Wavelength-swept spontaneous Raman spectroscopy system improves fiber-based collection efficiency for whole brain tissue classification.

IF 4.8 2区医学 Q1 NEUROSCIENCES

Neurophotonics Pub Date : 2024-04-01 Epub Date: 2024-06-19 DOI:10.1117/1.NPh.11.2.025007

Elahe Parham, Antoine Rousseau, Mireille Quémener, Martin Parent, Daniel C Côté

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引用次数: 0

Abstract

Significance: Raman spectroscopy is a valuable technique for tissue identification, but its conventional implementation is hindered by low efficiency due to scattering. Addressing this limitation, we are further developing the wavelength-swept Raman spectroscopy approach.

Aim: We aim to enhance Raman signal detection by employing a laser capable of sweeping over a wide wavelength range to sequentially excite tissue with different wavelengths, paired with a photodetector featuring a fixed narrow-bandpass filter for collecting the Raman signal at a specific wavelength.

Approach: We experimentally validate our technique using a fiber-based swept-source Raman spectroscopy setup. In addition, simulations are conducted to assess the efficacy of our approach in comparison with conventional spectrometer-based Raman spectroscopy.

Results: Our simulations reveal that the wavelength-swept configuration leads to a significantly stronger signal compared with conventional spectrometer-based Raman spectroscopy. Experimentally, our setup demonstrates an improvement of at least 200× in photon detection compared with the spectrometer-based setup. Furthermore, data acquired from different regions of a fixed monkey brain using our technique achieves 99% accuracy in classification via $k$ -nearest neighbor analysis.

Conclusions: Our study showcases the potential of wavelength-swept Raman spectroscopy for tissue identification, particularly in highly scattering media, such as the brain. The developed technique offers enhanced signal detection capabilities, paving the way for future in vivo applications in tissue characterization.

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波长扫描自发拉曼光谱系统提高了基于光纤的全脑组织分类收集效率。

意义重大：拉曼光谱是一种用于组织鉴定的重要技术，但由于散射导致的低效率，阻碍了拉曼光谱的传统应用。针对这一局限，我们正在进一步开发波长扫描拉曼光谱方法。目的：我们旨在通过使用能够在宽波长范围内扫描的激光器，以不同波长依次激发组织，并搭配具有固定窄带通滤波器的光电探测器，以收集特定波长的拉曼信号，从而增强拉曼信号检测：方法：我们使用基于光纤的扫源拉曼光谱装置对我们的技术进行了实验验证。此外，我们还进行了模拟，以评估我们的方法与传统光谱仪拉曼光谱法的功效：我们的模拟结果表明，与传统的基于光谱仪的拉曼光谱相比，波长扫频配置能产生更强的信号。实验证明，与基于光谱仪的装置相比，我们的装置在光子探测方面至少提高了 200 倍。此外，利用我们的技术从固定猴脑的不同区域获取的数据，通过 k 近邻分析进行分类的准确率达到 99%：我们的研究展示了波长扫描拉曼光谱在组织识别方面的潜力，尤其是在大脑等高散射介质中。所开发的技术具有更强的信号检测能力，为未来组织表征的体内应用铺平了道路。

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.