Global ETD Search

171	Studies of polysaccharide adsorption onto model cellulose surfaces and self-assembled monolayers by surface plasmon resonance spectroscopy Kaya, Abdulaziz 21 September 2009 (has links) Throughout the study of polymer adsorption at the air/water and solid/water interfaces, surface tension measurements and surface plasmon resonance (SPR) spectroscopy have been identified as key methods for the acquisition of structural and thermodynamic information. These techniques were used to determine air/water and cellulose/water interfacial properties of pullulan (P) and pullulan cinnamates (PCs), 2-hydroxypropyltrimethylammonium xylans (HPMAXs), and hydroxypropyl xylans (HPXs). Hydrophobic modification of pullulan with cinnamate groups promoted adsorption onto model surfaces of regenerated cellulose. In order to understand the relative contributions of hydrophilic and hydrophobic interactions towards PC adsorption, PC adsorption onto self-assembled monolayers (SAMs) with different functional groups was also studied. As the degree of cinnamate substitution increased, greater adsorption onto cellulose, methyl-terminated SAMs (SAM-CH3), and hydroxyl-terminated SAMs (SAM-OH) was observed. This study showed that hydrogen bonding alone could not provide a complete explanation for PC adsorption onto cellulose. The adsorption of cationic 2-hydroxypropyltrimethylammonium (HPMA) xylans with different degrees of substitution (DS) onto SAMs and regenerated cellulose was studied by SPR. Surface concentration (Ð ) exhibited a maximum (Ð max) for HPMAX adsorption onto carboxylic acid-terminated SAMs (SAM-COOH) at an intermediate HPMA DS of 0.10. This observation was indicative of a relatively flat conformation for adsorbed HPMAXs with higher HPMA DS because of higher linear charge densities along the polymer backbone. Ð observed for HPMAX adsorption onto regenerated cellulose and SAM-OH surfaces was relatively low compared to HPMAX adsorption onto SAM-COOH surfaces. Surface tension measurements for aqueous solutions of HPX by the Wilhelmy plate technique showed that surface tension changes ("Î³ = Î³water " Î³HPX(aq)) increased and critical aggregation concentrations generally decreased with increasing hydroxypropyl (HP) DS. Hence, even though HP substitution was necessary to induce aqueous solubility, excessive hydroxypropylation promoted aggregation in water. SPR studies indicated that HPXs did not adsorb significantly onto regenerated cellulose or SAM-OH surfaces (submonolayer coverage). In contrast, HPX did adsorb (~monolayer coverage) onto SAM-CH3 surfaces. Collectively, these studies showed natural polymers could be chemically modified to produce surface modifying agents with sufficient chemical control, whereby the surface properties of the resulting systems could be explained in terms of chemical structure and intermolecular interactions. / Ph. D. hemicelluloses xylans surface plasmon resonance spectroscopy self-assembled monolayer model cellulose surfaces polysaccharide adsorption
172	Studies on the Adsorption of Surfactants and Polymers to Surfaces and Their Effects on Colloidal Forces Tulpar, Aysen 11 November 2004 (has links) Surfactants, polymers, and their mixtures are widely used in commercial formulations of paints, water-based adhesives, detergents, food, and other products. This thesis describes measurements of the forces acting on colloidal particles in surfactant and polymer solutions. The change in force on addition of surfactants and polymers is usually caused by adsorption to an interface. In this thesis, I also describe the effect of surface charge density, surface crystallinity, surface heterogeneity, and preadsorbed polymer on surfactant adsorption. A new method for the stabilization of colloidal particles is introduced via the synthesis and adsorption of unnatural proteins. Unnatural proteins can be synthesized using the natural "machinery" of a bacterial cell with almost any primary sequence, and provide an environmentally friendly route to colloidal stabilization. As a model system, we study the stabilization of alumina, because alumina has a high Hamaker constant and is therefore difficult to stabilize. An unnatural protein with the sequence, thioredoxin-Pro39Glu10 is used. The Glu10 is anionic (pH > 3) and is designed to adsorb to positively charged alumina (pH<9). The thioredoxin-Pro39 is hydrophilic so it should remain in