Applications of Surface-Enhanced Raman Scattering in Biochemical and Medical Analysis

Szaniawska, Aleksandra; Kudelski, Andrzej

doi:10.3389/fchem.2021.664134

Cited by 58 publications

(33 citation statements)

References 46 publications

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“…In comparison, these low concentrations may not be detected using non-SERS Raman due to a decrease in sensitivity, and therefore a loss in peak resolution compared to SERS. The possibility to identify and quantify low concentrations of the target drugs gives the technique a potential use for testing both seizure samples and biological matrices [ 59 ] or even in instances where the fluorescence overwhelms the Raman signals [ 60 ]. Furthermore, in situ SERS substrate activation provides some benefits to overcoming a possible time-dependent decrease of the surface and plasmonic properties, which could affect the reproducibility and reliability of the measurements [ 29 ].…”

Section: Resultsmentioning

confidence: 99%

Rapid Determination of the ‘Legal Highs’ 4-MMC and 4-MEC by Spectroelectrochemistry: Simultaneous Cyclic Voltammetry and In Situ Surface-Enhanced Raman Spectroscopy

González-Hernández

Ott

Arcos‐Martínez

et al. 2021

Sensors

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The synthetic cathinones mephedrone (4-MMC) and 4-methylethcathinone (4-MEC) are two designer drugs that represent the rise and fall effect of this drug category within the stimulants market and are still available in several countries around the world. As a result, the qualitative and quantitative determination of ‘legal highs’, and their mixtures, are of great interest. This work explores for the first time the spectroelectrochemical response of these substances by coupling cyclic voltammetry (CV) with Raman spectroscopy in a portable instrument. It was found that the stimulants exhibit a voltammetric response on a gold screen-printed electrode while the surface is simultaneously electro-activated to achieve a periodic surface-enhanced Raman spectroscopy (SERS) substrate with high reproducibility. The proposed method enables a rapid and reliable determination in which both substances can be selectively analyzed through the oxidation waves of the molecules and the characteristic bands of the electrochemical SERS (EC-SERS) spectra. The feasibility and applicability of the method were assessed in simulated seized drug samples and spiked synthetic urine. This time-resolved spectroelectrochemical technique provides a cost-effective and user-friendly tool for onsite screening of synthetic stimulants in matrices with low concentration analytes for forensic applications.

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Section: Resultsmentioning

confidence: 99%

Rapid Determination of the ‘Legal Highs’ 4-MMC and 4-MEC by Spectroelectrochemistry: Simultaneous Cyclic Voltammetry and In Situ Surface-Enhanced Raman Spectroscopy

González-Hernández

Ott

Arcos‐Martínez

et al. 2021

Sensors

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“…[19,57] Due to their working ability in a diverse environment, SERS can be broadly applicable for characterizations in the field of chemistry, materials, and life science. [11,[58][59][60] The excitation source in the SERS experiments is intense, usually a laser of a defined wavelength such as 532 nm. [61] Excitation sources of various wavelength regions from the UV to IR range can be used depending on the types of substrate and SERS instruments.…”

Section: General Features Of Surface-enhanced Raman Scatteringmentioning

confidence: 99%

Stationary, Continuous, and Sequential Surface‐Enhanced Raman Scattering Sensing Based on the Nanoscale and Microscale Polymer‐Metal Composite Sensor Particles through Microfluidics: A Review

Visaveliya

Mazetyte‐Stasinskiene

Köhler

2022

Advanced Optical Materials

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Surface‐enhanced Raman scattering (SERS) is a label‐free and accurate analytical technique for the detection of a broad range of various analytes such as, biomolecules, pesticides, petrochemicals, as well as, cellular and other biological systems. A key component for the SERS analysis is the substrate which is required to be equipped with plasmonic features of metal nanostructures that directly interact with light and targeted analytes. Either metal nanoparticles can be deposited on the solid support (glass or silicon) which is suitable for stationary SERS analysis or dispersed in the solution (freely moving nanoparticles). Besides these routinely utilizing SERS substrates, polymer–metal composite particles are promising for sustained SERS analysis where metal nanoparticles act as plasmon‐active (hence SERS‐active) components and polymer particles act as support to the metal nanoparticles. Composite sensor particles provide 3D interaction possibilities for analytes, suitable for stationary, continuous, and sequential analysis, and they are reusable/regenerated. Therefore, this review is focused on the experimental procedures for the development of multiscale, uniform, and reproducible composite sensor particles together with their application for SERS analysis. The microfluidic reaction technique is highly versatile in the production of uniform and size‐tunable composite particles, as well as, for conducting SERS analysis.

