Two-dimensional electro-optical multiphoton microscopy.

IF 4.8 2区医学 Q1 NEUROSCIENCES

Neurophotonics Pub Date : 2024-04-01 Epub Date: 2024-06-05 DOI:10.1117/1.NPh.11.2.025005

Deano M Farinella, Samuel Stanek, Harishankar Jayakumar, Zachary L Newman, Jacob Gable, James Leger, Aaron Kerlin

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引用次数: 0

Abstract

Significance: The development of genetically encoded fluorescent indicators of neural activity with millisecond dynamics has generated demand for ever faster two-photon (2P) imaging systems, but acoustic and mechanical beam scanning technologies are approaching fundamental limits. We demonstrate that potassium tantalate niobate (KTN) electro-optical deflectors (EODs), which are not subject to the same fundamental limits, are capable of ultrafast two-dimensional (2D) 2P imaging in vivo.

Aim: To determine if KTN-EODs are suitable for 2P imaging, compatible with 2D scanning, and capable of ultrafast in vivo imaging of genetically encoded indicators with millisecond dynamics.

Approach: The performance of a commercially available KTN-EOD was characterized across a range of drive frequencies and laser parameters relevant to in vivo 2P microscopy. A second KTN-EOD was incorporated into a dual-axis scan module, and the system was validated by imaging signals in vivo from ASAP3, a genetically encoded voltage indicator.

Results: Optimal KTN-EOD deflection of laser light with a central wavelength of 960 nm was obtained up to the highest average powers and pulse intensities tested (power: 350 mW; pulse duration: 118 fs). Up to 32 resolvable spots per line at a 560 kHz line scan rate could be obtained with single-axis deflection. The complete dual-axis EO 2P microscope was capable of imaging a $13 μ m$ by $13 μ m$ field-of-view at over 10 kHz frame rate with $\sim 0.5 μ m$ lateral resolution. We demonstrate in vivo imaging of neurons expressing ASAP3 with high temporal resolution.

Conclusions: We demonstrate the suitability of KTN-EODs for ultrafast 2P cellular imaging in vivo, providing a foundation for future high-performance microscopes to incorporate emerging advances in KTN-based scanning technology.

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二维电子光学多光子显微镜。

意义重大：具有毫秒级动态的神经活动基因编码荧光指示器的开发，催生了对更快的双光子（2P）成像系统的需求，但声学和机械光束扫描技术已接近基本极限。我们证明，钽酸铌酸钾（KTN）电子光学偏转器（EOD）不受同样的基本限制，能够在体内进行超快二维（2D）双光子成像。目的：确定 KTN-EOD 是否适用于双光子成像，是否与二维扫描兼容，是否能够在体内对具有毫秒级动态的基因编码指标进行超快成像：方法：在与活体 2P 显微镜相关的驱动频率和激光参数范围内，对商用 KTN-EOD 的性能进行了鉴定。在双轴扫描模块中加入了第二个 KTN-EOD，并通过对基因编码电压指示器 ASAP3 的体内信号成像对系统进行了验证：结果：在测试的最高平均功率和脉冲强度（功率：350 mW；脉冲持续时间：118 fs）条件下，中心波长为 960 nm 的 KTN-EOD 可获得最佳激光偏转。在 560 kHz 的行扫描速率下，单轴偏转最多可获得每行 32 个可分辨光斑。完整的双轴 EO 2P 显微镜能够以超过 10 kHz 的帧速率对 13 μm x 13 μm 的视场进行成像，横向分辨率为 0.5 μm。我们展示了表达 ASAP3 的神经元在体内的高时间分辨率成像：我们证明了 KTN-EODs 适用于体内超快 2P 细胞成像，为未来高性能显微镜采用基于 KTN 的新兴扫描技术奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neurophotonics Neuroscience-Neuroscience (miscellaneous)

CiteScore

7.20

自引率

11.30%

发文量

114

审稿时长

21 weeks

期刊介绍： At the interface of optics and neuroscience, Neurophotonics is a peer-reviewed journal that covers advances in optical technology applicable to study of the brain and their impact on the basic and clinical neuroscience applications.