Phenotypic and Metabolic Profiling of Biological Samples in Near Real-Time Using Raman Spectroscopy

Zu, Theresah Nom Korbieh

22 October 2014

Raman spectroscopy, together with multivariate statistical analyses, has proven to be a near real-time analytical technique capable of phenotyping cells, tissues and organs. This dissertation will show exclusively the application of the Raman spectroscopy phenotypic profiling method to; (i) microbial toxicity, (ii) ex-vivo organ perfusion, and (iii) subcellular location targeting. Real-time analytical methods for monitoring living biological systems will enable study of the physiological changes associated with growth, genetic manipulations, and adverse environmental conditions. Most existing analytical methods (NMR exempt), though highly accurate, must be performed off-line and most require destruction of the studied sample. These attributes make these methodologies less desirable to the study of physiological changes of cells, tissues, and organs. In this work, Raman spectroscopy has been identified and shown to be a good candidate for real-time analysis mainly because it can be performed: (i) in near real-time, (ii) non-destructively and with minimal sample preparation, (iii) through a glass barrier (i.e., can be performed in situ), and (iv) with minimal spectral interference from water. Here, Raman spectroscopy was used in combination with multivariate statistics to analyze the differing toxic effects of 4-C chain alcohols on E. coli. Good correlations were established between Raman spectra and off-line analytical techniques used to measure: (i) saturated, unsaturated, and cyclopropane fatty acids; (ii) amino acid composition of total protein; and (iii) cell membrane fluidity. Also, Raman 'fingerprint' analysis was used to discriminate among different phenotypic responses of cells. In addition, this methodology was applied to analyze perfusates of organs maintained by the VasoWave® organ perfusion system. Raman fingerprints can be used to assess organ health, and it is believed this data can be used to inform decisions such as whether or not to transplant an organ. Finally, molecular biology techniques were used to design and produce specific protein targets harboring a silver binding domain fusion, which upon release migrate to specific subcellular locations. By employing the related technique of surface-enhanced Raman scattering (SERS), which produces a highly amplified Raman signal in the presence of metallic nanoparticle substrates (e.g., silver nanoparticles), different regions of the E. coli cell structure were studied. The target regions studied by the technique included: (i) outer cell membrane, (ii) periplasm, and the (iii) cytoplasm. / Ph. D.

Raman spectroscopy

surface enhanced Raman scattering

microbial phenotyping

alcohol toxicity

organ transplantation

ex vivo perfusion

near real-time analysis

silver nanoparticles

Advanced Applications of Raman Spectroscopy for Environmental Analyses

Lahr, Rebecca Halvorson

09 January 2014

Due to an ever-increasing global population and limited resource availability, there is a constant need for detection of both natural and anthropogenic hazards in water, air, food, and material goods. Traditionally a different instrument would be used to detect each class of contaminant, often after a concentration or separation protocol to extract the analyte from its matrix. Raman spectroscopy is unique in its ability to detect organic or inorganic, airborne or waterborne, and embedded or adsorbed analytes within environmental systems. This ability comes from the inherent abilities of the Raman spectrometer combined with concentration, separation, and signal enhancement provided by drop coating deposition Raman (DCDR) and surface-enhanced Raman spectroscopy (SERS). Herein the capacity of DCDR to differentiate between cyanotoxin variants in aqueous solutions was demonstrated using principal component analysis (PCA) to statistically demonstrate spectral differentiation. A set of rules was outlined based on Raman peak ratios to allow an inexperienced user to determine the toxin variant identity from its Raman spectrum. DCDR was also employed for microcystin-LR (MC-LR) detection in environmental waters at environmentally relevant concentrations, after pre-concentration with solid-phase extraction (SPE). In a cellulose matrix, SERS and normal Raman spectral imaging revealed nanoparticle transport and deposition patterns, illustrating that nanoparticle surface coating dictated the observed transport properties. Both SERS spectral imaging and insight into analyte transport in wax-printed paper microfluidic channels will ultimately be useful for microfluidic paper-based analytical device (𝜇PAD) development. Within algal cells, SERS produced 3D cellular images in the presence of intracellularly biosynthesized gold nanoparticles (AuNP), documenting in detail the molecular vibrations of biomolecules at the AuNP surfaces. Molecules involved in nanoparticle biosynthesis were identified at AuNP surfaces within algal cells, thus aiding in mechanism elucidation. The capabilities of Raman spectroscopy are endless, especially in light of SERS tag design, coordinating detection of analytes that do not inherently produce strong Raman vibrations. The increase in portable Raman spectrometer availability will only facilitate cheaper, more frequent application of Raman spectrometry both in the field and the lab. The tremendous detection power of the Raman spectrometer cannot be ignored. / Ph. D.

