Spatially co-registered wide-field nonlinear optical imaging of living and complex biosystems in a total internal reflection geometry

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Abstract

Nonlinear optical microscopy that leverages an objective based total internal reflection (TIR) excitation scheme is an attractive means for rapid, wide-field imaging with enhanced surface sensitivity. Through select combinations of distinct modalities, one can, in principle, access complementary chemical and structural information for various chemical species near interfaces. Here, we report a successful implementation of such a wide-field nonlinear optical microscope system, which combines coherent anti-Stokes Raman scattering (CARS), two-photon fluorescence (TPF), second harmonic generation (SHG), and sum frequency generation (SFG) modalities on the same platform. The intense optical fields needed to drive these high order nonlinear optical processes are achieved through the use of femtosecond pulsed light in combination with the intrinsic field confinement induced by TIR over a large field of view. The performance of our multimodal microscope was first assessed through the experimental determination of its chemical fidelity, intensity and polarization dependences, and spatial resolution using a set of well-defined model systems. Subsequently, its unique capabilities were validated through imaging complex biological systems, includingHydrangea quercifoliapollen grains andPantoeasp. YR343 bacterial cells. Specifically, the spatial distribution of different molecular groups in the former was visualizedviavibrational contrast mechanisms of CARS, whereas co-registered TPF imaging allowed the identification of spatially localized intrinsic fluorophores. We further demonstrate the feasibility of our microscope for wide-field CARS imaging on live cells through independent characterization of cell viability using spatially co-registered TPF imaging. This approach to TIR enabled wide-field imaging is expected to provide new insights into bacterial strains and their interactions with other species in the rhizosphere in a time-resolved and chemically selective manner.

Original languageEnglish
Pages (from-to)3062-3072
Number of pages11
JournalAnalyst
Volume146
Issue number9
DOIs
StatePublished - May 7 2021

Funding

Research was supported by U.S. Department of Energy, Office of Science, Biological and Environmental Research, Bioimaging Science Program and the Genomic Sciences program, as part of the Plant Microbe Interfaces Scientific Focus Area (http://pmi.ornl.gov). Authors would like to acknowledge useful conversations with Prof. Tessa R. Calhoun who suggested lily pollen as a model sample and in the design of this microscope.

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