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“…It can be deduced that, for the samples prepared using a freezing step, the degree of aggregation is significantly larger. Since the aggregation of plasmonic nanoparticles significantly increases their SERS activity (especially large SERS enhancements are observed for molecules in the narrow slits between the plasmonic nanoparticles, known as "hot spots" [20,21]), a certain agglomeration of the gold nanoparticles after the freezing step is probably also a cause of the larger SERS activity of such samples. During freezing, water crystals form, which cause a concentration of the solution (meaning a local concentration of the gold nanoparticles and DNA).…”

Section: Modification Of the Adsorption Proceduresmentioning

confidence: 99%

“…molecules in the narrow slits between the plasmonic nanoparticles, known as "hot spot [20,21]), a certain agglomeration of the gold nanoparticles after the freezing step probably also a cause of the larger SERS activity of such samples. During freezing, wat crystals form, which cause a concentration of the solution (meaning a local concentrati of the gold nanoparticles and DNA).…”

Section: Modification Of the Adsorption Proceduresmentioning

confidence: 99%

“…The SERS phenomenon is explained as a result of a synergistic cooperation of two mechanisms: a local enhancement of the intensity of the electric field, which is a consequence of the excitation of the localized surface plasmons, and an increase in the efficiency of the generation of Raman scattering due to chemical interactions with the SERS substrate, in an effect similar to standard resonance Raman scattering [20,21]. Important characteristic features of the enhancement of the SERS spectrum are a sharp decrease with increasing distance from the SERS substrate, and in the case of an agglomeration or aggregation of plasmonic SERS-active nanostructures, a very large increase in the SERS activity of the material (a very large field enhancement is observed in the narrow slits between the plasmonic nanograins, known as "hot spots", and the formation of such structures significantly increases the SERS activity of the material) [20,21]. SERS is one of the most sensitive analytical tools, and in some cases, it is possible to observe a quality SERS spectrum of even a single molecule [22,23].…”

Section: Introductionmentioning

confidence: 99%

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Attachment of Single-Stranded DNA to Certain SERS-Active Gold and Silver Substrates: Selected Practical Tips

et al. 2021

Self Cite

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Layers formed from single-stranded DNA on nanostructured plasmonic metals can be applied as “working elements” in surface–enhanced Raman scattering (SERS) sensors used to sensitively and accurately identify specific DNA fragments in various biological samples (for example, in samples of blood). Therefore, the proper formation of the desired DNA layers on SERS substrates is of great practical importance, and many research groups are working to improve the process in forming such structures. In this work, we propose two modifications of a standard method used for depositing DNA with an attached linking thiol moiety on certain SERS-active structures; the modifications yield DNA layers that generate a stronger SERS signal. We propose: (i) freezing the sample when forming DNA layers on the nanoparticles, and (ii) when forming DNA layers on SERS-active macroscopic silver substrates, using ω-substituted alkanethiols with very short alkane chains (such as cysteamine or mercaptopropionic acid) to backfill the empty spaces on the metal surface unoccupied by DNA. When 6-mercapto-1-hexanol is used to fill the unoccupied places on a silver surface (as in experiments on standard gold substrates), a quick detachment of chemisorbed DNA from the silver surface is observed. Whereas, using ω-substituted alkanethiols with a shorter alkane chain makes it possible to easily form mixed DNA/backfilling thiol monolayers. Probably, the significantly lower desorption rate of the thiolated DNA induced by alkanethiols with shorter chains is due to the lower stabilization energy in monolayers formed from such compounds.

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Applications of Surface-Enhanced Raman Scattering in Biochemical and Medical Analysis

Cited by 58 publications

References 46 publications

Rapid Determination of the ‘Legal Highs’ 4-MMC and 4-MEC by Spectroelectrochemistry: Simultaneous Cyclic Voltammetry and In Situ Surface-Enhanced Raman Spectroscopy

Rapid Determination of the ‘Legal Highs’ 4-MMC and 4-MEC by Spectroelectrochemistry: Simultaneous Cyclic Voltammetry and In Situ Surface-Enhanced Raman Spectroscopy

Stationary, Continuous, and Sequential Surface‐Enhanced Raman Scattering Sensing Based on the Nanoscale and Microscale Polymer‐Metal Composite Sensor Particles through Microfluidics: A Review

Attachment of Single-Stranded DNA to Certain SERS-Active Gold and Silver Substrates: Selected Practical Tips

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