Literature DB >> 21030951

Distinguishing cell types or populations based on the computational analysis of their infrared spectra.

Francis L Martin1, Jemma G Kelly, Valon Llabjani, Pierre L Martin-Hirsch, Imran I Patel, Júlio Trevisan, Nigel J Fullwood, Michael J Walsh.   

Abstract

Infrared (IR) spectroscopy of intact cells results in a fingerprint of their biochemistry in the form of an IR spectrum; this has given rise to the new field of biospectroscopy. This protocol describes sample preparation (a tissue section or cytology specimen), the application of IR spectroscopy tools, and computational analysis. Experimental considerations include optimization of specimen preparation, objective acquisition of a sufficient number of spectra, linking of the derived spectra with tissue architecture or cell type, and computational analysis. The preparation of multiple specimens (up to 50) takes 8 h; the interrogation of a tissue section can take up to 6 h (∼100 spectra); and cytology analysis (n = 50, 10 spectra per specimen) takes 14 h. IR spectroscopy generates complex data sets and analyses are best when initially based on a multivariate approach (principal component analysis with or without linear discriminant analysis). This results in the identification of class clustering as well as class-specific chemical entities.

Mesh:

Year:  2010        PMID: 21030951     DOI: 10.1038/nprot.2010.133

Source DB:  PubMed          Journal:  Nat Protoc        ISSN: 1750-2799            Impact factor:   13.491


  32 in total

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4.  Infrared spectroscopy with multivariate analysis potentially facilitates the segregation of different types of prostate cell.

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5.  Derivation of a subtype-specific biochemical signature of endometrial carcinoma using synchrotron-based Fourier-transform infrared microspectroscopy.

Authors:  Jemma G Kelly; Maneesh N Singh; Helen F Stringfellow; Michael J Walsh; James M Nicholson; Fariba Bahrami; Katherine M Ashton; Mark A Pitt; Pierre L Martin-Hirsch; Francis L Martin
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6.  Microspectroscopy of spectral biomarkers associated with human corneal stem cells.

Authors:  Takahiro Nakamura; Jemma G Kelly; Júlio Trevisan; Leanne J Cooper; Adam J Bentley; Paul L Carmichael; Andrew D Scott; Marine Cotte; Jean Susini; Pierre L Martin-Hirsch; Shigeru Kinoshita; Nigel J Fullwood; Francis L Martin
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7.  Discrimination of base differences in oligonucleotides using mid-infrared spectroscopy and multivariate analysis.

Authors:  Jemma G Kelly; Pierre L Martin-Hirsch; Francis L Martin
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8.  Detection of breast micro-metastases in axillary lymph nodes by infrared micro-spectral imaging.

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9.  A three-dimensional multivariate image processing technique for the analysis of FTIR spectroscopic images of multiple tissue sections.

Authors:  Bayden R Wood; Keith R Bambery; Corey J Evans; Michael A Quinn; Don McNaughton
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10.  FTIR-based spectroscopic analysis in the identification of clinically aggressive prostate cancer.

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2.  Evaluating the effects of causes of death on postmortem interval estimation by ATR-FTIR spectroscopy.

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Journal:  Nat Protoc       Date:  2016-03-10       Impact factor: 13.491

5.  Regulated genes in mesenchymal stem cells and gastric cancer.

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6.  Differential diagnosis of Alzheimer's disease using spectrochemical analysis of blood.

Authors:  Maria Paraskevaidi; Camilo L M Morais; Kássio M G Lima; Julie S Snowden; Jennifer A Saxon; Anna M T Richardson; Matthew Jones; David M A Mann; David Allsop; Pierre L Martin-Hirsch; Francis L Martin
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7.  High-resolution Fourier-transform infrared chemical imaging with multiple synchrotron beams.

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Review 8.  Infrared spectroscopic imaging: the next generation.

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Journal:  Appl Spectrosc       Date:  2012-10       Impact factor: 2.388

9.  Application of metasurface-enhanced infra-red spectroscopy to distinguish between normal and cancerous cell types.

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Review 10.  Infrared spectroscopic imaging: Label-free biochemical analysis of stroma and tissue fibrosis.

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