solution, thereby providing a steric barrier to the approach of two particles in a range of salt and pH conditions. Ellipsometry experiments show that thioredoxin-Pro39Glu10 adsorbs to alumina. Force measurements with the Atomic Force Microscopy (AFM) colloid probe technique show that adsorption of the unnatural protein leads to repulsive forces that decay exponentially with the separation between the surfaces, and are independent of salt concentration. The loss of a salt-dependent force shows that adsorption of the unnatural protein has effectively neutralized the charge on the alumina. Thus, I have shown that an unnatural protein can be used to control the stability of a colloidal system. In general, the same hydrophilic block can probably be added to a variety of anchoring blocks to stabilize different colloidal particles. Electrostatic forces are frequently responsible for the stabilization of colloidal particles. The decay length of these forces is dictated by the electrolyte concentration. The relationship between the decay length and the concentration is well understood for fully dissociated 1:1 electrolytes. Here, I examine the decay-length in solutions where the ions associate strongly. The forces are measured between silica surfaces in aqueous carboxylic acid and surfactant solutions. The decay lengths of the electrostatic double-layer force in both these solutions are well described by the usual expression for decay length when the concentration of ions is obtained from an activity measurement. The effect of the surface properties of the solid substrate on surfactant adsorption is also described in this thesis. The adsorption characteristics of a charged surfactant onto fixed charged surfaces as a function of surface charge density is reported. This is the first time that a method has been introduced for making a series of known fixed charged surfaces. Investigating surfactant adsorption to these surfaces has improved our understanding of the role of charge density in surfactant adsorption and desorption. The desired surface charge density is achieved by the use of gold-thiol self-assembled monolayers (SAMs) of different Ï -groups ("OH and "N+(CH3)3). The mole fraction of "N+(CH3)3 on the mixed SAM dictates the surface charge density. The charge on "N+(CH3)3 is fixed and does not self-regulate. The adsorption of sodium dodecyl sulfate (SDS) to the interface between these model surfaces and aqueous solutions of SDS is investigated. Atomic Force Microscopy (AFM) of the adsorbed surfactant reveals no surface micelles above the critical micelle concentration, cmc, over a wide variety of "N+(CH3)3 densities. This shows that the lateral mobility of ions other than surfactant at the interface is important for the formation of surface micelles of ionic surfactants. Adsorption isotherms of SDS (with no added salt) measured by Surface Plasmon Resonance (SPR) show a plateau region in which the surface excess of SDS is equal to the known fixed surface charge. This demonstrates that the adsorption is electrostatically driven. There is no critical surface charge density at which adsorption rises rapidly. Thus there appears to be no 'hemimicelle concentration'. My work suggests that the formation of hemimicelles depends on the lateral mobility of the surface ions. Desorption experiments starting above the cmc show rapid desorption of SDS into water until the surface excess is equal to the surface charge density. The rapid desorption is followed by a much slower desorption. The elucidation of this fast-slow desorption pattern based on charge density is made possible by the preparation of a set of constant charge surfaces. / Ph. D. Atomic Force Microscopy Surface Plasmon Resonance Self-Assembled Monolayer Surface Charge
