Study of gemcitabine‐sensitive/resistant cancer cells by cell cloning and synchrotron FTIR microspectroscopy

Rutter, Abigail V.; Siddique, Muhammad Irfan; Filik, Jacob; Sandt, Christophe; Dumas, Paul; Cinque, Gianfelice; Sockalingum, Ganesh D.; Yang, Ying; Sulé-Suso, Josep

doi:10.1002/cyto.a.22488

Cited by 26 publications

(19 citation statements)

References 38 publications

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“…Subtle differences in cell spectra have been used to distinguish cells in different stages in the cell cycle [2], apoptotic cells [3] or cell lines [4,5], to identify cancer cells [6], and to predict the aggressiveness of cancer cells [7]. Several studies have shown a relationship between the mode of action of chemotherapy drugs and changes in FTIR spectra of dried cells [8][9][10], as well as differences in FTIR spectra of drug-resistant and drug-sensitive cells [11][12][13]. In these studies cells were treated with a mildly cytotoxic or cytostatic concentration of drug, generally the IC 50 value for the drug toxicity, and were then collected and dried prior FTIR analysis, as water causes a strong interference in FTIR analysis.…”

Section: Introductionmentioning

confidence: 99%

In situ Fourier transform infrared analysis of live cells' response to doxorubicin

Fale

Altharawi

Chan

2015

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

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The study of the response of cancer cells to chemotherapy drugs is of high importance due to the specificity of some drugs to certain types of cancer and the resistance of some specific cancer types to chemotherapy drugs. Our aim was to develop and apply the label-free and non-destructive Fourier transform infrared (FTIR) method to determine the sensitivity of three different cancer cell-lines to a common anti-cancer drug doxorubicin at different concentrations and to demonstrate that information about the mechanism of resistance to the chemotherapy drug can be extracted from spectral data. HeLa, PC3, and Caco-2 cells were seeded and grown on an attenuated total reflection (ATR) crystal, doxorubicin was applied at the clinically significant concentration of 0.1-20 μM, and spectra of the cells were collected hourly over 20 h. Analysis of the amide bands was correlated with cell viability, which had been cross validated with MTT assays, allowing to determine that the three cell lines had significantly different resistance to doxorubicin. The difference spectra and principal component analysis (PCA) highlighted the subtle chemical changes in the living cells under treatment. Spectral regions assigned to nucleic acids (mainly 1085 cm(-1)) and carbohydrates (mainly 1024 cm(-1)) showed changes that could be related to the mode of action of the drug and the mechanism of resistance of the cell lines to doxorubicin. This is a cost-effective method that does not require bioassay reagents but allows label-free, non-destructive and in situ analysis of chemical changes in live cells, using standard FTIR equipment adapted to ATR measurements.

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Section: Introductionmentioning

confidence: 99%

In situ Fourier transform infrared analysis of live cells' response to doxorubicin

Fale

Altharawi

Chan

2015

Biochimica et Biophysica Acta (BBA) - Molecular Cell Research

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“…Cellular resistance pathways were specifically targeted by Yosef et al who used Raman spectral imaging to investigate the oncogenic mutation resistance to epidermal growth factor receptor targeting therapy and colon cancer cells with and without oncogenic mutations such as KRAS and BRAF mutations were treated with erlotinib, an inhibitor of epidermal growth factor receptor, in order to detect the impact of these mutations on Raman spectra of the cells as markers of cell resistance. Rutter et al utilised a cell cloning technique to specifically isolate sensitive and resistant cells from a mixed cell population, and investigated the difference in response of gemcitabine‐sensitive and gemcitabine‐resistant Calu‐1 epidermoid lung cancer cells to the commercial drug, using IR spectroscopy. Furthermore, Siddique et al showed that it was also possible to identify differences of nilotinib‐sensitive and nilotinib‐resistant K562 (a chronic myelogenous leukaemia cell line) cloned cells, using both FTIR and Raman microspectroscopies.…”

Section: Introductionmentioning

confidence: 99%

In vitro label‐free screening of chemotherapeutic drugs using Raman microspectroscopy: Towards a new paradigm of spectralomics

