An infrared spectroscopic blood test for non-small cell lung carcinoma and subtyping into pulmonary squamous cell carcinoma or adenocarcinoma

Ollesch, Julian; Theegarten, Dirk; Altmayer, Matthias; Darwiche, Kaid; Hager, Thomas; Stamatis, Georgios; Gerwert, Klaus

doi:10.3233/bsi-160144

Cited by 16 publications

(21 citation statements)

References 31 publications

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“…Thus, recent reports detailing the detection of specific disease in dried blood serum or plasma samples, such as the detection of cancer of the brain , prostate , bladder , lung , breast ovary , liver and bile duct , may have to be re‐evaluated in terms of their claims of detecting a specific disease. Rather, these reports may have detected a disease‐induced change in the AGR that may be much larger than signals expected for specific disease markers.…”

Section: Introductionmentioning

confidence: 99%

Comments on recent reports on infrared spectral detection of disease markers in blood components

Diem

2018

Journal of Biophotonics

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The search for disease markers in whole blood, or easily accessible blood components by spectral methods is a highly important aspect in the field of biophotonic research for disease diagnostics and screening, since it promises a minimally invasive approach to assess an individual's state of health. Fourier transform infrared spectroscopy, in particular, promises to be a fast, inexpensive method to search for markers of disease, since it detects variation in the proteome, lipidome and metabolome of biofluids, or activation of immune cells. However, the analysis of any materials by spectral methods is confounded by external factors such as those related to sample deposition and data acquisition, and by inherent variations in blood plasma concentration of small molecules (lactate, carbonate, phosphate, glucose) that varies between individual subjects and even for a given individual, as a function of time. Furthermore, observed differences in spectral patterns between patient samples and the control group may be due to the body's immune response (in particular, to the albumin to globulin ratio) and therefore, may not be specific to disease. These factors need to be accounted for in any effort to reliably detect much smaller variations in the concentration of disease-specific markers.

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Section: Introductionmentioning

confidence: 99%

Comments on recent reports on infrared spectral detection of disease markers in blood components

Diem

2018

Journal of Biophotonics

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“…Tester) we provide a robust methodology to make it easier to test different pre- The Random Forest (RF) machine learning algorithm is widely used in many different fields of research, including cheminformatics, [10,11] bioinformatics, [12], and ecology, [13]. Within the field of biomedical spectroscopy, RF has been used in the annotation of lung cancer subtypes [14] and in the diagnosis of nonsmall cell lung carcinoma, [15] urinary bladder cancer, [16], hyperlipidemia [17], and brain tumours [7]. RF has proven to be a robust and accurate technique for developing spectral diagnostic models, giving excellent classification results without over-fitting.…”

Section: Prffect (Pre-processing and Random Forest Feature Extraction Cmentioning

confidence: 99%

PRFFECT: A versatile tool for spectroscopists

Smith

Baker

Palmer

2018

Chemometrics and Intelligent Laboratory Systems

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PRFFECT is a computer program to aid with spectral preprocessing and the development of classification models. Via a simple text interface, PRFFECT allows users to select wavenumber ranges, perform spectral preprocessing, carry out data partitioning (into training and testing datasets), run a Random Forest classification, compute statistical results, and identify important descriptors for the classification. The preprocessing options provided fall into four categories: binning, smoothing, normalisation, and baseline correction. The program outputs a wide-variety of useful data, including classification metrics and graphs showing the importance of individual wavenumbers to the classification models. As proof-of-concept, PRFFECT has been benchmarked on preprocessing and classification of four food analysis datasets. Sensitivities and specificities above 0.92 were obtained in all cases. The results show that different preprocessing procedures are optimal for different datasets.

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“…It was suggested that FTIR in sputum cells showed high sensitivity and specificity in diagnosing the disease within a small range of significant wave numbers [10] . Another study was performed on 161 patients with initial cancer suspicion with the FTIR analysis of blood sample to identify non-small cell lung carcinoma (NSCLC) [43] . Biochemical differences between blood samples of control and lung carcinoma patients were detected in the spectra and an accuracy of 80% was achieved in separation of squamous cell and adenocarcinoma patients.…”

Section: Lung Cancermentioning

confidence: 99%

Application of Fourier Transform-Infrared Spectroscopy as a Tool for Early Cancer Detection

Kumari¹,

Kaur²,

Bhattacharyya³

2018

Am. J. Biomed. Sci.

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The absence of sufficiently reliable, cost-effective and non-invasive approaches for detection of cancers at initial stage fuel a search for new and effective diagnostic methods to screen and prevent cancer. Fourier transform infrared (FTIR) spectroscopy is a vibrational method which detects changes in vibration of molecular bonds using infrared radiation in tissues and cells. FTIR detects biochemical changes within the sample and can be used to find biomarkers for early detection of various cancers in the region of mid infrared range of 4000 to 400 cm -1 . It provides precise database on molecular finger printing of the characteristic FTIR peak frequencies for researchers aiming to study biological samples such as cells, tissue sections, bio fluids and fixed cytology. Promising role of FTIR as a specific and sensitive analytical tool to differentiate between unaffected and malignant cells in breast, colon, skin, ovaries, lung, cervix, and oesophagus carcinoma has been already reported. The biochemical changes within tumor and normal cells are normally detected at the "fingerprint region" of 1800 to 950 cm -1 by measuring the change in frequency of vibration of the molecules. In this review, we present application of FTIR spectroscopy in cancer biology. Thus this review is aimed to brief the potential role of FTIR in detection of various types of cancers.

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An infrared spectroscopic blood test for non-small cell lung carcinoma and subtyping into pulmonary squamous cell carcinoma or adenocarcinoma

Cited by 16 publications

References 31 publications

Comments on recent reports on infrared spectral detection of disease markers in blood components

Comments on recent reports on infrared spectral detection of disease markers in blood components

PRFFECT: A versatile tool for spectroscopists

Application of Fourier Transform-Infrared Spectroscopy as a Tool for Early Cancer Detection

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