advances in fluorescent-image guided surgery. , 2016, Annals of translational medicine.

[50]  Jared E. Toettcher,et al.  Optogenetic regulation of engineered cellular metabolism for microbial chemical production , 2018, Nature.

[51]  Christian Eggeling,et al.  Photoswitchable fluorescent proteins enable monochromatic multilabel imaging and dual color fluorescence nanoscopy , 2008, Nature Biotechnology.

[52]  A. Mehta,et al.  In vivo mammalian brain imaging using one- and two-photon fluorescence microendoscopy. , 2004, Journal of neurophysiology.

[53]  Timothy J Muldoon,et al.  Subcellular-resolution molecular imaging within living tissue by fiber microendoscopy. , 2007, Optics express.

[54]  Tim N. Ford,et al.  Fluorescence endomicroscopy with structured illumination. , 2008, Optics express.

[55]  Ehud Y Isacoff,et al.  Optical lock-in detection imaging microscopy for contrast-enhanced imaging in living cells , 2008, Proceedings of the National Academy of Sciences.

[56]  A. Miyawaki,et al.  Highlighted generation of fluorescence signals using simultaneous two-color irradiation on Dronpa mutants. , 2007, Biophysical journal.

[57]  J. Girkin,et al.  Micro-endoscope for in vivo widefield high spatial resolution fluorescent imaging , 2012, Biomedical optics express.

[58]  A. Rouse,et al.  Multispectral imaging with a confocal microendoscope. , 2000, Optics letters.

[59]  Rafal Klajn,et al.  Spiropyran-based dynamic materials. , 2014, Chemical Society reviews.

[60]  Shaoqun Zeng,et al.  Fast optical sectioning obtained by structured illumination microscopy using a digital mirror device , 2013, Journal of biomedical optics.

[61]  Richard P Harrison,et al.  Enhancing cell and gene therapy manufacture through the application of advanced fluorescent optical sensors (Review). , 2018, Biointerphases.