SERS detection methods for several key molecules in the oxidative stress process of cells

doi:10.13883/j.issn1004-5929.201904003

Chinese Journal of Light Scattering ›› 2019, Vol. 31 ›› Issue (4) : 317-325. DOI: 10.13883/j.issn1004-5929.201904003

Overview

SERS detection methods for several key molecules in the oxidative stress process of cells

YUE Jing, SHEN Yanting, WANG Jiaqi, XU Weiqing, XU Shuping^*

Author information +

History +

Abstract

Oxidative stress is associated with the development of various diseases including cancer, cardiovascular disease, neurodegenerative diseases and diabetes mellitus. In response to these oxidation reactions, cells start stress responses. A lot of the key molecules, e.g reactive oxygen species molecules (ROS), would be produced during oxidative stress and they play an extremely important role. The analysis and detection of these key molecules can not only help to understand the important roles of these molecules in the oxidative stress process, but also can have a deeper understanding of the occurrence and development of diseases. In this review, we focused on summarizing the surface-enhanced Raman spectroscopic techniques that realize the analyses and detections of the key molecules of oxidative stress in cells. Starting from the designed strategies of SERS methods, we classified and summarized the existing methods, enumerated a number of research work of Chinese scientists, and displayed the outlook for this field.

Key words

oxidative stress / intracellular detection / SERS / SERS tag / ROS

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

YUE Jing, SHEN Yanting, WANG Jiaqi, XU Weiqing, XU Shuping. SERS detection methods for several key molecules in the oxidative stress process of cells. Chinese Journal of Light Scattering. 2019, 31(4): 317-325 https://doi.org/10.13883/j.issn1004-5929.201904003

