Characterization of histone post-translational modification using reversed-phase high performance liquid chromatography and fourier transform ion cyclotron resonance mass spectrometry

Zhang, Liwen

01 October 2003

No description available.

Chemistry, Analytical

Histone Post-translational Modification

Peptide Mapping

Tandem Mass Spectrometry

Identification des produits de dégradation d’un solvant aminé régénérable permettant la capture de CO2

Lapointe, Anthony

04 1900

Le réchauffement de la planète est une préoccupation mondiale à notre époque. Celui-ci peut s’expliquer en partie par les grandes émissions de CO2 dans l’atmosphère depuis le début de l’industrialisation. Parmi les plus grands émetteurs de CO2, il y a entre autres les véhicules motorisés, le chauffage au charbon et les raffineries de pétrole. Depuis quelques années, un processus commence à être utilisé pour réduire les émissions de CO2 atmosphérique. Ce processus est la capture du CO2 par des solvants aminés régénérables. Dans le cadre de ma recherche, des échantillons d’un solvant aminé qui ont subi un traitement de capture et de régénération du CO2 et qui ont passé différents temps dans ces processus ont été analysés pour déterminer les différents produits de dégradation de ce solvent. L’identification des produits de dégradation permet d’optimiser la méthode de capture du CO2 pour éviter leur production et donc garder son efficacité le plus longtemps possible. La chromatographie liquide couplée à la spectrométrie de masse (LC-MS) a été utilisée pour séparer et identifier les différents produits de dégradation. L’utilisation de la spectrométrie de masse à haute résolution (HRMS) a permis l’identification des formules chimiques les plus probables pour les produits de dégradation présents. L’ajout d’une cellule de collision à la HRMS a permis d’obtenir plus d’information par fragmentation sur les différents groupes fonctionnels et donc sur la structure des composés inconnus. Lorsque les structures possibles sont peu nombreuses pour une telle formule chimique, des étalons ont été utilisés pour comparer les spectres obtenus et confirmer les structures. Pour les composés ayant trop de possibilités de structures moléculaires, d’autres méthodes d’analyse ont été effectuées, telle la chromatographie gazeuse couplée à la spectrométrie de masse (GC-MS), la spectrométrie à mobilité ionique et la spectroscopie à résonnance magnétique nucléaire (NMR) suite à une collecte de fractions en chromatographie liquide. Au final, aucun nouveau produit de dégradation n’a pu être identifié avec une certitude de 100 %. Le niveau de confiance envers la structure proposée est par contre assez élevé pour certains d’entre eux, mais la difficulté d’obtention d’étalons rend l’identification assez exigeante. L’ensemble de ces travaux de mémoire a été réalisé dans le cadre d’un partenariat industriel. Une autre partie du projet était le développement d’une méthode pour détecter et quantifier deux N-nitrosamines à une concentration de 1 µg/L. La validation de la méthode pour la quantification des nitrosamines a également été effectuée. Les deux nitrosamines sont des résidus des processus de dégradation des amines du partenaire industriel et il est recommandé que leur concentration soit inférieure à 1 µg/L lors du rejet des eaux usées dans une étendue d’eau naturelle (US Environnemental Protection Agency). Il est donc important de les déterminer pour éviter de contaminer les cours d’eaux. La méthode développée utilise une extraction liquide sur support solide comme préparation d’échantillon ainsi qu’une méthode LC-MS pour la séparation et la quantification. La plus grande quantité retrouvée d’une des deux nitrosamines est de 7,30 µg/L, ce qui est légèrement au-dessus des recommandations. / Global warming is one of the most important concerns of this century. It can be associated in major part to CO2 emissions into the atmosphere since the beginning of industrialization. The major CO2 emitters are motorized vehicles, coal heating and oil refineries. Some years ago, a scrubbing process started being used to reduce atmospheric emissions of CO2 from coal burning plants. This process is known as CO2 capture by regenerable amine-based solvents. As part of this master’s research, samples from an amine-based solvent that was subjected to CO2 capture for different amounts of time during the capture regeneration process were analyzed to determine the various degradation products formed from the capture solvent. Identification of the degradation products and their kinetics of formation allow optimization of the CO2 capture method, ideally to avoid their formation and to maximize the efficiency of the capture process over a longer period of use. Liquid chromatography coupled to mass spectrometry (LC-MS) was used to initially select various degradation products present in reasonable abundance. The use of high resolution mass spectrometry (HRMS) allowed the identification of the most probable chemical formulas for the degradation products found in the capture solvent. Addition of a collision cell to HRMS provided more information on the different functional groups by MS fragmentation, and therefore more structural information on the unknown compounds. When there were a few possible structures for a single unknown compound, standards were used to compare the MS spectra obtained and confirm the structures. For the unknown compounds with too many plausible structures, additional analysis methods were used, like gas chromatography coupled to mass spectrometry (GC-MS), ionic mobility mass spectrometry and nuclear magnetic resonance (NMR) after fraction collection by preparative liquid chromatography. No degradation products were identified with 100 % certainty. The level of confidence towards proposed structures was quite high for some of the unknowns; however, the standards needed to confirm their identification were too costly to synthesize. This entire master’s project was carried out in collaboration with an industrial partner. A secondary part of this master’s project involved the development of a method to detect and quantify two N-nitrosamines at a concentration of 1 µg/L. Validation of the method for the quantification of the two N-nitrosamines was also carried out. The two analytes were residues of the degradation process of a different amine-based CO2 capture solvent where the recommended concentration of the residues should be under 1 µg/L when releasing the wastewater into environmental waters (US Environnemental Protection Agency). It is therefore important to determine these N-nitrosamines to avoid contamination of water bodies. The developed method used solid-supported liquid-liquid extraction (SLE) for sample preparation and LC-MS for separation and quantification. The highest amount of one of the two N-nitrosamines found in the samples supplied by the industrial partner was 7.30 µg/L, which was over the recommended level.

