A representation learning approach for recovering scatter‐corrected spectra from <scp>Fourier‐transform</scp> infrared spectra of tissue samples

Raulf, Arne Peter; Butke, Joshua; Menzen, Lukas; Küpper, Claus; Großerueschkamp, Frederik; Gerwert, Klaus; Mosig, Axel

doi:10.1002/jbio.202000385

Cited by 6 publications

(7 citation statements)

References 36 publications

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“…37,51–59 In the past few years, deep learning approaches have made their advance in FT-IR spectroscopy. 60–63 Worth noticing is that recently developed deep neural network architectures can successfully approximate complex, often computationally heavy, model-based correction algorithms. 64 The currently available correction algorithms are often optimized for transmission spectra, as the distortions in transflection spectra are in general more severe.…”

Section: Resultsmentioning

confidence: 99%

Attenuated Total Reflection (ATR) Micro-Fourier Transform Infrared (Micro-FT-IR) Spectroscopy to Enhance Repeatability and Reproducibility of Spectra Derived from Single Specimen Organic-Walled Dinoflagellate Cysts

et al. 2021

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The chemical composition of recent and fossil organic-walled dinoflagellate cyst walls and its diversity is poorly understood and analyses on single microscopic specimens are rare. A series of infrared spectroscopic experiments resulted in the proposition of a standardized attenuated total reflection micro-Fourier transform infrared-based method that allows the collection of robust data sets consisting of spectra from individual dinocysts. These data sets are largely devoid of nonchemical artifacts inherent to other infrared spectrochemical methods, which have typically been used to study similar specimens in the past. The influence of sample preparation, specimen morphology and size and spectral data processing steps is also assessed within this methodological framework. As a result, several guidelines are proposed which facilitate the collection and qualitative interpretation of highly reproducible and repeatable spectrochemical data. These, in turn, pave the way for a systematic exploration of dinocyst chemistry and its assessment as a chemotaxonomical tool or proxy.

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Section: Resultsmentioning

confidence: 99%

Attenuated Total Reflection (ATR) Micro-Fourier Transform Infrared (Micro-FT-IR) Spectroscopy to Enhance Repeatability and Reproducibility of Spectra Derived from Single Specimen Organic-Walled Dinoflagellate Cysts

et al. 2021

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“…To obtain more robust models than the composite ones discussed here possible alternative strategies include (1) tuning the encoder-decoder networks with added AMW, substrate and enzyme information (as mentioned above), (2) retraining the AMW prediction on the output from the networks and (3) combining the FTIR networks with AMW prediction modelling for a joint optimization. We remark that for the combined approach (3), exploring the pre-training and fine-tuning strategy [18,19] based on FTIR autoencoders appears fruitful.…”

Section: Predicting Future Amwmentioning

confidence: 99%

“…For process monitoring, Jo et al [14] and Jinadasa et al [15] apply AE for feature/ signal extraction in near-infrared and Raman spectroscopy. In several recent papers [16,17] AEs and/or encoder-decoder networks [18,19] are used for denoising and scattering removal in FTIR spectra or to obtain classifiers for spectral histopathology, for example, Raulf et al [19]. In particular, the networks presented in Raulf et al's papers [18,19] are obtained by fine-tuning the encoder-decoder models, where the encoders (architecture and initial parameters) originate from an autoencoder obtained in a pre-training step.…”

Section: Introductionmentioning

confidence: 99%

“…In several recent papers [16,17] AEs and/or encoder-decoder networks [18,19] are used for denoising and scattering removal in FTIR spectra or to obtain classifiers for spectral histopathology, for example, Raulf et al [19]. In particular, the networks presented in Raulf et al's papers [18,19] are obtained by fine-tuning the encoder-decoder models, where the encoders (architecture and initial parameters) originate from an autoencoder obtained in a pre-training step. That is, the pre-training provides an initial guess for embedding of the raw spectra suitable for a given problem (specified by the decoder), for example, regression [18] or classification [19].…”

Section: Introductionmentioning

confidence: 99%

“…In particular, the networks presented in Raulf et al's papers [18,19] are obtained by fine-tuning the encoder-decoder models, where the encoders (architecture and initial parameters) originate from an autoencoder obtained in a pre-training step. That is, the pre-training provides an initial guess for embedding of the raw spectra suitable for a given problem (specified by the decoder), for example, regression [18] or classification [19]. Using pure data-driven approaches Mete et al [20] construct surrogate models of bioreactors.…”

Section: Introductionmentioning

confidence: 99%

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Encoder–decoder neural networks for predicting future FTIR spectra – application to enzymatic protein hydrolysis

Kuchta

Wubshet

Afseth

et al. 2022

Journal of Biophotonics

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In the process of converting foodprocessing by-products to value-added ingredients, fine grained control of the raw materials, enzymes and process conditions ensures the best possible yield and economic return. However, when raw material batches lack good characterization and contain high batch variation, online or at-line monitoring of the enzymatic reactions would be beneficial. We investigate the potential of deep neural networks in predicting the future state of enzymatic hydrolysis as described by Fourier-transform infrared spectra of the hydrolysates. Combined with predictions of average molecular weight, this provides a flexible and transparent tool for process monitoring and control, enabling proactive adaption of process parameters.

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Trends in artificial intelligence, machine learning, and chemometrics applied to chemical data

Houhou

Bocklitz

2021

Analytical Science Advances

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Artificial intelligence‐based methods such as chemometrics, machine learning, and deep learning are promising tools that lead to a clearer and better understanding of data. Only with these tools, data can be used to its full extent, and the gained knowledge on processes, interactions, and characteristics of the sample is maximized. Therefore, scientists are developing data science tools mentioned above to automatically and accurately extract information from data and increase the application possibilities of the respective data in various fields. Accordingly, AI‐based techniques were utilized for chemical data since the 1970s and this review paper focuses on the recent trends of chemometrics, machine learning, and deep learning for chemical and spectroscopic data in 2020. In this regard, inverse modeling, preprocessing methods, and data modeling applied to spectra and image data for various measurement techniques are discussed.

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A representation learning approach for recovering scatter‐corrected spectra from Fourier‐transform infrared spectra of tissue samples

Cited by 6 publications

References 36 publications

Attenuated Total Reflection (ATR) Micro-Fourier Transform Infrared (Micro-FT-IR) Spectroscopy to Enhance Repeatability and Reproducibility of Spectra Derived from Single Specimen Organic-Walled Dinoflagellate Cysts

Attenuated Total Reflection (ATR) Micro-Fourier Transform Infrared (Micro-FT-IR) Spectroscopy to Enhance Repeatability and Reproducibility of Spectra Derived from Single Specimen Organic-Walled Dinoflagellate Cysts

Encoder–decoder neural networks for predicting future FTIR spectra – application to enzymatic protein hydrolysis

Trends in artificial intelligence, machine learning, and chemometrics applied to chemical data

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