Deformable mirror-based two-photon microscopy for axial mammalian brain imaging

Peinado, Alba; Bendek, Eduardo; Yokoyama, Sae; Poskanzer, Kira E.

doi:10.1101/736124

Cited by 3 publications

(1 citation statement)

References 33 publications

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“…This is typically achieved by remotely modulating the beam convergence properties upstream of the objective using active optical components. Examples of such solutions are Spatial Light Modulators (SLMs) 11 – 13 , Deformable Mirrors (DMs) 14 , Acousto-Optic Deflectors (AODs) 15 – 17 , lenses with a programmable focal length 18 – 22 or objective-based z-scanning secondary arms 23 – 25 . Among these, active lenses are the simplest configuration to integrate and control.…”

Section: Introductionmentioning

confidence: 99%

Whole brain functional recordings at cellular resolution in zebrafish larvae with 3D scanning multiphoton microscopy

Bruzzone

Chiarello

Albanesi

et al. 2021

Sci Rep

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Optical recordings of neuronal activity at cellular resolution represent an invaluable tool to investigate brain mechanisms. Zebrafish larvae is one of the few model organisms where, using fluorescence-based reporters of the cell activity, it is possible to optically reconstruct the neuronal dynamics across the whole brain. Typically, leveraging the reduced light scattering, methods like lightsheet, structured illumination, and light-field microscopy use spatially extended excitation profiles to detect in parallel activity signals from multiple cells. Here, we present an alternative design for whole brain imaging based on sequential 3D point-scanning excitation. Our approach relies on a multiphoton microscope integrating an electrically tunable lens. We first apply our approach, adopting the GCaMP6s activity reporter, to detect functional responses from retinal ganglion cells (RGC) arborization fields at different depths within the zebrafish larva midbrain. Then, in larvae expressing a nuclear localized GCaMP6s, we recorded whole brain activity with cellular resolution. Adopting a semi-automatic cell segmentation, this allowed reconstructing the activity from up to 52,000 individual neurons across the brain. In conclusion, this design can easily retrofit existing imaging systems and represents a compact, versatile and reliable tool to investigate neuronal activity across the larva brain at high resolution.

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Section: Introductionmentioning

confidence: 99%

Whole brain functional recordings at cellular resolution in zebrafish larvae with 3D scanning multiphoton microscopy

Bruzzone

Chiarello

Albanesi

et al. 2021

Sci Rep

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Light-Based Neuronal Circuit Probing in Living Brains at High Resolution: Constraints and Layouts for Integrating Neuronal Activity Recording and Modulation in Three Dimensions

et al. 2023

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Understanding how the brain orchestrates neuronal activity to finely produce and regulate behavior is an intriguing yet challenging task. In the last years, the progressive refinement of optical techniques and light-based molecular tools allowed to start addressing open questions in cellular and systems neuroscience with unprecedented resolution and specificity. Currently, all-optical experimental protocols for simultaneous recording of the activity of large cell populations with the concurrent modulation of the firing rate at cellular resolution represent an invaluable tool. In this scenario, it is becoming everyday more evident the importance of sampling and probing the circuit mechanisms not just in a single plane, but extending the exploration to the entire volume containing the involved circuit components. Here, we focus on the design principles and the hardware architectures of all-optical approaches allowing for studying the neuronal dynamics at cellular resolution across a volume of the brain.

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Measurement of gain-saturation properties of a Q-switched Nd:YAG laser oscillator with a three-pass amplifier and corresponding beam diagnosis

Pourhashemi

Parvin

Khalilzade

2023

Optik

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Deformable mirror-based two-photon microscopy for axial mammalian brain imaging

Cited by 3 publications

References 33 publications

Whole brain functional recordings at cellular resolution in zebrafish larvae with 3D scanning multiphoton microscopy

Whole brain functional recordings at cellular resolution in zebrafish larvae with 3D scanning multiphoton microscopy

Light-Based Neuronal Circuit Probing in Living Brains at High Resolution: Constraints and Layouts for Integrating Neuronal Activity Recording and Modulation in Three Dimensions

Measurement of gain-saturation properties of a Q-switched Nd:YAG laser oscillator with a three-pass amplifier and corresponding beam diagnosis

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