173	Self-Assembly of Pullulan Abietate on Cellulose Surfaces Gradwell, Sheila Elizabeth 02 September 2004 (has links) Wood is a complex biocomposite that exhibits a high work of fracture, making it an ideal model for multiphase man-made materials. Typically, man-made composites demonstrate interfacial fracture at failure due to abrupt transitions between neighboring phases. This phenomenon does not occur in wood because gradual phase transitions exist between regions of cellulose, hemicellulose, and lignin and therefore adhesion between adjacent phases is increased. The formation of interphases occurs as a consequence of the self-assembly process which governs the formation of wood. If this process was understood more thoroughly, perhaps tougher man-made, biobased composites could be prepared. To study self-assembly phenomena in wood, a system composed of a model copolymer (pullulan abietate, DS=0.027) representing the lignin-carbohydrate complex (LCC) and a model surface for cellulose fibers was used. The self-assembly of the polysaccharide pullulan abietate (DS=0.027) onto a regenerated cellulose surface prepared using the Langmuir-Blodgett (LB) technique was studied via surface plasmon resonance (SPR). Rapid, spontaneous, and desorption-resistant cellulose surface modification resulted when exposed to the model LCC. Adsorption was quantified using the de Feijter equation revealing that between 9-10 anhydroglucose units (AGUs) adsorb per nm&178; of cellulose surface area when cellulose is exposed to pullulan abietate (DS=0.027) compared to the adsorption of 6.6 AGUs per nm&178; of cellulose surface area when cellulose is exposed to unsubstituted pullulan. / Master of Science cellulose surface modification pullulan abietate Langmuir-Blodgett thin films adsorption self-assembly SPR surface plasmon resonance
174	Bioenabled Synthesis of Anisotropic Gold and Silver Nanoparticles Geng, Xi 16 June 2017 (has links) Anisotropic plasmonic noble metallic nanoparticles (APMNs) have received enormous attention due to their distinct geometric features and fascinating physicochemical properties. Owing in large part to their tailored localized surface plasmon resonance (LSPR) and the intensive electromagnetic field at the sharp corners and edges, APMNs are exceptionally well suited for biomedical applications such as biosensing, bioimaging, diagnostics and therapeutics. Although a rich variety of surfactant-assisted colloidal routes have been developed to prepare well-defined APMNs, biomedical applications necessitate tedious and rigorous purification processes for the complete removal of toxic surfactants. In this dissertation, we aim to develop generic bioenabled green synthetic methodologies towards APMNs. By applying a series of thermodynamic, kinetic and seed quality control, a series of APMNs with varied morphologies such as branched nanostars and triangular nanoprisms have been successfully prepared. We first presented the preparation of gold nanostars (Au NSTs) through a two-step approach utilizing a common Good's buffer, HEPES, as a weak reducing agent. Single crystalline Au NSTs with tunable branches up to 30 nm in length were produced and the halide ions rather than the ionic strength played a significant roles on the length of the branches of Au NSTs. Then consensus sequence tetratricopetide repeat (CTPR) proteins with increasing number of repeats were used as model proteins to probe the effects of concentration as well as the protein shape on the morphology and resulting physicochemical properties of plasmonic gold nanoparticles. Since the underlying growth mechanism for the biomimetic synthesis of APMNs remains elusive and controversial, the other objective is to elucidate the molecular interactions between inorganic species and biopolymers during the course of NP evolution. Fluorescent quenching and 2D NMR experiments have confirmed the moderate binding affinity of CTPR to the Au(0) and Au(III). We observed that the initial complexation step between gold ions and CTPR3 is ionic strength dependent. Furthermore, we also found that NPs preferentially interact with the negatively charged face of CTPR3 as observed in 2D NMR. Knowledge of binding behavior between biospecies and metal ions/NPs will facilitate rational deign of proteins for biomimetic synthesis of metallic NPs. A modified seed-mediated synthetic strategy was also developed for the growth of silver nanoprisms with low shape polydispersity, narrow size distribution and tailored plasmonic absorbance. During the seed nucleation step, CTPR proteins are utilized as potent stabilizers to facilitate the formation of planar-twinned Ag seeds. Ag nanoprisms were produced in high yield in a growth solution containing ascorbic acid and CTPR-stabilized Ag seeds. From the time-course UV-Vis and transmission electron microscopy (TEM) studies, we postulate that the growth mechanism is the combination of facet selective lateral growth and thermodynamically driven Ostwald ripening. By incorporation of seeded growth and biomimetic synthesis, gold nanotriangles (Au NTs) with