Using volumetric optical coherence tomography to achieve spatially resolved organ of Corti vibration measurements

Optical coherence tomography (OCT) has become a powerful tool for measuring vibrations within the organ of Corti complex (OCC) in cochlear mechanics experiments. However, the one-dimensional nature of OCT measurements, combined with experimental and anatomical constraints, make these data ambiguous: Both the relative positions of measured structures and their orientation relative to the direction of measured vibrations are not known a priori. We present a method by which these measurement features can be determined via the use of a volumetric OCT scan to determine the relationship between the imaging/measurement axes and the canonical anatomical axes. We provide evidence that the method is functional by replicating previously measured radial vibration patterns of the basilar membrane (BM). We used the method to compare outer hair cell and BM vibration phase in the same anatomical cross section (but different optical cross sections), and found that outer hair cell region vibrations lead those of the BM across the entire measured frequency range. In contrast, a phase lead is only present at low frequencies in measurements taken within a single optical cross section. Relative phase is critical to the workings of the cochlea, and these results emphasize the importance of anatomically oriented measurement and analysis. (C) 2022 Acoustical Society of America.

Automated summary

Optical coherence tomography (OCT) is a powerful tool for measuring vibrations within the organ of Corti complex (OCC) in cochlear mechanics experiments. A method using volumetric OCT scan has been presented to determine measurement features and relationship between imaging/measurement axes and anatomical axes. Results show that outer hair cell vibrations lead those of the basilar membrane (BM) across the entire measured frequency range, emphasizing the importance of anatomically oriented measurement and analysis.