drop coating deposition Raman (DCDR)

cyanotoxin

microcystin-LR

cellular imaging

gold nanoparticles

intracellular biosynthesis

algae

Visualization, Characterization, and Analysis of Gold Nanoparticles Fate and Transport in Aqueous Porous Media Environment with Advanced Photonics Technique

Chan, Matthew Yunho

27 April 2017

Increased proliferation of nanotechnology has led to concerns regarding its implication to the water environment. Gold nanoparticles (AuNP) were used as a model nanomaterial to investigate the fate and dynamics of nanoparticles in the complex water environment. A column study was performed to examine the fate and transport of gold nanoparticles with two different coatings in porous media. The resulting data suggested that gold nanoparticles aggregate significantly in the porespace of the column interior, a finding that is not predicted by traditional colloidal filtration theory or Derjaguin-Landau-Verwey-Overbeek (DLVO) theory. Surface-enhanced Raman spectroscopy (SERS) was developed as a new technique to investigate AuNP aggregation in water with varying salt levels. The SERS technique proved valuable as an analytical technique, elucidating information about aggregation as well as AuNP surface interactions with dissolved halides in water. A thorough investigation examining Aunt aggregation with monovalent and divalent salts utilizing SERS, ultraviolet-visible light (UV-Vis) spectroscopy, and dynamic light scattering (DLS) was conducted. Each technique provided data describing different aspects of the dynamic behavior of AuNPs in complex water environments. Results suggest that in addition to attractive and repulsive interactions described by DLVO theory, chemical interactions between the AuNP surface and dissolved halides were also a significant driving force for aggregation and other transformative behaviors of AuNPs in water. The SERS technique developed in this work was shown to be a viable tool to help unveil the vastly complex dynamics of nanomaterial in the water environment. / Ph. D. / Nanotechnology is everywhere. It is in our smartphones, in our food, in our clothes, even if we do not recognize it is there. And this is a good thing, because nanotechnology – that is, technology that utilizes nanomaterials – can provide things that traditional technology often cannot. This is all because many nanomaterials have “superpowers” due to their size range: they are generally larger than what we may think of when we think of chemical molecules, but much smaller than macroscopic materials whose behaviors can be approximated by classic physics and chemistry. For example, we all know that gold has a shiny yellow metallic appearance. However, if we make little particles of gold – and these are going to be very tiny, with diameters about 10,000 times smaller than that of a strand of human hair (but about 100 times larger than what we would typically think of as molecules of chemicals) – and put them in water, the resulting mixture will be ruby-red like wine. One of the “superpowers” these gold nanoparticles possess is that they interact with light in a very different way than bulk gold. Currently, researchers in the biomedical field are producing promising work employing these particles in nextgeneration imaging, and much more. In this study, we were interested in what happens to these materials once they are released to the water environment. Because of the “superpowers” these gold nanoparticles possess, we really do not know how they will behave once they are released to either surface or groundwater because the physics and chemistry of those environments can be quite variable and complex. In this work, we have shown that traditional assumptions about particulate contaminants in water systems do not necessarily hold for gold nanoparticles. Laboratory simulations show that interactions between these particles and the surrounding environment that were once thought to be negligible, are in fact highly significant. As our title suggests, we are developing new and advanced “photonics” methods to help us discover the dynamic complexity dictating the fate of these gold nanoparticles once they are in the water environment. Photonics methods are techniques that employ light as a probing tool. These techniques use a well understood laser light source that is directed towards the particles in a water environment, and we then measure changes in the scattered light after it has interacted with the particles. The technique we have employed here (called surface-enhanced Raman spectroscopy, or SERS) simultaneously provides us information about different behaviors of gold nanoparticles in water, including how they may aggregate (that is, stick to one another and form big clumps) and how they interact with existing dissolved chemicals that may be present in the natural water environment. By pairing this method with other existing methods, we were able to paint a more complete picture of how these nanoparticles behave in the water environment, and we can answer some questions as to why they do not follow some previously held assumptions. In the end, the work in this dissertation will help future scientists continue to unlock the complexity of nanomaterial fate and dynamics in the water environment.