tunable edge length were synthesized via a green chemical route in the presence of the designed CTPR protein, halide anions (Br⁻) and CTPR-stabilized Ag seeds. The well-defined morphologies, tailored plasmonic absorbance from visible-light to the near infrared (NIR) region, colloidal stability and biocompatibility are attributed to the synergistic action of CTPR, halide ions, and CTPR-stabilized Ag seeds. We also ascertained that a vast array of biosustainable materials including negatively charged lignin and cellulose derivatives can serve as both a potent stabilizers and an efficient nanocrystal modifiers to regulate the growth of well-defined Ag nanoprisms using a one-pot or seeded growth strategy. The influential effects of reactants and additives including the concentration of sodium lignosulfonate, H2O2 and NaBH4 were studied in great detail. It implies that appropriate physicochemical properties rather than the specific binding sequence of biomaterials are critical for the shaped-controlled growth of Ag NTs and new synthetic paradigms could be proposed based on these findings. Last but not the least, we have demonstrated the resulting APMNs, particularly, Au NSTs and Ag NTs exhibit remarkable colloidal stability, enhanced SERS performance, making them promising materials for biosensing and photothermal therapy. Since the Ag nanoprisms are susceptible to morphological deformation in the presence of strong oxidant, they also hold great potential for the colorimetric sensing of oxidative metal cation species such as Fe3+, Cr3+, etc. / Ph. D. / When a beam of light impinges on the surface of noble metallic nanoparticle (NP), particularly gold (Au) and silver (Ag), the conduction electrons are excited which induces a collective oscillatory motion, resulting in an intense localized surface plasmon resonance (LSPR) absorbance as well as the amplified localized electromagnetic filed. Owing in large part to the tailored LSPR and the intensive electromagnetic field at the sharp corners and edges, anisotropic plasmonic noble metallic nanoparticles (APMNs) can be utilized to span an array of applications such as biosensing, bioimaging, diagnostics and therapeutics. Although great advancement has been made to prepare well-defined APMNs through versatile surfactant-assisted colloidal methodologies, biomedical applications necessitate tedious and rigorous purification processes for the complete removal of toxic surfactants. To address this ubiquitous challenge, biomimetic and bioinspired green synthesis have been extensively explored to fabricate APMNs under mild and ambient conditions. In this dissertation, we aim to develop generic bioenabled synthetic strategies towards APMNs, particularly, Au nanostars and Au/Ag nanoprisms. Herein, protein mediated shape-selective synthesis of APMNs were presented, in which consensus sequence tetratricopetide repeat (CTPR) proteins and biological Good’s buffers were employed as nanocrystal growth modifiers and mild reducing agents, respectively. The dramatic implications of repeat proteins on the morphological and optical properties of the Au NPs were explicitly discussed. The other objective of this dissertation is to elucidate the molecular interactions between inorganic species and biopolymers to further unravel the underlying growth mechanism during the course of APMNs evolution. By incorporation of seeded growth and biomimetic synthesis, Ag/Au nanotriangles (Au NTs) with tunable edge length were synthesized in the presence of the designed CTPR protein, halide anions (Br⁻) and CTPR-stabilized Ag seeds. The well-defined morphologies, tailored plasmonic absorbance from visible-light to the near infrared (NIR) region, colloidal stability and biocompatibility are attributed to the synergistic action of each components in the synthetic system. Last but not the least, we have demonstrated the resulting NPs exhibit remarkable colloidal stability, mitigated cytotoxicity and surface enhanced Raman spectroscopy (SERS) performance, making them good candidates for biosensing and photothermal therapy. This work might shed light on the roles biomolecules play in green synthesis of APMNs, along with rationalizing the design of biomimetic systems to bridge the gap between the bioenabled technique and traditional colloidal synthesis. plasmonic anisotropic nanoparticles bioenabled synthesis nanoprisms nanostars SERS repeat protein lignin.
