Vector of Motion Measurements in the Living Cochlea Using a 3D OCT Vibrometry System

Overview

Journal Biomed Opt Express

Specialty Radiology

Date 2022 May 6

PMID 35519276

Authors

Wihan Kim

Derek Liu

SangMin Kim

Kumara Ratnayake

Frank Macias-Escriva

Scott Mattison

John S Oghalai

Brian E Applegate

Affiliations

Soon will be listed here.

Abstract

Optical coherence tomography (OCT) has become an important tool for measuring the vibratory response of the living cochlea. It stands alone in its capacity to measure the intricate motion of the hearing organ through the surrounding otic capsule bone. Nevertheless, as an extension of phase-sensitive OCT, it is only capable of measuring motion along the optical axis. Hence, measurements are 1-D. To overcome this limitation and provide a measure of the 3-D vector of motion in the cochlea, we developed an OCT system with three sample arms in a single interferometer. Taking advantage of the long coherence length of our swept laser, we depth (frequency) encode the three channels. An algorithm to depth decode and coregister the three channels is followed by a coordinate transformation that takes the vibrational data from the experimental coordinate system to Cartesian or spherical polar coordinates. The system was validated using a piezo as a known vibrating element that could be positioned at various angles. The angular measurement on the piezo was shown to have an RMSE of ≤ 0.30° (5.2 mrad) with a standard deviation of the amplitude of ≤ 120 pm. Finally, we demonstrate the system for imaging by measuring the vector of motion over a volume image in the apex of the mouse cochlea.

Citing Articles

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