Environment

chemistry

nanotechnology

nanomaterials

nanoparticles

gold nanoparticles

groundwater

surface water

halide

Raman spectroscopy

surface-enhanced Raman spectroscopy

SERS

aggregation

deposition

DLVO

photons

Uv-vis

DLS

fate

Development of a Temperature Controlled Cell for Surface Enhanced Raman Spectroscopy for in situ Detection of Gases

Appelblad, André

January 2014

This work describes a master’s thesis in engineering physics at Umeå University carried out during the spring semester of 2014. In the thesis the student has constructed and tested a temperature controlled cell for cooling/heating of surface-enhanced-Raman-spectroscopy (SERS) substrates for rapid detection of volatile substances. The thesis was carried out at the Swedish Defence Research Agency (FOI) in Umeå, Sweden. A Linkam Scientific Instruments TS1500 cell was equipped with a Peltier element for cooling/heating and a thermistor temperature sensor. A control system was constructed, based on an Arduino Uno microcontroller board and a pulse-width-modulated (PWM) H-bridge motor driver to control the Peltier element using a proportional-integral (PI) control algorithm. The temperature controlled cell was able to regulate the temperature of a SERS substrate within -15 to +110 °C and maintain the temperature over prolonged periods at ±0.22 °C of the set point temperature. Gas phase of 2-chloro-2-(difluoromethoxy)-1,1,1-trifluoro-ethane (isoflurane) was flowed through the cell and SERS spectra were collected at different temperatures and concentrations. This test showed that the signal is increased when the substrate is cooled and reversibly decreased when the substrate was heated. Keywords: temperature control, Raman scattering, surface enhanced Raman spectroscopy SERS, SERS substrate, volatile substances, Peltier module, thermistor, PWM, H-bridge, PI(D) control. / Detta dokument beskriver ett examensarbete för civilingenjörsexamen i teknisk fysik vid Umeå Universitet som utförts under vårterminen 2014. I examensarbetet har en kyl-/värmecell för temperaturkontroll av substratytor för ytförstärkt ramanspektroskopi (SERS) för snabb detektion av farliga flyktiga ämnen konstruerats och testats. Arbetet utfördes vid Totalförsvarets forskningsinstitut (FOI) i Umeå, Sverige. Utgångspunkten var ett Linkam Scientific Instruments TS1500 mikroskopsteg, vilket utrustades med ett Peltierelement för kylning/värmning och en termistor för temperaturövervakning. Ett styrsystem baserat på ett Arduino Uno mikrostyrenhetskort konstruerades med ett motordrivkort (H-brygga) vilket använder pulsbreddsmodulering (PWM) för att reglera spänningen till Peltierelementet utifrån en PI-regulator. Den färdiga cellen klarade att reglera temperaturen på ett SERS-substrat i ett temperaturspann på ungefär -15 till +110 °C med en temperaturstabilitet på ±0.22 °C av måltemperaturen. Cellen testades sedan på flyktiga ämnen för att visa dess funktion. Difluorometyl-2,2,2-trifluoro-1-kloroetyleter (isofluran) i gasfas, med instrumentluft som bärargas, flödades genom cellen och SERS-spektra erhölls vid olika koncentrationer och temperaturer. Vid samtliga koncentrationer visades att lägre temperatur ger ökad signalstyrka. När ytan sedan värmdes upp sjönk signalen reversibelt tillbaka till ursprungsvärdet. Nyckelord: temperaturkontroll, ytförstärkt ramanspektroskopi, SERS, flyktiga ämnen, Peltierelement, thermistor, PWM, H-brygga, PI(D)-regulator.

temperature control

Raman scattering

surface enhanced Raman spectroscopy SERS

SERS substrate

volatile substances

Peltier module

thermistor

PWM

H-bridge

PI(D) control.

temperaturkontroll

ytförstärkt ramanspektroskopi

SERS

flyktiga ämnen

Peltierelement

thermistor

PWM

H-brygga

PI(D)-regulator.

Surface- and tip-enhanced resonant Raman scattering from CdSe nanocrystals

Sheremet, E., Milekhin, A. G., Rodriguez, R. D., Weiss, T., Nesterov, M., Rodyakina, E. E., Gordan, O. D., Sveshnikova, L. L., Duda, T. A., Gridchin, V. A., Dzhagan, V. M., Hietschold, M., Zahn, D. R. T.