175	Adsorption of Biomacromolecules onto Polysaccharide Surfaces Zhang, Xiao 02 October 2014 (has links) Plant cell wall polysaccharides are abundant natural polymers making them potential sources for sustainable and biodegradable materials. Interfacial behavior, including adsorption and enzymatic degradation, of several plant cell wall polysaccharides and their derivatives were studied with a quartz crystal microbalance with dissipation monitoring (QCM-D), surface plasmon resonance (SPR) and atomic force microscopy (AFM). Xyloglucan adsorption isotherms were obtained to probe how cellulose-hemicellulose interactions were affected by the type of cellulose substrate and molar mass of xyloglucan. Xyloglucan as small as a heptasaccharide still adsorbed irreversibly onto cellulose. Carboxymethyl cellulose (CMC) adsorption onto cellulose and viscoelastic properties and water contents of the adsorbed CMC layers were obtained from a combination of QCM-D and SPR data. The CMC samples formed hydrated and viscoelastic layers compared to the relatively rigid xyloglucan layer. Pectin model surfaces were prepared by pectin adsorption from citric phosphate buffer onto gold substrates. These pectin model surfaces were used for subsequent interaction studies with xyloglucan and enzymatic degradation behavior. There is a strong correlation between the degree of esterification (DE) and film resistance to degradation with the high DE being the most susceptible to degradation. The adsorption of two mixed linkage glucans (MLG), barley and lichen MLG, onto regenerated cellulose (RC) surfaces in the absence and presence of other matrix polysaccharides was studied. Viscoelastic properties of the resulting layer were compared as a function of the proprotion of '-(1''3) linkages with lichen MLG forming softer gel-like layers on RC. The lichen MLG layers were further used for enzymatic degradation studies with respect to enzyme concentration, temperature, pH and ionic strength. These studies show that polymer adsorption is a promising strategy to modify material surfaces and provides fundamental understanding of interactions and biodegradation of cell wall polysaccharides at solid/liquid interfaces. / Ph. D. Surface Plasmon Resonance Cellulose Carboxymethyl Cellulose Pectin and Mixed Linkage Glucans
176	Influence of the Local Dielectric Environment and its Spatial Symmetry on Metal Nanoparticle Surface Plasmon Resonances Torrance, David 01 January 2007 (has links) This project examines how the collective oscillation of electrons in optically excited metal nanoparticles ( diameter < 100 nm) is affected by the presence of different dielectric environments. When coupled with material polarization, these collective oscillations are known as a Surface Plasmon Polaritons (SPPs), which preferentially absorb and scatter light at a specific frequency satisfying the Local Surface Plasmon Resonance (LSPR) condition. Surface plasmons on metal nanoparticles are widely studied for use in optical labeling, ultrasensitive biodetection, and thermally activated tissue treatment. In general Mie theory can be used to accurately model the optical behavior of ideal spherical particles in a homogeneous environment. However, many experiments involving LSPRs deal with metal nanoparticles in inhomogeneous environments; a typical experimental procedure involves the deposition of a colloidal suspension of metal nanoparticles directly onto a substrate. This project explains how the LSPR of nanoparticles deposited onto planar substrates depends upon the polarization of incident radiation, and demonstrates evidence of resonance tuning by comparing the optical response in various dielectric environments. Physics
