Machine Learning of Raman Spectroscopy Data for Classifying Cancers: A Review of the Recent Literature

Blake, Nathan; Gaifulina, Riana; Griffin, Lewis D.; Bell, Ian M.; Thomas, Geraint M. H.

doi:10.3390/diagnostics12061491

Cited by 24 publications

(24 citation statements)

References 59 publications

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“…A Python library BaselineRemoval contains several methods to remove the noise, caused by fluorescence in Raman spectra, and according to our previous findings [ 54 ], the airPLS algorithm [ 51 ] has a good performance. Principal component analysis (PCA) was used to extract informative features [ 55 , 56 ].…”

Section: Methodsmentioning

confidence: 99%

Discovering Glioma Tissue through Its Biomarkers’ Detection in Blood by Raman Spectroscopy and Machine Learning

et al. 2023

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The most commonly occurring malignant brain tumors are gliomas, and among them is glioblastoma multiforme. The main idea of the paper is to estimate dependency between glioma tissue and blood serum biomarkers using Raman spectroscopy. We used the most common model of human glioma when continuous cell lines, such as U87, derived from primary human tumor cells, are transplanted intracranially into the mouse brain. We studied the separability of the experimental and control groups by machine learning methods and discovered the most informative Raman spectral bands. During the glioblastoma development, an increase in the contribution of lactate, tryptophan, fatty acids, and lipids in dried blood serum Raman spectra were observed. This overlaps with analogous results of glioma tissues from direct Raman spectroscopy studies. A non-linear relationship between specific Raman spectral lines and tumor size was discovered. Therefore, the analysis of blood serum can track the change in the state of brain tissues during the glioma development.

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Section: Methodsmentioning

confidence: 99%

Discovering Glioma Tissue through Its Biomarkers’ Detection in Blood by Raman Spectroscopy and Machine Learning

et al. 2023

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“…This allows for hyperparameters to be optimised in an inner CV loop, and then tested against held-out data in an outer CV loop ( Figure 1 ). Nested CV has been shown to reduce a model’s estimated accuracy by as much as 20% in oncological applications of RS, giving a more realistic assessment of the model’s generalisability [ 8 ]. A single metric needs to be selected to optimise: the log loss was chosen as it is a proper scoring metric which utilises distributional information, compared to typical binarised metrics such as accuracy [ 17 ].…”

Section: Materials and Methodsmentioning

confidence: 99%

“…A Raman spectrum represents the change in photon wavenumber from a monochromatic light source along the x-axis and the intensity (i.e., number of photons) thus scattered on the y-axis. RS has been successfully applied to discriminate between numerous cancer types in human tissues, most recently to the brain, breast, cervical, colon, lung, nasopharyngeal, prostate, skin and tongue [ 8 ]. The applications include early diagnosis, biopsy guidance and intraoperative tumour margin detection.…”

Section: Introductionmentioning

confidence: 99%

“…Its ability to capture non-linear relationships make it suited to complex clinical datasets, and it may help unleash the potential of RS. In addition to being increasingly applied to oncology problems in the context of digital histopathology [ 10 ], it is now extending into oncological applications of RS [ 8 ]. However, DL is notoriously data-intensive, which makes it difficult to apply to smaller medical proof-of-concept studies.…”

Section: Introductionmentioning

confidence: 99%

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Deep Learning Applied to Raman Spectroscopy for the Detection of Microsatellite Instability/MMR Deficient Colorectal Cancer

Blake

Gaifulina

Griffin

et al. 2023

Cancers

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Defective DNA mismatch repair is one pathogenic pathway to colorectal cancer. It is characterised by microsatellite instability which provides a molecular biomarker for its detection. Clinical guidelines for universal testing of this biomarker are not met due to resource limitations; thus, there is interest in developing novel methods for its detection. Raman spectroscopy (RS) is an analytical tool able to interrogate the molecular vibrations of a sample to provide a unique biochemical fingerprint. The resulting datasets are complex and high-dimensional, making them an ideal candidate for deep learning, though this may be limited by small sample sizes. This study investigates the potential of using RS to distinguish between normal, microsatellite stable (MSS) and microsatellite unstable (MSI-H) adenocarcinoma in human colorectal samples and whether deep learning provides any benefit to this end over traditional machine learning models. A 1D convolutional neural network (CNN) was developed to discriminate between healthy, MSI-H and MSS in human tissue and compared to a principal component analysis–linear discriminant analysis (PCA–LDA) and a support vector machine (SVM) model. A nested cross-validation strategy was used to train 30 samples, 10 from each group, with a total of 1490 Raman spectra. The CNN achieved a sensitivity and specificity of 83% and 45% compared to PCA–LDA, which achieved a sensitivity and specificity of 82% and 51%, respectively. These are competitive with existing guidelines, despite the low sample size, speaking to the molecular discriminative power of RS combined with deep learning. A number of biochemical antecedents responsible for this discrimination are also explored, with Raman peaks associated with nucleic acids and collagen being implicated.

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“…A strength of the technique is that this information can be reinterpreted as a molecular fingerprint lending an interpretation of the material’s composition in terms of the relative concentration of proteins and specific amino acids, lipids, deoxyribonucleic acid, and ribonucleic acid, as well as water and other metabolites. 4 , 5 …”

Section: Introductionmentioning

confidence: 99%

Open-sourced Raman spectroscopy data processing package implementing a baseline removal algorithm validated from multiple datasets acquired in human tissue and biofluids

et al. 2023

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.SignificanceStandardized data processing approaches are required in the field of bio-Raman spectroscopy to ensure information associated with spectral data acquired by different research groups, and with different systems, can be compared on an equal footing.AimAn open-sourced data processing software package was developed, implementing algorithms associated with all steps required to isolate the inelastic scattering component from signals acquired using Raman spectroscopy devices. The package includes a novel morphological baseline removal technique (BubbleFill) that provides increased adaptability to complex baseline shapes compared to current gold standard techniques. Also incorporated in the package is a versatile tool simulating spectroscopic data with varying levels of Raman signal-to-background ratios, baselines with different morphologies, and varying levels of stochastic noise.ResultsApplication of the BubbleFill technique to simulated data demonstrated superior baseline removal performance compared to standard algorithms, including iModPoly and MorphBR. The data processing workflow of the open-sourced package was validated in four independent in-human datasets, demonstrating it leads to inter-systems data compatibility.ConclusionsA new open-sourced spectroscopic data pre-processing package was validated on simulated and real-world in-human data and is now available to researchers and clinicians for the development of new clinical applications using Raman spectroscopy.

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Machine Learning of Raman Spectroscopy Data for Classifying Cancers: A Review of the Recent Literature

Cited by 24 publications

References 59 publications

Discovering Glioma Tissue through Its Biomarkers’ Detection in Blood by Raman Spectroscopy and Machine Learning

Discovering Glioma Tissue through Its Biomarkers’ Detection in Blood by Raman Spectroscopy and Machine Learning

Deep Learning Applied to Raman Spectroscopy for the Detection of Microsatellite Instability/MMR Deficient Colorectal Cancer

Open-sourced Raman spectroscopy data processing package implementing a baseline removal algorithm validated from multiple datasets acquired in human tissue and biofluids

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