27 February 2015

Surface- and tip-enhanced resonant Raman scattering (resonant SERS and TERS) by optical phonons in a monolayer of CdSe quantum dots (QDs) is demonstrated. The SERS enhancement was achieved by employing plasmonically active substrates consisting of gold arrays with varying nanocluster diameters prepared by electron-beam lithography. The magnitude of the SERS enhancement depends on the localized surface plasmon resonance (LSPR) energy, which is determined by the structural parameters. The LSPR positions as a function of nanocluster diameter were experimentally determined from spectroscopic micro-ellipsometry, and compared to numerical simulations showing good qualitative agreement. The monolayer of CdSe QDs was deposited by the Langmuir–Blodgett-based technique on the SERS substrates. By tuning the excitation energy close to the band gap of the CdSe QDs and to the LSPR energy, resonant SERS by longitudinal optical (LO) phonons of CdSe QDs was realized. A SERS enhancement factor of 2 × 10³ was achieved. This allowed the detection of higher order LO modes of CdSe QDs, evidencing the high crystalline quality of QDs. The dependence of LO phonon mode intensity on the size of Au nanoclusters reveals a resonant character, suggesting that the electromagnetic mechanism of the SERS enhancement is dominant. Finally, the resonant TERS spectrum from CdSe QDs was obtained using electrochemically etched gold tips providing an enhancement on the order of 10⁴. This is an important step towards the detection of the phonon spectrum from a single QD. / Dieser Beitrag ist aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

Ellipsometrie

Technische Universität Chemnitz

Allianzlizenz

Raman spectroscopy

Surface-enhanced Raman spectroscopy

Tip-enhanced Raman spectroscopy

Cadmium Selenide

Nanocrystals

Localized surface plasmon

Localized surface plasmon resonance

Ellipsometry

Electromagnetic enhancement

ddc:540

Ellipsometrie

Design, characterisation and biosensing applications of nanoperiodic plasmonic metamaterials / Conception, caractérisation et applications de métamatériaux nanopériodiques plasmoniques pour biocapteurs

Danilov, Artem

11 April 2018

Cette thèse considère de nouvelles architectures prometteuses des métamatériaux plasmoniques pour biosensing, comprenant: (I) des réseaux périodiques 2D de nanoparticules d'Au, qui peuvent supporter des résonances des réseaux de surface couplées de manière diffractive; (II) Reseaux 3D à base de cristaux plasmoniques du type d'assemblage de bois. Une étude systématique des conditions d'excitation plasmonique, des propriétés et de la sensibilité à l'environnement local dans ces géométries métamatérielles est présentée. On montre que de tels réseaux peuvent combiner une très haute sensibilité spectrale (400 nm / RIU et 2600 nm / RIU, ensemble respectivement) et une sensibilité de phase exceptionnellement élevée (> 105 deg./RIU) et peuvent être utilisés pour améliorer l'état actuel de la technologie de biosensing the-art. Enfin, on propose une méthode de sondage du champ électrique excité par des nanostructures plasmoniques (nanoparticules uniques, dimères). On suppose que cette méthode aidera à concevoir des structures pour SERS (La spectroscopie du type Raman à surface renforcée), qui peut être utilisée comme une chaîne d'information supplémentaire à un biocapteur de transduction optique. / This thesis consideres novel promissing architechtures of plasmonic metamaterial for biosensing, including: (I) 2D periodic arrays of Au nanoparticles, which can support diffractively coupled surface lattice resonances; (II) 3D periodic arrays based on woodpile-assembly plasmonic crystals, which can support novel delocalized plasmonic modes over 3D structure. A systematic study of conditions of plasmon excitation, properties and sensitivity to local environment is presented. It is shown that such arrays can combine very high spectral sensitivity (400nm/RIU and 2600 nm/RIU, respectively) and exceptionally high phase sensitivity (> 105 deg./RIU) and can be used for the improvement of current state-of-the-art biosensing technology. Finally, a method for probing electric field excited by plasmonic nanostructures (single nanoparticles, dimers) is proposed. It is implied that this method will help to design structures for SERS, which will later be used as an additional informational channel for biosensing.