177	Plasmon Directed Chemical Reactivity and Nanoparticle Self-Assembly See, Erich M. 25 April 2017 (has links) Nanotechnology has advanced to the point that nanoparticles can now be fabricated in a broad variety of shapes from a wide range of materials, each with their own properties and uses. As the list of manufacturable particles continues to grow, a new frontier presents itself: assembling these existing nanoparticles into more complicated nanoscale structures. The primary objective of this thesis is to demonstrate and characterize one such method of nanoscale construction, the plasmonically directed self-assembly of gold nanospheres onto both silver nanospheroids and gold nanorods. At the heart of this research is a the use of a photocleavable ligand (1-(6-Nitrobenzo[d][1,3]dioxol-5-yl)ethyl(4-(1,2-Dithiolan-3-yl)butyl) carbamate), which is capable of forming a photoreactive self-assembly monolayer (SAM) on gold and silver surfaces. After photoactivation, this SAM becomes positively charged at low pH, allowing it to electrostatically bind with negatively charged gold nanospheres (or other negatively charged nanoparticles). In this thesis, I describe both a secondary photoreaction that this ligand is capable post-photocleavage, which removes the ligand's ability to bind to negatively charged gold nanospheres, allowing for, among other assembly methods, reverse photopatterning. I further show that this photocleavable ligand can be used in conjunction with gold nanospheres to create aligned, metal structures on silver nanospheroid surface by exposure to linearly polarized UV light. Similarly, I also demonstrate how the ligand can be used to preferentially bind gold nanospheres to the ends of gold nanorods with the use of ultrafast femtosecond pulsed 750 nm laser light, making use of multi-photon absorption. Both methods of self-assembly, as well as the secondary photoreaction, are dependent on the plasmonics of the metal nanoparticles. This thesis also goes into the backgrounds of plasmonics, plasmonically mediated catalysis, self-assembly, and photocleavable chemicals. / Ph. D. / Nanotechnology has advanced to the point that nanoparticles can now be fabricated in a broad variety of shapes from a wide range of materials, each with their own properties and uses. As the list of manufacturable particles continues to grow, a new frontier presents itself: assembling these existing nanoparticles into more complicated nanoscale structures. The ability to build and design such structures further advances the use of nanotechnology for medical and industrial applications. In this thesis, I describe and demonstrate a method of nanoparticle self-assembly developed by our group which uses the unique optical properties of metallic nanoparticles in conjunction with a light-activated binding chemical to control and direct the assembly of gold nanoparticles onto a silver nanosphere or gold nanorod base. The preliminary results for both of these techniques are highly promising, and I describe them in detail. I furthermore explore a secondary light-driven reaction our light-activated chemical is capable of. This secondary reaction can prevent particle binding, broadening the applications and techniques of the lightactivated binding chemical. Nanotechnology Nano Plasmon Plasmonics Surface Plasmon Resonance SPR Self-assembly. nanoparticle
178	Interfacial study of cell adhesion to liquid crystals using widefield surface plasmon resonance microscopy. Soon, Chin Fhong, Khaghani, Seyed A., Youseffi, Mansour, Nafarizal, N., Saim, H., Britland, Stephen T., Blagden, Nicholas, Denyer, Morgan C.T. 16 April 2013 (has links) No / Widefield surface plasmon resonance (WSPR) microscopy provides high resolution imaging of interfacial interactions. We report the application of the WSPR imaging system in the study of the interaction between keratinocytes and liquid crystals (LC). Imaging of fixed keratinocytes cultured on gold coated surface plasmon substrates functionalized with a thin film of liquid crystals was performed in air using a 1.45 NA objective based system. Focal adhesion of the cells adhered to glass and LC were further studied using immunofluorescence staining of the vinculin. The imaging system was also simulated with 2 × 2 scattering matrix to investigate the optical reflection of the resonant plasmonic wave via the glass/gold/cell and glass/gold/LC/cell layers. WSPR imaging indicated that keratinocytes are less spread and formed distinct topography of cell–liquid crystal couplings when cultured on liquid crystal coated substrates. The simulation indicates that glass/LC shifted the surface plasmon excitation angle to 75.39° as compared to glass/air interface at 44°. The WSPR microcopy reveals that the cells remodelled their topography of adhesion at different interfaces. Interfacial interactions Keratinocytes Cell adhesion Liquid crystals
