Shrinking endoscopes with metal-optical fibers

Scientists from the University of Washington have developed a novel technique for reducing the rigid tip length of endoscopes.

Edited by Grace Koennecke

A meta-optic is optimized for integration with the coherent fiber bundle, whereas the individual fiber cores are taken as the imaging limitation. The meta-optical fiber endoscope (MOFIE) achieves a reduced tip length while maintaining a wide field of view of 22.5° and a large DoF exceeding 30mm, compared with a traditional gradient-index (GRIN) lens.
PHOTO COURTESY OF JOHANNES E. FRÖCH, LUOCHENG HUANG, QUENTIN A.A. TANGUY, SHANE COLBURN, ALAN ZHAN, ANDREA RAVAGLI, ERIC J. SEIBEL, KARL BÖHRINGER, AND ARKA MAJUMDAR.

Ultra-compact, agile endoscopes with a large field of view (FoV), long depth of field (DoF), and short rigid tip length are essential for developing minimally invasive operations and new experimental surgeries. As these fields develop, the requirement for miniaturization and increased precision become progressively demanding. In existing endoscopes, rigid tip length is a fundamental limitation of the device’s agility within small tortuous ducts, such as an artery. It’s primarily constrained by the size of the optical elements required for imaging. Thus, alternative solutions are urgently needed to reduce the tip length.

In a new paper published in eLight, scientists led by Dr. Johannes Fröch and Prof. Arka Majumdar from the University of Washington developed a novel technique for reducing the rigid tip length.

Existing solutions include lensless and computational imaging with single fibers or coherent fiber bundles. However, these are typically limited to a short working distance and often extremely sensitive to bending and twisting of the optical fiber, affecting or even precluding accurate computational reconstruction.

Flat meta-optics are an emerging and versatile idea in the photonics community to create miniaturized optical elements. These are sub-wavelength diffractive optical elements composed of nano-scale scatterer arrays. They’re designed to shape an incident wavefront’s phase, amplitude, and spectral response. Such ultrathin flat optics not only dramatically shrink the size of traditional optics, but can also combine multiple functionalities in a single surface.

Flat meta-optics are compatible with high-volume semiconductor manufacturing technology and can create disposable optics. These properties inspired researchers to explore the potential of meta-optics for endoscopy, including fiber-integrated endoscopy, side-viewing single fiber scanning endoscopy, and scanning fiber forward-viewing endoscopy.

In this work, the research team demonstrated an inverse-designed meta-optic optimized to capture real-time full color scenes with a 1mm diameter coherent fiber bundle. The meta-optic enables operations at an FoV of 22.5°, a DoF of >30mm (exceeding 300% of the nominal design working distance) and a minimum rigid tip length of only ~2.5mm. This is a 33% tip length reduction compared to a traditional commercial gradient-index (GRIN) lens integrated fiber bundle endoscope. This is due to the shorter focal length and the ultrathin nature of the meta-optic.

At the same time, comparable imaging performance and working distance are maintained. To achieve exceptional FoV, DoF, and color performance of the meta-optical fiber endoscope (MOFIE), the research team approached this design problem from a system-level perspective.

By ensuring that the meta-optic has a mean time to failure (MTF) within the limitations of the fiber bundle, the research team achieved full-color operation without requiring a computational reconstruction step, thus facilitating real-time operation. The team emphasized that its design approach fundamentally differs from traditional achromatic metalens design efforts. The researchers formulated an optimization problem to find the best solution for full-color imaging. This was instead of trying to achieve diffraction-limited performance in all wavelengths, which may pose a physically unsolvable problem.

This approach is important because it’s not limited to this particular system. It can be extended to larger aperture sizes and support computational post-processing steps. To highlight this, they also demonstrated an example of a meta-optic with a 1cm aperture and full-color imaging under ambient light conditions.

University of Washington
https://www.washington.edu

Changchun Institute of Optics, Fine Mechanics and Physics
http://english.ciomp.cas.cn

August 2023
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