Biocapteurs plasmoniques

Métamatériaux plasmoniques

Pslr

Spp

Lspr

Sers

Asnom

Plasmonic biosensors

Plasmonic metamaterials

Plasmonic Surface Lattice Resonances

Surface Plasmon Resonance

Localized Surface Plasmon Resonance

Surface Enhanced Raman Spectroscopy

539

Application of Raman and Fluorescence Spectroscopy to Single Chromatographic Beads

Larsson, Mina

January 2005

<p>Chromatography is a powerful technique, essential in chemical analyses and preparative separation in industry and research. Many different kinds of chromatographic material are needed, due to the large variety of applications. Detailed methods of characterisation are needed to design new chromatographic materials and understand their properties. In this thesis, confocal Raman spectroscopy and surface enhanced Raman spectroscopy (SERS) have been applied to micrometer-size chromatographic beads, for which these techniques have not been used earlier. New methodology, optimized for use with the chromatographic beads, has been developed and evaluated. </p><p>Confocal spectroscopy has been used to determine distributions of functional groups within single chromatographic beads. This distribution is of great importance in determining the chromatographic properties, since the material is porous and the solute molecules can diffuse inside the beads. Most of the confocal experiments have been performed with Raman spectroscopy; fluorescence spectroscopy, using Nd³⁺ ions or dye-labelled proteins as fluorescence probes, has been used for comparison. </p><p>The concentration of adsorbed analytes is very low within the beads. SERS was therefore used to enhance the Raman signal. SERS-active surfaces were prepared by incorporating gold nano-particles into the interior of the bead. TEM measurements showed that the gold nano-particles could be observed throughout, and it was possible to record analyte spectra from different positions within the bead. Enhanced spectra could be obtained both for small test molecules and for larger bio-molecules, although the spectra for the smaller analytes were much more intense.</p>

Chemistry

agarose

chelating group

confocal Raman spectroscopy

confocal scanning laser microscopy

gold nanoparticles

ligand distribution

functional group

neodymium

polymer beads

Raman

SERS

surface-enhanced Raman spectroscopy

Kemi

Chemistry

Kemi

Application of Raman and Fluorescence Spectroscopy to Single Chromatographic Beads

Larsson, Mina

January 2005

Chromatography is a powerful technique, essential in chemical analyses and preparative separation in industry and research. Many different kinds of chromatographic material are needed, due to the large variety of applications. Detailed methods of characterisation are needed to design new chromatographic materials and understand their properties. In this thesis, confocal Raman spectroscopy and surface enhanced Raman spectroscopy (SERS) have been applied to micrometer-size chromatographic beads, for which these techniques have not been used earlier. New methodology, optimized for use with the chromatographic beads, has been developed and evaluated. Confocal spectroscopy has been used to determine distributions of functional groups within single chromatographic beads. This distribution is of great importance in determining the chromatographic properties, since the material is porous and the solute molecules can diffuse inside the beads. Most of the confocal experiments have been performed with Raman spectroscopy; fluorescence spectroscopy, using Nd3+ ions or dye-labelled proteins as fluorescence probes, has been used for comparison. The concentration of adsorbed analytes is very low within the beads. SERS was therefore used to enhance the Raman signal. SERS-active surfaces were prepared by incorporating gold nano-particles into the interior of the bead. TEM measurements showed that the gold nano-particles could be observed throughout, and it was possible to record analyte spectra from different positions within the bead. Enhanced spectra could be obtained both for small test molecules and for larger bio-molecules, although the spectra for the smaller analytes were much more intense.

Chemistry

agarose

chelating group

confocal Raman spectroscopy

confocal scanning laser microscopy

gold nanoparticles

ligand distribution

functional group

neodymium

polymer beads

Raman

SERS

surface-enhanced Raman spectroscopy

Kemi

Chemistry

Kemi

Spectroelectrochemistry of self-assembled monolayers of 2- and 4-mercaptopyridines