Spectrométrie de masse

Capture de CO2

Chromatographie liquide

Solvants aminés régénérables

Séparations analytiques

Mass spectrometry

CO2 capture

Liquid chromatography

Regenerable amine solvent

Analytical separations

The Formation of Two Dimensional Supramolecular Structures and Their Use in Studying Charge Transport at the Single Molecule Level at the Liquid-Solid Interface

Afsari Mamaghani, Sepideh

January 2015

Understanding charge transport through molecular junctions and factors affecting the conductivity at the single molecule level is the first step in designing functional electronic devices using individual molecules. A variety of methods have been developed to fabricate metal-molecule-metal junctions in order to evaluate Single Molecule Conductance (SMC). Single molecule junctions usually are formed by wiring a molecule between two metal electrodes via anchoring groups that provide efficient electronic coupling and bind the organic molecular backbone to the metal electrodes. We demonstrated a novel strategy to fabricate single molecule junctions by employing the stabilization provided by the long range ordered structure of the molecules on the surface. The templates formed by the ordered molecular adlayer immobilize the molecule on the electrode surface and facilitate conductance measurements of single molecule junctions with controlled molecular orientation. This strategy enables the construction of orientation-controlled single molecule junctions, with molecules lacking proper anchoring groups that cannot be formed via conventional SMC methods. Utilizing Scanning Tunneling Microscopy (STM) imaging and STM break junction (STM-BJ) techniques combined, we employed the molecular assembly of mesitylene to create highly conductive molecular junctions with controlled orientation of benzene ring perpendicular to the STM tip as the electrode. The long range ordered structure of mesitylene molecules imaged using STM, supports the hypothesis that mesitylene is initially adsorbed on the Au(111) with the benzene ring lying flat on the surface and perpendicular to the Au tip. Thus, long range ordered structure of mesitylene facilitates formation of Au-π-Au junctions. Mesitylene molecules do not have standard anchoring groups providing enough contact to the gold electrode and the only assumable geometry for the molecules in the junction is via direct contact between Au and the π system of the benzene ring in mesitylene. SMC measurements for Au/mesitylene/Au junctions results in a molecular conductance value around 0.125Go, two orders of magnitude higher than the measured conductance of a benzene ring connected via anchoring groups. We attributed this conductance peak to charge transport perpendicular to the benzene ring due to direct coupling between the π system and the gold electrode that happens in planar orientation. The conductance we measured for planar orientation of benzene ring is two order of magnitude larger than conductance of junctions formed with benzene derivatives with conventional linkers. Thus, altering the orientation of a single benzene-containing molecule between the two electrodes from planar orientation to the upright attached via the linkers, results in altering the conductivity in a large order. Based on these findings, by utilizing STM imaging and STM-BJ in an electrochemical environment including potential induced self-assembly formation of terephthalic acid, we designed an electrochemical single molecule switch. Terephthalic acid forms large domains of ordered structure on negatively charged Au(111) surface under negative electrochemical surface potentials with the benzene ring lying flat on the surface due to hydrogen bonding between carboxylic acid groups of neighboring molecules. Formation of long range ordered structure facilitates direct contact between the π system of the benzene ring and the gold electrodes resulting in the conductance peak. On positively charged Au(111), deprotonation of carboxylic