References

[1] Lane L A, Qian X, Nie S. SERS Nanoparticles in Medicine: From Label-Free Detection to Spectroscopic Tagging[J].Chemical Reviews,2015, 115(19):10489-10529.
[2] Cialla-May D, Zheng X S, Weber K, et al. Recent progress in surface-enhanced Raman spectroscopy for biological and biomedical applications: from cells to clinics[J]. Chemical Society Reviews, 2017, 46(13):3945-3961.
[3] Zong C, Xu M, Xu L J, et al. Surface-enhanced Raman spectroscopy for bioanalysis: reliability and challenges[J]. Chemical Reviews, 2018, 118(10):4946-4980.
[4] Jiang C, Liu R, Han G, et al. A chemically reactive Raman probe for ultrasensitively monitoring and imaging the in vivo generation of femtomolar oxidative species as induced by anti-tumor drugs in living cells[J]. Chemical Communications, 2013, 49(59):6647-6649.
[5] Qu L L, Li,D W, Qin L X, et al. Selective and sensitive detection of intracellular O₂^·- using AuNPs/cytochrome c as SERS nanosensors[J]. Analytical Chemistry, 2013, 85(20): 9549-9555.
[6] Kumar S, Rhim W K, Lim D K, et al. Glutathione dimerization-based plasmonic nanoswitch for biodetection of reactive oxygen and nitrogen species[J]. ACS Nano, 2013, 7(3):2221-2230.
[7] Qu L L, Liu,Y Y, He S H, et al. Highly selective and sensitive surface enhanced Raman scattering nanosensors for detection of hydrogen peroxide in living cells[J]. Biosensors & Bioelectronics, 2016,77:292-298.
[8] Gu X, Wang H, Schultz Z D, et al. Sensing glucose in urine and serum and hydrogen peroxide in living cells by use of a novel boronate nanoprobe based on surface-enhanced Raman spectroscopy[J]. Analytical Chemistry, 2016, 88(14):7191-7197.
[9] Peng R, Si Y, Deng T, et al. A novel SERS nanoprobe for the ratiometric imaging of hydrogen peroxide in living cells[J]. Chemical Communications, 2016, 52(55):8553-8556.
[10] Wang W, Zhang L, Li L, et al. A Single nanoprobe for ratiometric imaging and biosensing of hypochlorite and glutathione in live cells using surface-enhanced Raman scattering[J]. Analytical Chemistry, 2016, 88(19):9518-9523.
[11] Kumar S, Kumar A, Kim G H, et al. Myoglobin and polydopamine-engineered Raman nanoprobes for detecting, imaging, and monitoring reactive oxygen species in biological samples and living cells[J]. Small, 2017,13(43):1701584.
[12] Cui K, Fan C, Chen G, et al. Para-aminothiophenol radical reaction-functionalized gold nanoprobe for one-to-all detection of five reactive oxygen species in vivo[J]. Analytical Chemistry, 2018, 90(20):12137-12144.
[13] Li D W, Sun J J, Gan Z F, et al. Reaction-based SERS nanosensor for monitoring and imaging the endogenous hypochlorous acid in living cells[J]. Analytica Chimica Acta, 2018, 1018:104-110.
[14] Li D W, Chen H Y, Gan Z F, et al. Surface-enhanced Raman scattering nanoprobes for the simultaneous detection of endogenous hypochlorous acid and peroxynitrite in living cells[J]. Sensors and Actuators B, 2018, 277:8-13.
[15] Chen H Y, Guo D, Gan Z F, et al. A phenylboronate-based SERS nanoprobe for detection and imaging of intracellular peroxynitrite[J]. Microchimica Acta, 2018, 186(1):11.
[16] Si Y, Li L, Qin X, et al. Porous SiO₂-coated Au-Ag alloy nanoparticles for the alkyne-mediated ratiometric Raman imaging analysis of hydrogen peroxide in live cells[J]. Analytica Chimica Acta, 2019, 1057:1-10.
[17] Wei C, Liu X, Gao Y, et al. Thiol-disulfide exchange reaction for cellular glutathione detection with surface-enhanced Raman scattering[J]. Analytical Chemistry, 2018, 90(19):11333-11339.
[18] Dong J, Guo G, Xie W, et al. Free radical-quenched SERS probes for detecting H₂O₂ and glucose[J]. Analyst, 2015, 140(8):2741-2746.
[19] Qin L, Li X, Kang S Z, et al. Gold nanoparticles conjugated dopamine as sensing platform for SERS detection[J]. Colloids and Surfaces B, 2015, 126:210-216.
[20] Qu L L, He S H, Wang J J, et al. Fluorescence-surface enhanced Raman scattering dual-mode nanosensors to monitor hydroxyl radicals in living cells[J]. Sensors and Actuators B, 2017, 251:934-941.
[21] Shen Y, Liang L, Zhang J, et al. Interference-free surface-enhanced Raman scattering nanosensor for imaging and dynamic monitoring of reactive oxygen species in mitochondria during photothermal therapy[J]. Sensors and Actuators B, 2019, 285:84-91.
[22] Saha A, Jana N R. Detection of cellular glutathione and oxidized glutathione using magnetic-plasmonic nanocomposite-based "turn-off" surface enhanced Raman scattering[J]. Analytical Chemistry, 2013, 85(19):9221-9228.
[23] Ouyang L, Zhu L, Jiang J, et al. A surface-enhanced Raman scattering method for detection of trace glutathione on the basis of immobilized silver nanoparticles and crystal violet probe[J]. Analytica Chimica Acta, 2014,816:41-49.
[24] Zhao J, Zhang K, Ji J, et al. Sensitive and label-free quantification of cellular biothiols by competitive surface-enhanced Raman spectroscopy[J]. Talanta, 2016, 152:196-202.
[25] Sezer M, Kielb P, Kuhlmann U, et al. Surface enhanced resonance Raman spectroscopy reveals potential induced redox and conformational changes of cytochrome c oxidase on electrodes[J]. J Phys Chem B, 2017, 30:9586-9591.
[26] Zhang H J, Kou Y M, Li J B, et al. Nickel nanowires combined with surface-enhanced Raman spectroscopy: application in label-free detection of cytochrome c-mediated apoptosis[J]. Analytical Chemistry, 2019, 91:1213-1216.
[27] Li Z H, Cheng H J, Shao S Q, et al. Surface immobilization of redox-labile fluorescent probes: enabling single-cell co-profiling of aerobic glycolysis and oncogenic protein signaling activities[J]. Angewandte Chemie International Edition in English, 2018, 57:11554-11558.

PDF(1909 KB)

196

Accesses

Citation

Detail

Sections

Recommended

Abstract
Key words
Cite this article
References

Received	Revised	Published
2019-07-26	2019-12-08	2019-12-10
Issue Date
2022-08-19

Please choose a citation manager

Content to export

Abstract

Key words

Cite this article

{{custom_sec.title}}

{{custom_sec.title}}

References

{{custom_fnGroup.title_en}}

Footnotes