Enhancing MINFLUX 3D imaging precision by vortex interference.

A new acquisition framework for MINFLUX super-resolution microscopy is proposed, termed Vortex Interference MINFLUX (viMINFLUX). From our analysis, we showed that by utilizing vortex interference, the scan range and phase shift mutually modulate MINFLUX precision, resulting in a precision enhancement by a factor of two or more for the same scan range. We further showed that vortex interference can be extended to 3D imaging, whereby 3D viMINFLUX provides for nearly isotropic 3D precision, resulting in a two-fold improvement in lateral precision and a five-fold enhancement in axial precision compared to conventional 3D MINFLUX techniques.

Ultra high-speed single-molecule fluorescence imaging.

In two articles in this issue, Fujiwara et al. developed an ultrasensitive high-speed camera capable of single-molecule fluorescence imaging at a microsecond timescale (2023. J.

Lattice light sheets generated with a firmly arranged dielectric regular hexagonal pyramid array.

We present a firmly arranged dielectric regular hexagonal pyramid array to generate lattice light sheets with high conversion efficiency and low stray light. Both the size and working distance of the lattice light sheets can be modulated by changing the structural parameters. We experimentally recorded the lattice light sheets illumination, which is consistent with the corresponding simulation.

Dynamic imaging of zebrafish heart with multi-planar light sheet microscopy.

Light sheet fluorescence microscopy has become a research hotspot in biomedicine because of low phototoxicity, high speed, and high resolution. However, the conventional methods to acquire three-dimensional spatial information are mainly based on scanning, which inevitably increases photodamage and is not real-time. Here, we propose a method to generate controllable multi-planar illumination with a dielectric isosceles triangular array and a design of multi-planar light sheet fluorescence microscopy system.

All-Dielectric Meta-Surface for Multispectral Photography by Theta Modulation.

The traditional theta modulator encodes input information by superimposing Ronchi sub-gratings, which is extremely easy to cause spatial channel overlap that results in bands mixing. In this case, we present an all-dielectric theta modulation meta-surface with a new encoding method, which separates red, green, blue, and achromatic spatial channels on the focal plane. The meta-surface ensures that the positions of focal points are relatively consistent while focusing energy into the sub-wavelength regions.