成像优化的受激拉曼散射模拟

IF 1.9 4区 物理与天体物理 Q3 OPTICS
Liron Zada, Bart Fokker, Heather A. Leslie, A. Dick Vethaak, Johannes F. de Boer, Freek Ariese
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引用次数: 6

摘要

开发了具有锁相放大器(LIA)检测的受激拉曼散射显微镜(SRS)成像系统仿真程序。SRS是一种基于振动拉曼截面作为对比机制的成像技术,可以实现快速、无标记的成像。大多数SRS实现是基于调制信号的LIA检测。然而,在选择LIA参数设置以优化采集速度或图像质量时,构建和操作此类SRS设置仍然面临挑战。此外,样品的类型,例如稀疏样品与密集填充样品,所需的分辨率以及拉曼截面和激光功率都会影响参数的选择。利用仿真程序求出这些最优参数。利用单个激光器(泵浦激光器和斯托克斯激光器)的焦斑直径来估计SRS信号的有效焦斑和(光学)空间分辨率。通过校准信号和噪声在已知分子的SRS系统中的传播,我们估计了输入到LIA的信号和噪声。我们使用低通滤波器模型来模拟LIA行为,以找到最优参数(即滤波器阶数和时间常数)。对图像质量(表示为噪声比对比)或采集时间进行了优化。首先确定目标对象的大小作为所需分辨率的度量。仿真输出包括LIA参数、像素驻留时间和噪比对比。在第二个模拟中,我们基于与最优设置模拟相同的原理评估SRS成像,即信号通过成像系统和LIA检测传播。将模拟图像与聚苯乙烯珠的实验SRS图像进行了比较。最后,使用相同的软件模拟多路SRS成像。在这项研究中,我们模拟了一个六通道频率编码多路SRS系统与六个LIA通道解调。我们评估了通道间串扰作为所选LIA参数的函数,这在多路SRS成像中也需要考虑。这些优化对比度噪声比、采集速度、分辨率和串扰的程序将有助于操作受激拉曼散射成像装置,以及设计新的装置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Stimulated Raman scattering simulation for imaging optimization

Stimulated Raman scattering simulation for imaging optimization

Two simulation programs of a stimulated Raman scattering microscopy (SRS) imaging system with lock-in amplifier (LIA) detection were developed. SRS is an imaging technique based on the vibrational Raman cross-section as the contrast mechanism and enables fast, label-free imaging. Most SRS implementations are based on LIA detection of a modulated signal. However, building and operating such SRS set-ups still poses a challenge when selecting the LIA parameter settings for optimized acquisition speed or image quality. Moreover, the type of sample, e.g. a sparse sample vs. a densely packed sample, the required resolution as well as the Raman cross-section and the laser powers affect the parameter choice.

A simulation program was used to find these optimal parameters. The focal spot diameters of the individual lasers (pump and Stokes) were used to estimate the effective SRS signal focal spot and the (optical) spatial resolution. By calibrating the signal and noise propagation through an SRS system for a known molecule, we estimated the signal and noise input to the LIA. We used a low pass filter model to simulate the LIA behavior in order to find the optimal parameters (i.e. filter order and time constant).

Optimization was done for either image quality (expressed as contrast to noise ratio) or acquisition time. The targeted object size was first determined as a measure for the required resolution. The simulation output consisted of the LIA parameters, pixel dwell time and contrast to noise ratio.

In a second simulation we evaluated SRS imaging based on the same principles as the optimal setting simulation, i.e. the signals were propagated through an imaging system and LIA detection. The simulated images were compared to experimental SRS images of polystyrene beads.

Finally, the same software was used to simulate multiplexed SRS imaging. In this study we modeled a six-channel frequency-encoded multiplexed SRS system demodulated with six LIA channels. We evaluated the inter-channel crosstalk as a function of chosen LIA parameters, which in multiplex SRS imaging also needs to be considered.

These programs to optimize the contrast to noise ratio, acquisition speed, resolution and crosstalk will be useful for operating stimulated Raman scattering imaging setup, as well as for designing novel setups.

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来源期刊
CiteScore
2.40
自引率
0.00%
发文量
12
审稿时长
5 weeks
期刊介绍: Rapid progress in optics and photonics has broadened its application enormously into many branches, including information and communication technology, security, sensing, bio- and medical sciences, healthcare and chemistry. Recent achievements in other sciences have allowed continual discovery of new natural mysteries and formulation of challenging goals for optics that require further development of modern concepts and running fundamental research. The Journal of the European Optical Society – Rapid Publications (JEOS:RP) aims to tackle all of the aforementioned points in the form of prompt, scientific, high-quality communications that report on the latest findings. It presents emerging technologies and outlining strategic goals in optics and photonics. The journal covers both fundamental and applied topics, including but not limited to: Classical and quantum optics Light/matter interaction Optical communication Micro- and nanooptics Nonlinear optical phenomena Optical materials Optical metrology Optical spectroscopy Colour research Nano and metamaterials Modern photonics technology Optical engineering, design and instrumentation Optical applications in bio-physics and medicine Interdisciplinary fields using photonics, such as in energy, climate change and cultural heritage The journal aims to provide readers with recent and important achievements in optics/photonics and, as its name suggests, it strives for the shortest possible publication time.
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