acid groups leads to absence of long range ordered structure of molecules with planar orientation and absence of the conductance peak. In this case alternating the surface (electrode) potential from negative to positive charge densities induces a transition in the adlayer structure on the surface and switches conductance value. Hence, electrochemical surface potential can, in principle, be employed as an external stimulus to switch single molecule arrangement on the surface and the conductance in the junction. The observation of conductance switching due to molecule’s arrangement in the junction lead to the hypothesis that for any benzene derivative, an orientation-dependent conductance in the junction due to the contact geometry (i.e. electrode-anchoring groups versus direct electrode-π contact) should be expected. Conventional techniques in fabricating single molecule junctions enable accessing charge transport along only one direction, i.e., between two anchoring groups. However, molecules such as benzene derivatives are anisotropic objects and we are able to measure an orientation-dependent conductance. In order to systematically study anisotropic conductivity at single molecule level, we need to measure the conductance in different and well-controlled orientations of single molecules in the junction. We employed the same EC-STM-BJ set up for SMC measurements and utilize electrochemical potential of the substrate (electrode) as the tuning source to variate the orientation of the single molecule in the junction. We investigated single molecule conductance of the benzene rings with carboxylic acid functional groups in two orientations: one with the benzene ring bridging between two electrodes using carboxylic acids as anchoring groups (upright); and one with the molecule lying flat on the substrate perpendicular to the STM tip (planar). Physisorption of these species on the Au (111) single crystal electrode surface at negative electrochemical potentials results in an ordered structure with the benzene ring in a planar orientation. Positive electrochemical potentials cause formation of the ordered structure with molecules standing upright due to coordination of a deprotonated carboxyl groups to the electrode surface. Thus, formation of the single molecule junction and consequently conductivity measurements is facilitated in two directions for the same molecule and anisotropic conductivity can be studied. In engineering well-ordered two-dimensional (2-D) molecular structures with controlled assembly of molecular species, pH can be employed as another tuning source for the molecular structures and adsorption in experiments conducted in aqueous solutions. Based on simple chemical principles, amine (NH2) groups are hydrogen bond acceptors and donors. Amines are soluble in water and protonation results in protonated (NH3+) and unprotonated (NH2) amine groups in acidic and moderately acidic/neutral solutions, respectively. Thus, amines are suitable molecular building blocks for fabricating 2-D supramolecular structures where pH is employed as a knob to manipulate intermolecular hydrogen bonding leading to phase transitions. We investigated pH induced structural changes in the 1,3,5–triaminobenzene (TAB) monolayer and the formation/disruption of hydrogen bonds between neighboring molecules. Our STM images indicate that in the concentrated acidic solution, the protonated amine groups of TAB are not able to form H-bonds and long range ordered structure of TAB does not form on the Au(111) surface. However, in moderately acidic solution (pH ~ 5.5) at room temperature, protonation on the ring carbon atom generates species capable of forming H-bonds leading to the formation of the long range ordered structures of TAB molecules. Utilizing EC-STM set up, we investigated the controllable fabrication of a TAB 2-D supramolecular structure based on amine-amine hydrogen bonding and effect of pH in formation of ordered/disordered TAB network. / Chemistry

