A Universal and Accurate Method for Easily Identifying Components in Raman Spectroscopy Based on Deep Learning

Fan, Xiaqiong; Wang, Yue; Yu, Chuanxiu; Lv, Yuanxia; Zhang, Ye; Yang, Qiong; Wen, Ming; Lü, Hongmei; Zhang, Zhimin

doi:10.1021/acs.analchem.2c03853

Cited by 22 publications

(13 citation statements)

References 53 publications

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“…The backbone is stacked by four identical blocks whose internal structure is shown in Figure B. Eventually, by comparing the outcome, the global average pooling, instead of spatial pyramid pooling, is used by classifier to integrate all features and output probability distributions for each category via a fully connected layer (FC). The detailed processes of Patchify and the backbone are as follows.…”

Section: Methodsmentioning

confidence: 99%

Patch-Based Convolutional Encoder: A Deep Learning Algorithm for Spectral Classification Balancing the Local and Global Information

Lu,

Wang,

Tang

et al. 2024

Anal. Chem.

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Molecular vibrational spectroscopies, including infrared absorption and Raman scattering, provide molecular fingerprint information and are powerful tools for qualitative and quantitative analysis. They benefit from the recent development of deep-learning-based algorithms to improve the spectral, spatial, and temporal resolutions. Although a variety of deep-learning-based algorithms, including those to simultaneously extract the global and local spectral features, have been developed for spectral classification, the classification accuracy is still far from satisfactory when the difference becomes very subtle. Here, we developed a lightweight algorithm named patch-based convolutional encoder (PACE), which effectively improved the accuracy of spectral classification by extracting spectral features while balancing local and global information. The local information was captured well by segmenting the spectrum into patches with an appropriate patch size. The global information was extracted by constructing the correlation between different patches with depthwise separable convolutions. In the five open-source spectral data sets, PACE achieved a state-of-the-art performance. The more difficult the classification, the better the performance of PACE, compared with that of residual neural network (ResNet), vision transformer (ViT), and other commonly used deep learning algorithms. PACE helped improve the accuracy to 92.1% in Raman identification of pathogen-derived extracellular vesicles at different physiological states, which is much better than those of ResNet (85.1%) and ViT (86.0%). In general, the precise recognition and extraction of subtle differences offered by PACE are expected to facilitate vibrational spectroscopy to be a powerful tool toward revealing the relevant chemical reaction mechanisms in surface science or realizing the early diagnosis in life science.

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Section: Methodsmentioning

confidence: 99%

Patch-Based Convolutional Encoder: A Deep Learning Algorithm for Spectral Classification Balancing the Local and Global Information

Lu,

Wang,

Tang

et al. 2024

Anal. Chem.

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“…56,57 Specifically, Fan et al proposed the concept of a DNA "contrary logic pair" (CLP) to try to reduce the time/cost of molecular computing based on functional nucleic acids. [58][59][60] After that, electrochemical and electro-chemiluminescent CLPs were further fabricated. 61,62 However, to the best of our knowledge, nanozyme-based CLP systems have barely been reported.…”

Section: Contrary Logic Pairs Based On the Fe 3 Ni-mof-nh 2 Nanozymementioning

confidence: 99%

A facile, low-cost bimetallic iron–nickel MOF nanozyme-propelled ratiometric fluorescent sensor for highly sensitive and selective uric acid detection and its smartphone application

Han,

Zhang,

et al. 2024

Nanoscale

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“…Recent advances in machine learning (ML), especially deep learning (DL), offer an exciting opportunity to reshape scientic research within the domains of chemical and materials science. [6][7][8] This is particularly evident in facilitating rapid analysis of intricate data, including but not limited to XRD, 9,10 IR/FTIR, 11,12 Raman, 13,14 and MS data. 15,16 For example, Oviedo and coworkers have demonstrated deployment of convolutional neural networks (CNNs) to effectively classify the dimensionalities and space groups of thin-lm metal halides from XRD spectra.…”

Section: Introductionmentioning

confidence: 99%

An interpretable and transferrable vision transformer model for rapid materials spectra classification

Chen,

Xie,

et al. 2024

Digital Discovery

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A Universal and Accurate Method for Easily Identifying Components in Raman Spectroscopy Based on Deep Learning

Cited by 22 publications

References 53 publications

Patch-Based Convolutional Encoder: A Deep Learning Algorithm for Spectral Classification Balancing the Local and Global Information

Patch-Based Convolutional Encoder: A Deep Learning Algorithm for Spectral Classification Balancing the Local and Global Information

A facile, low-cost bimetallic iron–nickel MOF nanozyme-propelled ratiometric fluorescent sensor for highly sensitive and selective uric acid detection and its smartphone application

An interpretable and transferrable vision transformer model for rapid materials spectra classification

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