Hassan, Nazly

10 July 2007

Die Elektrochemie und die Spektroelektrochemie von selbst-organisiererten Monoschichten (selfassembled monolayers, SAMs) gebildet aus 2-Mercaptopyridin (2MP) und 4-Mercaptopyridin (4MP) wurden an polykristallinen Goldelektroden in wässrigen Elektrolytlösungen untersucht. Folgende Untersuchungsmethoden wurden angewandt: zyklische Voltammetrie, elektrochemische Impedanzmessungen (EIM) und oberflächenverstärkte Raman Streuung (surface-enhanced Raman scattering, SERS). Die elektrochemischen Untersuchungen von 2MP und 4MP in wässriger saurer Lösung (0.5 M H2SO4) zeigten, dass 2MP stärker adsorbiert wird als 4MP aufgrund der Bildung eines S-Au-N Chelates, wobei die S-Au-Interaktionen bei 4MP stärker sind. Die Bildung eines Chelates im Falle von 2MP verringert die Wahrscheinlichkeit der Bildung eines Dimers. In sauren Lösungen wird das N-Atom von 2MP protoniert, was zu einer schwächeren Bindung von 2MP-Molekülen zur Substratoberfläche führt. Die Ergebnisse der SERS-Untersuchungen stimmen mit den Resultaten aus der zyklischen Voltammetrie überein. Man erhält eine Au-S-Streckschwingungsbande für 2MP zwischen 225 bis 250 cm-1 bei Abscheidung aus wässriger oder saurer Lösung und für 4MP bei ca. 263 cm-1 in beiden Lösungen. Die SERS-Experimente ergaben eine senkrechte Orientierung zur Goldoberfläche sowohl für 2MP als auch für 4MP. Die Thion-Thiol-Tautomerie von 2- Mercaptopyridinen wurde ebenfalls in Betracht gezogen. Die Unter- und Überpotentialabscheidung von Kupfer auf einer polykristallinen Goldelektrode in wässriger 0.1 M Schwefelsäure in An- und Abwesenheit von SAMs von 2- und 4- Mercaptopyridin wurde mit zyklischer Voltammetrie untersucht. Es zeigte sich, daß bei Vorhandensein der SAMs die Elektrodeposition von Kupfer verhindert wird, was auf starke Wechselwirkungskräfte zwischen dem Adsorbat (MP) und der Goldoberfläche zurückzuführen ist. 2MP zeigt eine grössere Inhibierung, was höchstwahrscheinlich auf die Bildung der Chelatstruktur zurückzuführen ist. Es wurden ebenso Untersuchungen zum Einfluss von 2MP und 4MP auf die abgeschiedene Kupfermonolage auf der Goldelektrode durchgeführt. Es zeigte sich, daß die Kupfermonolage teilweise durch 2MP oder 4MP ersetzt wird. Die Elektronenaustauschgeschwindigkeit für das Fe2+/Fe3+-Redoxsystem in An- und Abwesenheit von 2MP- oder 4MP-Monolagen wurde mit zyklischer Voltammetrie und elektrochemischen Impedanzmessungen (EIM) untersucht. Es stellte sich heraus, dass der Elektronenaustausch höchstwahrscheinlich über Defektstellen in der Monolage (Pinholes) erfolgt. In einer wässrigen Lösung verringert 4MP den Elektronenaustausch stärker als 2MP. Da die Packungsdichte bei 4MP größer ist als bei 2MP ist wahrscheinlich auch die Zahl der Pinholes geringer in der 4MP-Monolage. In saurer Lösung liegen die N-Atome protoniert vor. Man kann davon ausgehen, dass in saurer Lösung zwei Prozesse gleichzeitig ablaufen, die für den Elektronenaustausch entscheidend sind. Erstens kommt es zu einer Abstoßung zwischen der positiv geladenen Monolage und den positiv geladenen Redoxionen. Und zweitens erfolgt eine Abstoßung zwischen den positiv geladenen Molekülen der SAMs, was zu einer geringeren Packungsdichte führt. Der Ladungsaustausch wird dominiert durch den zweiten Effekt. Mit Hilfe von EIM wurden die Elektronenaustauschgeschwindigkeit und der Bedeckungsgrad bestimmt. Die korrosionshemmende Wirkung von 2MP und 4MP auf Stahl in 3.5 % wässriger NaCl-Lösung wurde mit Hilfe der EIM untersucht. 2MP zeigte eine grössere Hemmung als 4MP. / The electrochemistry and spectroelectrochemistry of the self-assembled monolayers (SAMs) prepared of 2-mercaptopyridine (2MP) and 4-mercaptopyridine (4MP) dissolved either in water or 0.1 M H2SO4 have been investigated at polycrystalline gold electrodes in aqueous electrolyte solutions using cyclic voltammetry, electrochemical impedance measurements (EIM) and surface enhanced Raman spectroscopy (SERS). Electrochemical studies of 2MP and 4MP monolayers in aqueous acidic solution (0.5 M H2SO4) suggest that 2MP is adsorbed more strongly than 4MP due to the formation of S-Au-N chelate. However, the S-Au bond was found to be stronger in 4MP as compared with 2MP. The formation of the chelate in case of 2MP diminishes the probability of dimer formation. In the acidic solvent, the N-atom of 2MP molecule will be protonated leading to a weaker interaction of 2MP molecules with the substrate surface. The SERS results are in good agreement with the cyclic voltammetry results. The Au-S stretching band was obtained in the region from 215 to 245 cm-1 for 2MP deposited from water and acidic solvent and around 263 cm-1 for 4MP in both solvents. The SERS measurements showed also a perpendicular orientation of both 2MP and 4MP on the gold surface. In explaining the SERS results, the thione-thiol tautomerisations of the mercaptopyridines were also taken into consideration. The under- and overpotential deposition of copper on a polycrystalline gold electrode in aqueous 0.1 M sulfuric acid in the presence and in the absence of SAMs of 2- and 4-mercaptopyridine has been studied using cyclic voltammetry. In general, the presence of these SAMs has been found to inhibit the electrodeposition process of copper, suggesting very strong interactions between these adsorbates and the Au surface. 2MP shows a higher degree of inhibition, which is due to a stronger interaction probably due to the formation of the chelate structure. Studies have also been made of the influence of mercaptopyridines SAMs on the copper monolayer electrodeposited on the gold surface. The copper adlayer was found to be partially displaced by 2MP and 4MP monolayers. The rate of electron transfer for the Fe3+/2+ redox system on the gold electrode has been probed in the absence and presence of 2MP and 4MP monolayers by cyclic voltammetry and electrochemical impedance measurements (EIM). The charge transfer process was suggested to occur through the defects (pinholes) in the monolayer. In case of aqueous solvent 4MP decreases the electron transfer reaction stronger than 2MP. Since the packing density for 4MP is higher than that of 2MP the number of pinholes might be lower in 4MP monolayer. In acidic solvent the N-atoms of the mercaptopyridines will be protonated. It is proposed that two effects, which exist at the same time, are responsible for the electron transfer process in acidic solution. First, there will be a repulsive interaction between the positively charged monolayer and the positively charged redox probe. Second, there is a repulsion among the positively charged monolayer molecules that results in a less compact monolayer. The charge transfer is dominated due to the latter effect. With the EIM the rate of electron transfer and the surface coverage were determined. 2MP and 4MP were examined as steel corrosion inhibitors in 3.5% aqueous NaCl solution using EIM. 2MP shows higher inhibition efficiency than 4MP.

