Kamila Moor scite author profile

Kamila Moor

6Publications

100Citation Statements Received

45Citation Statements Given

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Affiliations

Kwansei Gakuin University, Nazarbayev University

Publications

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Nanoparticle–nanoparticle vs. nanoparticle–substrate hot spot contributions to the SERS signal: studying Raman labelled monomers, dimers and trimers

Sergiienko

Moor

Gudun

et al. 2017

Phys. Chem. Chem. Phys.

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We used a combination of Raman microscopy, AFM and TEM to quantify the influence of dimerization on the surface enhanced Raman spectroscopy (SERS) signal for gold and silver nanoparticles (NPs) modified with Raman reporters and situated on gold, silver, and aluminum films and a silicon wafer. The overall increases in the mean SERS enhancement factor (EF) upon dimerization (up by 43% on average) and trimerisation (up by 96% on average) of AuNPs and AgNPs on the studied metal films are within a factor of two, which is moderate when compared to most theoretical models. However, the maximum ratio of EFs for some dimers to the mean EF of monomers can be as high as 5.5 for AgNPs on a gold substrate. In contrast, for dimerization and trimerization of gold and silver NPs on silicon, the mean EF increases by 1-2 orders of magnitude relative to the mean EF of single NPs. Therefore, hot spots in the interparticle gap between gold nanoparticles rather than hot spots between Au nanoparticles and the substrate dominate SERS enhancement for dimers and trimers on a silicon substrate. However, Raman labeled noble metal nanoparticles on plasmonic metal films generate on average SERS enhancement of the same order of magnitude for both types of hot spot zones (e.g. NP/NP and NP/metal film).

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Noninvasive and label-free determination of virus infected cells by Raman spectroscopy

et al. 2014

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Abstract. The present study demonstrates that Raman spectroscopy is a powerful tool for the detection of virusinfected cells. Adenovirus infection of human embryonic kidney 293 cells was successfully detected at 12, 24, and 48 h after initiating the infection. The score plot of principal component analysis discriminated the spectra of the infected cells from those of the control cells. The viral infection was confirmed by the conventional immunostaining method performed 24 h after the infection. The newly developed method provides a fast and label-free means for the detection of virus-infected cells.

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Early detection of virus infection in live human cells using Raman spectroscopy

et al. 2018

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Virus infection of a human cell was determined only 3 h after invagination. We used viral vector Ad-CMV-control (AdC), which lacks the E1 gene coding for early polypeptide 1 (E1). AdC can replicate in human embryonic kidney 293 (HEK293) cells into which the E1 gene has been transfected. According to partial least-square regression discriminant analysis, it was assumed that two kinds of reaction take place in the cell during viral invasion. The first response of the cell was determined 3 h after the virus invasion, and the second one was determined ∼9 h later. The first one seems to be due to compositional changes in DNA. Analysis of large-scale datasets strongly indicated that the second reaction can be attributed to a reduction in protein concentration or uptake of phenylalanine into the nucleus.

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Study of virus by Raman spectroscopy

Moor

Kitamura

Hashimoto

et al. 2013

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Analysis of virus infected cell by Raman spectroscopy and transmission electron microscopy

Moor

Ohtani

Myrzakozha

et al. 2014

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Raman spectroscopy is a promising tool for detection of virus infection in live cells. In the present study, we demonstrate its feasibility to observe dynamic reaction of the live cell infected by virus. The Raman spectra of the adenovirus infected live cell (293 HEK) are analyzed by comparing with those of control cells. Principal component analysis (PCA) is employed also to analyze the spectra in detail. A band at 1650 cm-1 increases its intensity in the spectra measured at 24 hours after the virus infection. The infection of the virus is also examined by immune-staining and transmission electron microscope (TEM), and the virus infection is confirmed with these method also. It should be noted that the present technique does not require specifying the type of virus in advance.

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Raman Spectroscopy in Studies on Live Cells and Tissues

Sato¹,

Taketani²,

Moor³

et al. 2014

adv sci engng med

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Kamila Moor

Nanoparticle–nanoparticle vs. nanoparticle–substrate hot spot contributions to the SERS signal: studying Raman labelled monomers, dimers and trimers

Noninvasive and label-free determination of virus infected cells by Raman spectroscopy

Early detection of virus infection in live human cells using Raman spectroscopy

Study of virus by Raman spectroscopy

Analysis of virus infected cell by Raman spectroscopy and transmission electron microscopy

Raman Spectroscopy in Studies on Live Cells and Tissues

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