English

Vortex Interference Enables optimal 3D Interferometric Nanoscopy

Optics 2025-02-20 v2

Abstract

Super-resolution imaging methods that combine interferometric (z) analysis with single-molecule localization microscopy (iSMLM) have achieved ultra-high 3D precision and contributed to the elucidation of important biological ultrastructures. However, their dependence on imaging multiple phase-shifted output channels necessitates complex instrumentation and operation. To solve this problem, we develop an interferometric super-resolution microscope capable of optimal direct axial nanoscopy, termed VILM (Vortex Interference Localization Microscopy). Using a pair of vortex phase plates with opposite orientation for each dual-opposed objective lenses, the detection point-spread functions (PSFs) adopt a bilobed profile whose rotation encodes the axial position. Thus, direct 3D single-molecule coordinate determination can be achieved with a single output image. By reducing the number of output channels to as few as one and utilizing a simple 50:50 beamsplitter, the imaging system is significantly streamlined, while the optimal iSMLM imaging performance is retained, with axial resolution ~2 times better than the lateral. The capability of VILM is demonstrated by resolving the architecture of microtubules and probing the organization of tyrosine-phosphorylated signalling proteins in integrin-based cell adhesions.

Keywords

Cite

@article{arxiv.2409.14033,
  title  = {Vortex Interference Enables optimal 3D Interferometric Nanoscopy},
  author = {Wei Wang and Zengxin Huang and Yilin Wang and Hangfeng Li and Pakorn Kanchanawong},
  journal= {arXiv preprint arXiv:2409.14033},
  year   = {2025}
}
R2 v1 2026-06-28T18:52:12.371Z