2- und 4-Mercaptopyridin

Corrosion inhibition

Cyclic Voltammetry

Electrochemical impedance measurements

Electrochemistry

Electron transfer

Self-assembled monolayers

Spectroelectrochemistry

Surface enhanced Raman spectroscopy

Zyklische Voltmmetrie

selbst-organisierende Monoschichten

ddc:540

Elektrochemie

Elektronentransfer

Korrosionsinhibierung

Spektroelektrochemie

Development of Epidermal Growth Factor Receptor (EGFR) Specific Nanoprobes for Surface Enhanced Raman Spectroscopy (SERS)

Lucas, Leanne Jennifer

29 July 2013

Novel biocompatible nanoprobes for optical imaging of Epidermal Growth Factor receptor (EGFR) were created. 5 and 18 nm gold nanoparticles (AuNPs) and 5 and 45 nm diameter silver nanoparticles (AgNPs) were conjugated to EGF protein via ?-lipoic acid. AgNPs were not previously attached to EGF. TOF-MS confirms EGF-linker formation. ELISA verifies the linked-EGF activity alone and with EGF-NPs. Core-shell silver-gold nanoparticles (AgAuNPs) gave similar results. TEM staining with uranyl acetate exhibits a bright ring, smaller than EGF, around nanoparticles. Dark field microscopy shows localized, intense cytoplasmic scattering, possibly lipid droplets, in cancer cells incubated with or without nanoprobes. Following injection, mice organs were harvested for EGF-NP immune response determination. Sterilization likely inactivated EGF before ICP-MS. Intense surface enhanced Raman scattering (SERS, 632.8 nm) follows MgSO4 induced EGF-AgNPs aggregation. Pelleted EGF-AgNP tagged cancer cells lack SERS indicative intensity contrast. AgAuNPs could provide increased stability, brighter SERS, and reduced silver biocompatibility concerns.