Litcius/Paper detail

Metaoptics for aberration correction in microendoscopy

Susan Thomas, Jerin Geogy George, Francesco Ferranti, Shanti Bhattacharya

2024Optics Express12 citationsDOIOpen Access PDF

Abstract

Compact and minimally invasive scanning fiber endoscopy probes with micron-level resolution have great potential in detailed tissue interrogation and early disease diagnosis, which are key applications of confocal reflectance imaging at visible wavelengths. State-of-the-art imaging probes commonly employ refractive lens triplets or gradient refractive index (GRIN) lenses as the micro-objective. However, off-axis aberration emerges as a critical factor affecting resolution, especially at the extremities of the imaging field. In response to this challenge, we propose what we believe to be a novel design integrating a metasurface with the GRIN micro-objective to address optical aberrations during beam scan. The metasurface acts as a corrector element for optical aberrations in a fiber-scanning endoscope using the same fiber for excitation and collection. Modeling such hybrid refractive-metasurface designs requires the coupling of simulation techniques across macroscale and nanoscale optics, for which we used an Ansys simulation workflow platform. Operating at a wavelength of 644 nm, this metaoptical element serves as a thin and compact aberration correction surface, ensuring uniform resolution across the entire imaging field. Experimental results from our scanning fiber endoscopy system demonstrate a notable enhancement in optical performance both on-axis and off-axis, achieving a resolution of 3 µm at the center of the imaging field. Impressively, the resolution experiences only a modest degradation by a factor of 0.13 at the edge of the field of view compared to the center.

Topics & Concepts

OpticsGradient-index opticsOptical coherence tomographyLens (geology)Materials scienceRefractive indexOptical fiberChromatic aberrationPhysicsChromatic scaleOptical Coherence Tomography ApplicationsAdvanced Fluorescence Microscopy TechniquesPhotoacoustic and Ultrasonic Imaging