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Imaging deeper than the transport mean free path with multiphoton microscopy

Najva Akbari, Mihailo R Rebec, Fei Xia, Chris Xu

2021Biomedical Optics Express31 citationsDOIOpen Access PDF

Abstract

Multiphoton fluorescence microscopy enables deep in vivo imaging by using long excitation wavelengths to increase the penetration depth of ballistic photons and nonlinear excitation to suppress the out-of-focus fluorescence. However, the imaging depth of multiphoton microscopy is limited by tissue scattering and absorption. This fundamental depth limit for two-photon microscopy has been studied theoretically and experimentally. Long wavelength three-photon fluorescence microscopy was developed to image beyond the depth limit of two-photon microscopy and has achieved unprecedented in vivo imaging depth. Here we extend the theoretical framework for characterizing the depth limit of two-photon microscopy to three-photon microscopy. We further verify the theoretical predictions with experimental results from tissue phantoms. We demonstrate experimentally that high spatial resolution diffraction-limited imaging at a depth of 10 scattering mean free paths, which is nearly twice the transport mean free path, is possible with multiphoton microscopy. Our results indicate that the depth limit of three-photon microscopy is significantly beyond what has been achieved in biological tissues so far, and further technological development is required to reach the full potential of three-photon microscopy.

Topics & Concepts

MicroscopyOpticsTwo-photon excitation microscopyPenetration depthOptical sectioningMaterials scienceFluorescence microscopeWavelengthMicroscopeScatteringFluorescence-lifetime imaging microscopyLight sheet fluorescence microscopySuper-resolution microscopyExcitationPhotonLight scatteringMean free pathOptical microscopeResolution (logic)Biological imagingImage resolutionConfocal microscopyScanning confocal electron microscopyPhotoactivated localization microscopyPoint spread functionPhysicsDigital holographic microscopyImage formationOptical pathAdvanced Fluorescence Microscopy TechniquesOptical Imaging and Spectroscopy TechniquesRandom lasers and scattering media
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