University of Milan-Bicocca , Department of Physics, Piazza della Scienza 3, 20126 Milano, Italy.
University of Pavia , Department of Brain and Behavioural Sciences, Via Forlanini 6, 27100 Pavia, Italy ; University of Modena and Reggio Emilia , Department of Biomedical, Metabolic and Neural Sciences, Via Campi 287, 41125 Modena, Italy.
Neurophotonics. 2015 Jan;2(1):015005. doi: 10.1117/1.NPh.2.1.015005. Epub 2015 Feb 9.
The optical monitoring of multiple single neuron activities requires high-throughput parallel acquisition of signals at millisecond temporal resolution. To this aim, holographic two-photon microscopy (2PM) based on spatial light modulators (SLMs) has been developed in combination with standard laser scanning microscopes. This requires complex coordinate transformations for the generation of holographic patterns illuminating the points of interest. We present a simpler and fully digital setup (SLM-2PM) which collects three-dimensional two-photon images by only exploiting the SLM. This configuration leads to an accurate placement of laser beamlets over small focal volumes, eliminating mechanically moving parts and making the system stable over long acquisition times. Fluorescence signals are diffraction limited and are acquired through a pixelated detector, setting the actual limit to the acquisition rate. High-resolution structural images were acquired by raster-scanning the sample with a regular grid of excitation focal volumes. These images allowed the selection of the structures to be further investigated through an interactive operator-guided selection process. Functional signals were collected by illuminating all the preselected points with a single hologram. This process is exemplified for high-speed (up to 1 kHz) two-photon calcium imaging on acute cerebellar slices.
多单个神经元活动的光学监测需要以毫秒时间分辨率进行高通量并行信号采集。为此,已经结合标准激光扫描显微镜开发了基于空间光调制器 (SLM) 的全息双光子显微镜 (2PM)。这需要进行复杂的坐标变换,以生成用于照明感兴趣点的全息图案。我们提出了一种更简单且完全数字化的设置 (SLM-2PM),该设置仅通过 SLM 采集三维双光子图像。这种配置导致激光小光束在小焦点体积上的精确放置,消除了机械移动部件,并使系统在长时间采集过程中保持稳定。荧光信号具有衍射极限,并通过像素化探测器进行采集,这为采集速率设置了实际限制。通过以激发焦点体积的规则网格对样品进行光栅扫描来获取高分辨率结构图像。这些图像允许通过交互式操作员引导的选择过程选择要进一步研究的结构。通过用单个全息图照亮所有预选点来收集功能信号。该过程以急性小脑切片上高达 1 kHz 的高速双光子钙成像为例进行了说明。