Combined Hardware and Computational Optical Wavefront Correction

Overview

Journal Biomed Opt Express

Specialty Radiology

Date 2018 Sep 28

PMID 30258673

Citations 11

Authors

Fredrick A South

Kazuhiro Kurokawa

Zhuolin Liu

Yuan-Zhi Liu

Donald T Miller

Stephen A Boppart

Affiliations

Soon will be listed here.

Abstract

In many optical imaging applications, it is necessary to overcome aberrations to obtain high-resolution images. Aberration correction can be performed by either physically modifying the optical wavefront using hardware components, or by modifying the wavefront during image reconstruction using computational imaging. Here we address a longstanding issue in computational imaging: photons that are not collected cannot be corrected. This severely restricts the applications of computational wavefront correction. Additionally, performance limitations of hardware wavefront correction leave many aberrations uncorrected. We combine hardware and computational correction to address the shortcomings of each method. Coherent optical backscattering data is collected using high-speed optical coherence tomography, with aberrations corrected at the time of acquisition using a wavefront sensor and deformable mirror to maximize photon collection. Remaining aberrations are corrected by digitally modifying the coherently-measured wavefront during imaging reconstruction. This strategy obtains high-resolution images with improved signal-to-noise ratio of human photoreceptor cells with more complete correction of ocular aberrations, and increased flexibility to image at multiple retinal depths, field locations, and time points. While our approach is not restricted to retinal imaging, this application is one of the most challenging for computational imaging due to the large aberrations of the dilated pupil, time-varying aberrations, and unavoidable eye motion. In contrast with previous computational imaging work, we have imaged single photoreceptors and their waveguide modes in fully dilated eyes with a single acquisition. Combined hardware and computational wavefront correction improves the image sharpness of existing adaptive optics systems, and broadens the potential applications of computational imaging methods.

Citing Articles

Computational approach for correcting defocus and suppressing speckle noise in line-field optical coherence tomography images.

Abbasi N, Chen K, Wong A, Bizheva K Biomed Opt Express. 2024; 15(9):5491-5504.

PMID: 39296416 PMC: 11407272. DOI: 10.1364/BOE.530569.

Evolution of adaptive optics retinal imaging [Invited].

Williams D, Burns S, Miller D, Roorda A Biomed Opt Express. 2023; 14(3):1307-1338.

PMID: 36950228 PMC: 10026580. DOI: 10.1364/BOE.485371.

The Development and Clinical Application of Innovative Optical Ophthalmic Imaging Techniques.

Alexopoulos P, Madu C, Wollstein G, Schuman J Front Med (Lausanne). 2022; 9:891369.

PMID: 35847772 PMC: 9279625. DOI: 10.3389/fmed.2022.891369.

Computational refocusing of Jones matrix polarization-sensitive optical coherence tomography and investigation of defocus-induced polarization artifacts.

Zhu L, Makita S, Oida D, Miyazawa A, Oikawa K, Mukherjee P Biomed Opt Express. 2022; 13(5):2975-2994.

PMID: 35774308 PMC: 9203103. DOI: 10.1364/BOE.454975.

Label-free metabolic and structural profiling of dynamic biological samples using multimodal optical microscopy with sensorless adaptive optics.

Iyer R, Sorrells J, Yang L, Chaney E, Spillman Jr D, Tibble B Sci Rep. 2022; 12(1):3438.

PMID: 35236862 PMC: 8891278. DOI: 10.1038/s41598-022-06926-w.

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