Farhane¹,

Nawaz

Bonnier

et al. 2018

Journal of Biophotonics

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This overview groups some of the recent studies highlighting the potential application of Raman microspectroscopy as an analytical technique in preclinical development to predict drug mechanism of action and in clinical application as a companion diagnostic and in personalised therapy due to its capacity to predict cellular resistance and therefore to optimise chemotherapeutic treatment efficacy. Notably, the anthracyclines, doxorubicin and actinomycin D, elicit similar spectroscopic signatures of subcellular interaction characteristic of the mode of action of intercalation. Although cisplatin and vincristine show markedly different signatures, at low exposure doses, their signatures at higher doses show marked similarities to those elicited by the intercalating anthracyclines, confirming that anticancer agents can have different modes of action with different spectroscopic signatures, depending on the dose. The study demonstrates that Raman microspectroscopy can elucidate subcellular transport and accumulation pathways of chemotherapeutic agents, characterise and fingerprint their mode of action, and potentially identify cell-resistant strains. The consistency of the spectroscopic signatures for drugs of similar modes of action, in different cell lines, suggests that this fingerprint can be considered a "spectralome" of the drug-cell interaction suggesting a new paradigm of representing spectroscopic responses.

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“…Rutter et al [69] investigated the difference in response of gemcitabinesensitive and gemcitabine-resistant CALU-1 epidermoid lung cancer cells to gemcitabine. By cloning sensitive and resistant cell populations, from a mixed population, they showed that PCA did not discriminate treated from untreated resistant cells, but did for sensitive cells.…”

Section: Infrared Spectroscopy For Monitoring Drug-cell Interactionmentioning

confidence: 99%

Vibrational spectroscopy as a tool for studying drug-cell interaction: Could high throughput vibrational spectroscopic screening improve drug development?

Jamieson

Byrne²

2017

Vibrational Spectroscopy

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. (2017). Vibrational spectroscopy as a tool for studying drug-cell interaction: could high throughput vibrational spectroscopic screening improve drug development? Vibrational Spectroscopy, vol. 91, July, pp. 16-30. doi.org/10.1016/ j.vibspec.2016 Vibrational spectroscopy as a tool for studying drug-cell interaction: could high throughput vibrational spectroscopic screening improve drug development? AbstractVibrational spectroscopy is currently widely explored as a tool in biomedical applications. An area at the forefront of this field is the use of vibrational spectroscopy for disease diagnosis, ultimately aiming towards spectral pathology. However, while this field shows promising results, moving this technique into the clinic faces the challenges of widespread clinical trials and legislative approval. While spectral pathology has received a lot of attention, there are many other biomedical applications of vibrational spectroscopy, which could potentially be translated to applications with greater ease. A particularly promising application is the use of vibrational spectroscopic techniques to study the interaction of drugs with cells. Many studies have demonstrated the ability to detect biochemical changes in cells in response to drug application, using both infrared and Raman spectroscopy. This has shown potential for use in high throughput screening (HTS) applications, for screening of efficacy and mode of action of potential drug candidates, to speed up the drug discovery process. HTS is still a relatively new and growing area of research and, therefore, there is more potential for new techniques to move into and shape this field. Vibrational spectroscopic techniques come with many benefits over the techniques used currently in HTS, primarily based on fluorescence assays to detect specific binding interactions or phenotypes. They are label free, and an infrared or Raman spectrum provides a wealth of biochemical information, and therefore could reveal not only information about a specific interaction, but about how the overall biochemistry of a cell changes in response to application of a drug candidate. Therefore, drug mode of action could be elucidated. This review will investigate the potential for vibrational spectroscopy, particularly FTIR and Raman spectroscopy, to benefit the field of HTS and improve the drug development process. In addition to FTIR and Raman spectroscopy, surface enhanced Raman spectroscopy (SERS), coherent anti-Stokes Raman spectroscopy (CARS) and stimulated Raman spectroscopy (SRS), will be investigated as an alternative tool in the HTS process.

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Study of gemcitabine‐sensitive/resistant cancer cells by cell cloning and synchrotron FTIR microspectroscopy

Cited by 26 publications

References 38 publications

In situ Fourier transform infrared analysis of live cells' response to doxorubicin

In situ Fourier transform infrared analysis of live cells' response to doxorubicin

In vitro label‐free screening of chemotherapeutic drugs using Raman microspectroscopy: Towards a new paradigm of spectralomics

Vibrational spectroscopy as a tool for studying drug-cell interaction: Could high throughput vibrational spectroscopic screening improve drug development?

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