Chemistry

Chemistry, Analytical

Chemistry, Physical

Molecular Electronics

Scanning Tunneling Microscopy

Self-assembled Monolayers

Single Molecule Conductivity

Stm- Break Junction

Synthesis, Characterization, Standardization, and Validation of Luminescence Optical Chemosensors for the Detection of Carbon Dioxide, Aluminum Ions, and Silver Ions for Real-Life Applications

Perera, Nawagamu Appuhamilage Kasun

12 1900

The presented dissertation encompasses three distinct investigations into novel complexes with diverse applications. Firstly, a Europium-based complex, K[Eu(hfa)4], exhibits remarkable potential for detecting dissolved CO2 in an ethylene glycol medium, offering a low limit of detection, rapid response times, and high signal-to-noise ratios. This complex demonstrates promise for quantifying CO2 concentrations and finds utility in sugar fermentation monitoring. Secondly, an innovative ratiometric optical sensor, Eu(tta)3([4,4'-(t-bu)2-2,2'-bpy)], showcases exceptional sensitivity and selectivity in detecting aluminum ions, making it suitable for environmental and biological applications. It exhibits reliable quantification in both methanol and aqueous samples, with remarkable accuracy validated by ICP-OES. Lastly, modifications to the Au3Pz3 complex synthesis enable the development of a silver ion sensor, paving the way for detecting silver ion leaching in real-life scenarios, such as silver nanoparticle-embedded bandages. The research extends to the synthesis of silver nanoparticles using various methods and foresees expanded in vitro and in vivo studies. These investigations collectively offer insights into the development of advanced sensing technologies with significant implications for a wide range of practical applications.

Europium

chemosensors

Carbon dioxide sensor

Aluminum sensor

Silver ion sensor

Diketones

Real-life applications of chemosensors

Luminescence

Chemistry, Inorganic

Chemistry, Analytical

Chemistry, Organic

Chemically Optimized Cu Etch Bath Systems for High-Density Interconnects and the FTIR Operando Exploration of the Nitrogen Reduction Reaction on a Vanadium Oxynitride Electrocatalyst

Caperton, Joshua M

08 1900

Printed circuit board manufacturing involves subtractive copper (Cu) etching where fine features are developed with a specific spatial resolution and etch profile of the Cu interconnects. A UV-Vis ATR metrology, to characterize the chemical transitions, has been developed to monitor the state of the bath by an in-situ measurement. This method provides a direct correlation of the Cu etch bath and was able to predict a 35% lower etch rate that was not predicted by the three current monitoring methods (ORP, specific gravity, and conductivity). Application of this UV-Vis ATR probe confirmed that two industrial etch baths, in identical working conditions, confirmed a difference in Cu2+ concentration by the difference of the near IR 860nm peak. The scope of this probe allowed chemically specific monitoring of the Cu etch bath to achieve a successful regeneration for repeated use. Interlayer dielectrics (ILDs) provide mechanical and electrical stability to the 3D electrical interconnects found in IC devices. It is particularly important that the structural support is created properly in the multilayered architecture to prevent the electrical cross signaling in short range distances. A combined multiple internal reflection and transmission FTIR has been employed for the characterization of silicon oxycarbonitride (SiOCN) films. These dielectric low-k films incorporate various functional groups bonded to silicon and require chemical bonding insight in the transformation and curing process. Distinct SiOx bonding patterns were differentiated, and the structure of the films can be predicted based on the amount of Si network and caged species. Further optimization of the FTIR analysis must minimize interference from moisture that can impact the judgement of peak heights. To accommodate this, a high-quality glove box was designed for dry air feedthrough to achieve a 95% moisture reduction during analysis, where less than 0.1 mAbs of moisture is detected in the spectra (without additional correction). The glove box allows for the rapid analysis of multiple sample throughput to outpace alternative characterization methods while retaining low spectral noise and a dry environment for 24/7 analysis. There is a great need to identify new catalysts that are suitable for tackling current economic demands, one of which is the nitrogen reduction reaction (NRR). The development of the surface enhanced infrared absorption spectroscopy (SEIRAS) has been applied to characterize the NRR mechanisms on the vanadium oxynitride electrocatalyst. Electrochemical measurements demonstrate NRR activity that is up to three times greater in the presence of N2 than the control Ar. FTIR operando suggests that a considerable number of intermediates were formed and continued to increase in absorbing value under an applied potential of -0.8 V vs Ag/AgCl. XPS results of the post-NRR film suggest a restricting of the film where vanadium oxynitride films are prone to instabilities under the possible MvK mechanism. After 90 minutes of NRR, the NH3 generated was approximately 0.01 ppm was calculated for through the salicylate colorimetric method. On-going efforts are focusing on optimizing the vanadium oxynitride film by the tuning of the oxynitride ratios and crystalline properties to promote the formation of V≡N: during the nitrogen reduction reaction.

