Axial super-resolution evanescent wave tomography

Pendharker, Sarang; Shende, Swapnali; Newman, Ward D.; Ogg, Stephen C.; Nazemifard, Neda; Jacob, Zubin

doi:10.1364/ol.41.005499

Cited by 12 publications

(4 citation statements)

References 29 publications

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“…As a clear demonstration of imaging performance for our Moirémetalens-based microscope, both standard resolution target and fluorescent microspheres are imaged, with a lateral resolution of ∼2 μm, as well as optical sectioning capability of ∼7 μm. The varifocal Moirémetalens with ultrathin size and compact design may replace its counterpart in any optical system that requires a focus-tunable lens, such as optical coherence tomography 50 and microendoscopy 19 for in vivo imaging.…”

Section: ■ Conclusionmentioning

confidence: 99%

Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

et al. 2021

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Fluorescence microscopy with optical sectioning capabilities is extensively utilized in biological research to obtain three-dimensional structural images of volumetric samples. Tunable lenses have been applied in microscopy for axial scanning to acquire multiplane images. However, images acquired by conventional tunable lenses suffer from spherical aberration and distortions. Here, we design, fabricate, and implement a dielectric Moirémetalens for fluorescence imaging. The Moirémetalens consists of two complementary phase metasurfaces, with variable focal length, ranging from ∼10 to ∼125 mm at 532 nm by tuning mutual angles. In addition, a telecentric configuration using the Moirémetalens is designed for high-contrast multiplane fluorescence imaging. The performance of our system is evaluated by optically sectioned images obtained from HiLo illumination of fluorescently labeled beads, as well as ex vivo mice intestine tissue samples. The compact design of the varifocal metalens may find important applications in fluorescence microscopy and endoscopy for clinical purposes.

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Section: ■ Conclusionmentioning

confidence: 99%

Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

et al. 2021

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“…However, it allows only one-dimensional magnification and is further limited when the host index is not small due to the loss of negative spatial frequencies. In many ways this is not entirely surprising, as dielectric prisms are known as dispersive tools for exciting surface plasmons [20] or for frustrated total internal reflection tomography [37], more so than they are for imaging. Here we explore whether hyperprism applications mimicking a conventional prism, tunably coupling free-space plane waves to high-k modes, are more promising.…”

Section: Applications Of High-k Mode Excitationmentioning

confidence: 99%

“…The sample is thus illuminated by only the evanescent field, which can allow for high longitudinal resolution. By scanning the angle of incidence and thus the penetration depth, a three-dimensional image with subwavelength longitudinal resolution can be reconstructed [37,44]. Total internal reflection microscopy is particularly useful to image within highly absorbing samples, for example, in water at THz frequencies [45].…”

Section: B Total Internal Reflection Microscopy and Tomographymentioning

confidence: 99%

Analysis of a hyperprism for exciting high- k modes and subdiffraction imaging

et al. 2019

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We study the effect of resonances on the ability of prisms made of hyperbolic metamaterials in the canalization regime (such as wire array media) to couple evanescent high spatial frequencies (high-k modes) to low spatial frequencies that propagate in the far-field zone. Using simple analytical models, we calculate the far-field propagation from the hyperprism. The resonant nature of the metal wire segments within the prism yields a transmission function identical to that of a grating, but with periodicity proportional to the wavelength, making the hyperprism function like a nondispersive grating. Numerically compensating the effect of resonances allows the hyperprism to be used as a one-dimensional imaging device able to resolve feature sizes below the diffraction limit if the host medium has a low refractive index. Furthermore, the hyperprism enables coupling of propagating plane waves to a range of high-k modes that can be increased by increasing the angle of the prism. We quantify how this tunable, nondispersive excitation of high-k modes opens up possibilities for new experimental approaches for coupling to plasmonic systems and for increased axial resolution in total internal reflection imaging, in particular in the terahertz spectrum.

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“…On the other hand, fluorescence microscopy techniques such as wide-field microscopy, confocal microscopy and most of super-resolution (SR) microscopy exhibited axial resolution inferior to the lateral axis. By rapidly switching among multiple incident angles of the TIRF illumination (MA-TIRF), it has been shown that an axial resolution of ~50 nm is possible in live cells [1,2]. However, given that raw images are always convolution of fluorescence emission image with the point spread function (PSF) of the microscopy, the lateral resolution in previous studies did not reach the diffraction limit yet, as neither method deblurred the raw image with a deconvolution step.…”

Section: Introductionmentioning

confidence: 99%

One-step deconvolution for multi-angle TIRF microscopy with enhanced resolution

Fan

Huang

et al. 2019

Biomed. Opt. Express

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Total internal reflection fluorescence microscopy (TIRF microscopy) uses a rapid decay of evanescent waves to excite fluorophores within several hundred nanometers (nm) beneath the plasma membrane, which can effectively suppress excitation of fluorescence signals in the deep layers. From image stacks obtained with a plurality of different incident angles, a three-dimensional spatial structure of the observed sample can be reconstructed by a Multi-Angle-TIRF (MA-TIRF) algorithm that provides an axial resolution of ~50 nm. Taking into account the point spread function (PSF) of the TIRF microscopes, we further increase its lateral resolution by introducing a fast deconvolution algorithm into the reconstruction of MA-TIRF data (DMA-TIRF), which is approached in just one step of minimizing the reconstruction function. We also introduce a TV regularization term in the deconvolution algorithm to suppress artifacts induced by the excessive noise. Therefore, based on the hardware of existing MA-TIRF microscopes, the proposed DMA-TIRF algorithm has achieved lateral and axial resolutions of ~200 and ~50 nm, respectively.

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Axial super-resolution evanescent wave tomography

Cited by 12 publications

References 29 publications

Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

Varifocal Metalens for Optical Sectioning Fluorescence Microscopy

Analysis of a hyperprism for exciting high- k modes and subdiffraction imaging

One-step deconvolution for multi-angle TIRF microscopy with enhanced resolution

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