Zhu Shanshan, Cui Xiaoyu, Xu Wenbin, Chen Shuo, Qian Wei
Sino-Dutch Biomedical and Information Engineering School, Northeastern University Shenyang China 110169
Key Laboratory of Data Analytics and Optimization for Smart Industry (Northeastern University), Ministry of Education China.
RSC Adv. 2019 Mar 25;9(17):9500-9508. doi: 10.1039/c9ra00327d. eCollection 2019 Mar 22.
Raman spectroscopy is a label-free and non-destructive spectroscopic technique that has been explored for bacterial identification. However, noise often interferes with the interesting Raman peaks because the Raman signal is inherently weak, especially for bacterial samples. Although this problem can be solved by increasing the exposure time or the power of the excitation laser, a longer acquisition time is required or the risk of sample damage is increased. In contrast, short exposure time and low laser power often lead to inadequate acquisition of Raman scattering, in which the Raman spectra with low signal-to-noise ratio (SNR) is difficult to be further analyzed. In order to quickly and accurately characterize biological samples by using low SNR Raman measurements, a weighted spectral reconstruction based method was developed and tested on Raman spectra with low SNR from 20 bacterial samples of two species. Principal component analysis followed by support vector machine was applied on the reference Raman spectra and the spectra recovered from the low SNR Raman measurements by the proposed method, the traditional spectral reconstruction method, and four other commonly used de-noising methods for the discrimination of bacterial species. The results showed that a classification accuracy of 90% was achieved based on our method, which was comparable to that of the reference Raman spectra and showed significant advantages over other spectral recovery methods. Therefore, the weighted spectral reconstruction method can preserve the most biochemical information for the bacterial species' identification while removing the noise from the low SNR Raman spectra, in which the advantages of lesser sample damage and shorter acquisition time would promote wider biomedical applications of Raman spectroscopy.
拉曼光谱是一种无需标记且非破坏性的光谱技术,已被用于细菌鉴定研究。然而,由于拉曼信号本身较弱,尤其是对于细菌样本,噪声常常干扰感兴趣的拉曼峰。虽然这个问题可以通过增加曝光时间或激发激光的功率来解决,但这需要更长的采集时间或增加样本受损的风险。相比之下,短曝光时间和低激光功率往往会导致拉曼散射采集不足,其中信噪比(SNR)低的拉曼光谱难以进一步分析。为了利用低信噪比的拉曼测量快速准确地表征生物样本,开发了一种基于加权光谱重建的方法,并在来自两个物种的20个细菌样本的低信噪比拉曼光谱上进行了测试。对参考拉曼光谱以及通过所提出的方法、传统光谱重建方法和其他四种常用去噪方法从低信噪比拉曼测量中恢复的光谱应用主成分分析,然后进行支持向量机分析,以区分细菌物种。结果表明,基于我们的方法实现了90%的分类准确率,这与参考拉曼光谱的准确率相当,并且相对于其他光谱恢复方法具有显著优势。因此,加权光谱重建方法在从低信噪比拉曼光谱中去除噪声的同时,可以保留用于细菌物种鉴定的最多生化信息,其中样本损伤较小和采集时间较短的优势将促进拉曼光谱在生物医学领域更广泛的应用。