Cu etch bath

anisotropic etching

low-k

dielectrics

multiple internal reflection

FTIR spectroscopy

operando

spectroelectrochemistry

electrocatalyst

vanadium oxynitride

nitrogen reduction reaction

Chemistry, Analytical

A Comprehensive Investigation of Photoinduced Electron Transfer and Charge Transfer Mechanisms in Push-Pull Donor-Acceptor Systems: Implications for Energy Harvesting Applications

Alsaleh, Ajyal Zaki

12 1900

Donor-acceptor systems exhibit distinctive attributes rendering them highly promising for the emulation of natural photosynthesis and the efficient capture of solar energy. This dissertation is primarily devoted to the investigation of these unique features within diverse donor-acceptor system typologies, encompassing categories such as closely covalently linked, push-pull, supramolecular, and multi-modular donor- acceptor conjugates. The research encompasses an examination of photosynthetic analogs involving compounds such as chelated azadipyromethene (AzaBODIPY), N,N-dimethylaminophenyl (NND), phenothiazine (PTZ), triphenylamine (TPA), phenothiazine sulfone (PTZSO2), tetracyanobutadiene (TCBD), and expanded tetracyanobutadiene (exTCBD). The strategic configuration of the donor (D), acceptor (A), and spacer elements within these constructs serves to promote intramolecular charge transfer (ICT), which are crucial for efficient charge and electron transfer. The employment of cutting-edge analytical techniques, such as ultrafast transient absorption spectroscopy, is integral to the study. Furthermore, a comprehensive suite of analytical methodologies including steady-state UV-visible absorption spectroscopy, fluorescence and phosphorescence spectroscopies, electrochemical techniques (including cyclic voltammetry and differential pulse voltammetry), spectroelectrochemistry, and density functional theory calculation (DFT), collectively contribute to the comprehensive characterization of push-pull donor-acceptor systems, with a particular emphasis on their potential as highly effective solar energy harvesting application.

Ultrafast spectroscopy

excited-state charge separation

azaBODIPY

Charge transfer

push-pull systems

donor-acceptor constructs

Tetracyanobutadiene (TCBD)

and phenothiazine

Chemistry, Analytical

Chemistry, Physical

Chemistry, Organic

Preparation, Characterization and Structural Study of Silane Functionalized Organic and Inorganic Intercalated Zn-Al Layered Double Hydroxides and Their Polymeric Coatings

Aminifazl, Alireza

05 1900

Adding layered double hydroxides (LDHs) to polymer compounds has been shown to make them more resistant to corrosion and improve their physical and chemical properties. However, the main challenge lies in the compatibility between inorganic LDH fillers and organic polymer matrices. The incompatibility between these two is due to differences in polarity and surface properties, which makes dispersion of LDHs within the polymer very difficult, negatively affecting the final material's performance and characteristics. In this work, Zn-Al-NO3 LDH particles were synthesized through co-precipitation method and then modified by decavanadate via the anion exchange process. Then, a silane coupling agent was used to functionalize intercalated LDH particles to make them more hydrophobic; this helped the particles to disperse well inside epoxy coating, which ultimately resulted in better corrosion inhibition performance for the coating. The concentration effect of silane coupling agent on LDHs' surface grafting was also studied using various concentrations of 3-aminopropyltriethoxy silane (APTES). Compositional and structural characterization study on revealed more insight into how the surface treatments worked. Finally, to modify LDHs, sodium dodecyl sulfate was inserted in LDH structure, then APTES molecules were grafted on the dodecyl sulfate intercalated LDHs' surface. These organic intercalation and grafting steps made LDHs more suitable with acrylic resin to form uniform composite mixture through solvent solution mixing. The thermal stability of acrylic coating improved by adding modified hybrid LDH fillers and elevation in decomposition temperature was confirmed using thermogravimetric analysis.

