Parallel imaging with phonon microscopy using a multi-core fibre bundle detection

In this paper, we show a proof-of-concept method to parallelise phonon microscopy measurements for cell elasticity imaging by demonstrating a 3-fold increase in acquisition speed which is limited by current acquisition hardware. Phonon microscopy is based on time-resolved Brillouin scattering, which...

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Bibliographic Details
Published in:Photoacoustics (Munich) 2023-06, Vol.31, p.100493, Article 100493
Main Authors: Fuentes-Domínguez, Rafael, Yao, Mengting, Hardiman, William, La Cavera III, Salvatore, Setchfield, Kerry, Pérez-Cota, Fernando, Smith, Richard J., Clark, Matt
Format: Article
Language:English
Subjects:
Parallel measurements
Phonon microscopy
Picosecond ultrasonics
Time-domain Brillouin scattering
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Summary:In this paper, we show a proof-of-concept method to parallelise phonon microscopy measurements for cell elasticity imaging by demonstrating a 3-fold increase in acquisition speed which is limited by current acquisition hardware. Phonon microscopy is based on time-resolved Brillouin scattering, which uses a pump–probe method with asynchronous optical sampling (ASOPS) to generate and detect coherent phonons. This enables access to the cell elasticity via the Brillouin frequency with sub-optical axial resolution. Although systems based on ASOPS are typically faster compared to the ones built with a mechanical delay line, they are still very slow to study real time changes at the cellular level. Additionally, the biocompatibility is reduced due to long light exposure and scanning time. Using a multi-core fibre bundle rather than a single channel for detection, we acquire 6 channels simultaneously allowing us to speed-up measurements, and open a way to scale-up this method. [Display omitted] •Proof-of-concept method to parallelise phonon microscopy cell elasticity measurements•A multi-core fibre bundle is used to detect 6 channels in parallel•A 3-fold increase in acquisition speed is achieved limited by the electronics speed.
ISSN:2213-5979
2213-5979
DOI:10.1016/j.pacs.2023.100493