Zn-Al LDH

Decavanadate

Silane coupling agent

Epoxy coating

Corrosion protection

XRD

FTIR

TGA

Contact Angle measurement

SEM-EDAX

sodium dodecyl sulfate

Acrylic composite

Chemistry, Analytical

Chemistry, Polymer

Développement d’une méthode d’extraction des contaminants émergents dans les solides particulaires par LDTD-APCI-MS/MS

Darwano, Hicham

11 1900

Douze contaminants émergents (composés pharmaceutiques, pesticides et hormones) ont été quantifiés et extraits de l'eau de rivières et d’échantillons d'eaux usées municipales. La séparation des solides en suspension est effectuée par filtration des échantillons d'eau. L'effet de filtration sur les concentrations de contaminants dissous a été évaluée afin de minimiser les pertes de composés cibles. Les échantillons ont été lyophilisés et ont été extraits en deux cycles par ultrasons combinés avec une étape de nettoyage sur cartouche d’extraction de type C18. La quantification a été réalisée en utilisant la spectrométrie de masse. Les recouvrements de la méthode pour tous les composés ont varié de 68 à 112% dans toutes les matrices étudiées, sauf pour le sulfaméthoxazole et le diclofénac où des recouvrements plus modestes ont été obtenus (38 à 85%). Les limites de détection pour les 12 analytes dans les sédiments et particules en suspension (SPM) de la rivière variaient de 0,7 à 9,4 ng g-1 et de 21 à 92 ng g-1, pour les échantillons SPM de station d'épuration. Tous les contaminants émergents cibles ont été détectés à des concentrations variant de 3 à 5440 ng g-1 dans les matrices étudiées, les concentrations les plus élevées ont été observées dans les échantillons SPM de stations d'épuration. Une partie importante de certains de ces contaminants est clairement associée aux sédiments de rivière ou aux particules en suspension. L’optimisation des processus de traitement de l'eau et le devenir environnemental doit absolument tenir compte de la fraction de contaminants qui liée à des particules si on espère avoir un bilan de masse raisonnable. / We developed a protocol to quantify 12 emerging contaminants (pharmaceuticals and hormones) and pesticides extracted from suspended particulate matter (SPM) of river water and municipal wastewaters samples. The separation of suspended solids was carried through filtration of water samples. We tested a series of 6 different filter types. The effect of filtration on the concentrations of dissolved contaminants was evaluated in order to minimize losses of target compounds. The river bottom sediments samples were lyophilized and both SPM and sediment samples were subjected to ultrasonic extraction combined with C18 cartridge clean-up. Quantifications were realized using mass spectrometry. The overall method recoveries of all compounds ranged from 38 to 112 % in all studied matrices, poor recoveries were achieved for sulfamethoxazole and diclofenac (recoveries for all other compounds in the wastewater treatment plant (WWTP) samples were 68 to 111%). The detection limits in sediments and SPM from river samples for the 12 analytes varied from 0.7 to 9.4 ng g-1 and from 21 to 92 ng g-1 for WWTP SPM samples. All target emerging contaminants were detected with concentrations ranging from 3 to 5440 ng g-1 in the studied matrices, with the highest concentrations observed in WWTP SPM samples. A significant portion of some of those contaminants is clearly associated with bottom sediments or suspended particulates. Optimization of water treatment processes and environmental fate must absolutely consider the fraction of contaminants which is particulate-bound if one hopes to have a reasonable mass balance.

Contaminants émergents

Boues d’épuration

Eaux usées

Station d’épuration

LDTD

Filtration

Extraction

Particules en suspension,

Suspended particulate matter

Emerging contaminants

Sewage sludge

Wastewater treatment plant

Propriétés optiques et analytiques des nanotrous : vers la conception de biocapteurs en résonance des plasmons de surface localisés

Murray Méthot, Marie-Pier

12 1900

Les biocapteurs sont utilisés quotidiennement pour déterminer la présence de molécules biologiques dans une matrice complexe, comme l’urine pour les tests de grossesses ou le sang pour les glucomètres. Les techniques courantes pour la détection des autres maladies nécessitent fréquemment le marquage de l’analyte avec une autre molécule, ce qui est à éviter pour fin de simplicité d’analyse. Ces travaux ont pour but la maximisation de la sensibilité d’une surface d’or ou d’argent nanotrouée, afin de permettre la détection de la liaison de molécules biologiques par résonance des plasmons de surface localisés (LSPR), en utilisant la spectroscopie de transmission. Un biocapteur portable, rapide et sans marquage pour quantifier des analytes d’intérêt médical ou environnemental pourrait être construit à partir de ces travaux. Dans l’objectif d’étudier de nombreuses configurations pour maximiser la sensibilité, le temps et le coût des méthodes de fabrication de nanostructures habituelles auraient limité le nombre de surfaces nanotrouées pouvant être étudiées. Un autre objectif du projet consiste donc au développement d’une technique de fabrication rapide de réseaux de nanotrous, et à moindres coûts, basée sur la lithographie de nanosphères (NSL) et sur la gravure au plasma à l’oxygène (RIE). La sensibilité à la variation d’indice de réfraction associée aux liaisons de molécules sur la surface du métal noble et la longueur d’onde d’excitation du plasmon de surface sont influencées par les caractéristiques des réseaux de nanotrous. Dans les travaux rapportés ici, la nature du métal utilisé, le diamètre ainsi que la périodicité des trous sont variés pour étudier leur influence sur les bandes LSPR du spectre en transmission pour maximiser cette sensibilité, visant la fabrication d’un biocapteur. Les surfaces d’argent, ayant un diamètre de nanotrous inférieur à 200 nm pour une périodicité de 450 nm et les nanotrous d’une périodicité de 650 nm démontre un potentiel de sensibilité supérieur. / Biosensors are used daily to determine the presence of biomolecules in a complex matrix, like urine for pregnancy test or blood with a glucometer. The usual biodetection methods require the addition of a tag on the analyte, which is to be avoided to design a simple analytical method. The objective of this work is to maximize the sensitivity of a gold or silver nanohole arrays to detect the biomolecules liaisons close to the metal surface by localized surface plasmon resonance (LSPR) in transmission spectroscopy. A portable and effective biosensor to quantify analytes could be built based on this work, without a tagging step. To achieve the objective of evaluating numerous configurations for maximal sensitivity, the time and cost of the usual nanostructures fabrication methods would have limited the number of nanohole arrays in metal surface that could have been studied in this project. This fact motivated another objective of this project, the development of a fast and low cost fabrication method for nanohole arrays using nanospheres lithography (NSL) followed by reactive ions etching (RIE). The plasmon sensitivity and wavelength excitation are influenced by the nanohole arrays characteristics. In the work presented here, the chemical composition of the metal surface, the diameter and the periodicity of the nanohole arrays are shown to the influence the LSPR bands. The transmission maximum and minimum position of some LSPR bands are sensitive to refractive index change, which can be exploited in a biosensor format to detect biomolecules. The optimization of these nanohole arrays characteristics allows the maximization of this sensitivity to build a biosensor. The best index refraction sensitive results were with silver surfaces, with nanohole diameters smaller than 200 nm for a periodicity of 450 nm and the nanoholes with a periodicity of 650 nm show a potential for an increased sensitivity.

Lithographie de nanosphère

Or

Argent

Diamètre

Périodicité

Nanosphere lithography

Oxygen plasma etching

Gold

Silver

Sensibility to refractive index

Diameter

Periodicity

Propriétés des monocouches auto-assemblées du liquide ionique 1-(12-mercaptododécyl)-3-méthylimidazolium

Ratel, Mathieu

08 1900

Les propriétés d'une nouvelle classe de chimie de surface basée sur les monocouches auto-assemblées de liquides ioniques (ILs-SAMs), ont été étudiées pour une utilisation dans la construction de biocapteurs basés sur la résonance des plasmons de surface (SPR). Les biocapteurs sont utiles pour détecter des biomolécules spécifiques dans une matrice biologique complexe. Cependant, le signal analytique de la biomolécule spécifique peut être masqué par l’adsorption non spécifique de la matrice biologique, produisant une réponse faussement positive. Par ailleurs, l'activité des récepteurs moléculaires est souvent réduite par des techniques d'immobilisation chimique. Ainsi, il est essentiel de déterminer une surface idéale pour la préparation de biocapteurs. Les liquides ioniques sont bien connus pour favoriser l'activité des récepteurs moléculaires et cette étude enquête si cette propriété importante peut se traduire sur des capteurs SPR. Différents liquides ioniques ont été utilisés pour former des monocouches auto-assemblées sur une surface d'or. Les ILs-SAMs sont tous basés sur les sels de mercapto-(chaîne alkyle)nCH2-méthylimidazolium avec différentes chaînes alkyles (n = 3, 6, 9, 12) et différents contre-anions (Br-, BF4-, PF6-, NTf2-). Des études cinétiques de l'adsorption non spécifique de sérum bovin ont été réalisées sur des capteurs SPR avec un instrument construit sur mesure, basé sur l'interrogation des longueurs d’ondes SPR sur un prisme d’inversion d’image (dove). Par la suite, l’anti-IgG de chèvre sélective à l’IgG humain a été utilisé en tant que modèle pour la confection de biocapteurs sur les ILs-SAMs. En solution, il est possible d’effectuer des échanges du contre-anion des liquides ioniques pour un contre-anion de plus en plus hydrophobe. Cependant, l’échange inverse, soit vers des anions de plus en plus hydrophile, s’avère impossible. Toutefois, il a été observé par les travaux présentés dans ce mémoire, que les liquides ioniques immobilisés sur une surface d'or ont la capacité d'échanger leurs contre-anions réversiblement, procurant une méthode simple de moduler leurs propriétés physico-chimiques. Ce phénomène a été observé par la mesure d’angles de contacts et par les techniques spectroscopiques de l’infrarouge moyen (mid-IR), des photoélectrons de rayon-X (XPS) et par la diffusion Raman exaltée par les surfaces (SERS) ii ainsi que par la spectrométrie de masse (MS). La connaissance des propriétés d’échange d’anion est importante pour prédire le comportement de ces surfaces de liquides ioniques dans les tampons et fluides biologiques. / The properties of a novel class of surface chemistry based on ionic liquid self-assembled monolayers (IL-SAM) were investigated for use with surface plasmon resonance (SPR) biosensors. Biosensors are useful to detect specific biomolecules in a complex biological matrix. However, the analytical signal of a specific biomolecule can be masked by nonspecific adsorption of the biological matrix, resulting in a false positive response. Moreover, the activity of molecular receptors is often reduced by current immobilization chemistry. Thus, it is essential to determine an ideal surface for the preparation of biosensors. Ionic liquids are well-known to promote the activity of molecular receptors and this study investigates if this important property translates to SPR sensors. Different ionic liquids were used to form self-assembled monolayers on a gold surface. IL-SAM were based on mercapto(alkyl chain)n methylimidazolium salts with different alkyl chain (n = 3, 6, 9, 12) and counter anions (Br-, BF4-, PF6-, NTf2-). Kinetic studies of the nonspecific adsorption of bovine serum were carried on SPR sensors with a custom built instrument based on wavelength interrogation SPR on a dove prism. Thereafter, anti-goat IgG selective to human IgG was used as a model for biosensor employing ILs-SAM surface chemistry. Exchange of counter anion of ionic liquids was believed impossible for most hydrophobic counter anions. However, it was observed that ionic liquids immobilized on a gold surface have the ability to exchange their counter anions reversibly, allowing a simple method to modulate their physico-chemical properties. This phenomenon was observed by contact angle technique and by attenuated total reflectance mid-infrared (ATR mid-IR), X-ray photoelectron spectroscopy (XPS), surface enhanced raman spectroscopy (SERS) and mass spectrometry (MS). Better understanding of the anion exchange properties is crucial in predicting the behaviour of IL-SAM in presence of biological buffers and fluids.

Liquide ionique

Ionic liquid

monocouche auto-assemblée

self-assembled monolayers

chimie de surface

surface chemistry

adsorption non spécifique

non-specific adsorption

biocapteur

biosensor

résonance des plasmons de surface

surface plasmon resonance