179	Design, characterisation and biosensing applications of nanoperiodic plasmonic metamaterials / Conception, caractérisation et applications de métamatériaux nanopériodiques plasmoniques pour biocapteurs Danilov, Artem 11 April 2018 (has links) 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
180	Sugar and Peptide mimics for SPR Characterization of autoantibodies in monoclonal gammopathy / Sucres et peptides mimétiques pour la caractérisation des autoanticorps dans les gammopathies monoclonales par la résonance des plasmons de Surface Cao, Yihong 21 June 2013 (has links) La gammopathie monoclonale IgM est une polyneuropathie démyélinisante sensorielle et motrice. Il a été montré qu'elle est associée à des anticorps contre des glycoprotéines associées à la myéline (MAG/SGPG). L'épitope HNK-1 est un résidu 3-sulfo-glucuronyle lié à des structures lactosamine et il est présent aussi bien dans MAG que dans SGPG (SO4-3-GlcA(β1-3)Gal-(β1-4)GlcNAc(β1-3)Gal-(β1-4)Glcβ(1-1′)Cer). Il est exprimé principalement dans le système nerveux et joue un rôle important dans la réinnervation motrice préférentielle. Toutefois, l'épitope HNK-1 est difficile à isoler et à synthétiser et les essais diagnostiques cliniques ne sont pas toujours reproductibles et fiables.Le but de notre étude est d'identifier un outil synthétique simple de diagnostic (peptide ou monosaccharide), mimétique de l'épitope HNK-1, capable de reconnaître les anticorps dans les sera des neurogammapathies par Surface Plasmon Resonance (SPR) afin qu'il soit utilisé chez des patients à l'état précoce et qu'il puisse éventuellement permettre le suivi de l'évolution de la maladie. Pour cela, nous avons essayé de synthétiser ce trisaccharide, puis nous avons réalisé la synthèse de ses monosaccharides terminaux avec différents groupements fonctionnels (glucopyranoside d'octyle, acide 1-O-octylglucuronique, acide 1-O-octyl-3-O-sulfoglucuronique et acide 8-aminooctyl-3-O-sulfo-glucuronique).Puis 10 peptides linéaires et cycliques mimant conformationellement et/ou structuralement le HNK-1 ont également été synthétisés (LSETTI, LSETTl, cyclo(-TTILSE-), cyclo(-TTlLSE-), cyclo(-TKTlLSE-), cyclo(-TETKlLSE-), TYTKlLSE, TY(SO3)TKlLSE, cyclo(-TYTKlLSE-) et cyclo(-TY(SO3)TKlLSE-)). Les cinétiques d'affinité de ces mimes sucres et peptides ont été étudiées avec un anticorps anti HNK-1 commercial en utilisant le Biacore. De plus, les mimes avec les plus fortes affinités ont été choisis pour des études d'interaction antigène-anticorps dans des sera de patients atteints de gammapathie IgM. / IgM monoclonal gammopathy is a common age-related demyelinating sensory and motor polyneuropathy. It has been shown to be associated with antibodies against myelin-associated glycoproteins (MAG/SGPG). The HNK-1 carbohydrate epitope is a terminal 3-sulfo-glucuronyl residue attached to lactosamine structures and it is shared both in MAG and SGPG (SO4-3-GlcA(β1-3)Gal-(β1-4)GlcNAc(β1-3)Gal-(β1-4)Glcβ(1-1′)Cer). It is mostly expressed in the nervous system and plays an important role in preferential motor reinnervation. Nevertheless, the HNK-1 epitope is difficult to be isolated and synthesized and diagnostic assays used in the clinics are not always reproducible and reliable. Therefore in our study, our goal is to identify a simple synthetic diagnostic tool (peptide or monosaccharide), mimetic of the HNK-1 epitope, able to recognize antibodies in neurogammopathies sera by Surface Plasmon Resonance to be used in earlier stage patients and possibly to monitor disease activity. For this reason, we firstly tried to synthesize this trisaccharide and then we achieved the synthesis of its terminal monosaccharides with different function groups (octyl glucopyranoside, octyl glucuronic acid, octyl 3-O-sulfo-glucuronic acid and 8-amino octyl 3-O-sulfo-glucuronic acid). Then 10 linear and cyclic peptides conformationally and/or structurally mimicking HNK-1 were also synthesized (LSETTI, LSETTl, cyclo(-TTILSE-), cyclo(-TTlLSE-), cyclo(-TKTlLSE-), cyclo(-TETKlLSE-), TYTKlLSE, TY(SO3)TKlLSE, cyclo(-TYTKlLSE-) and cyclo(-TY(SO3)TKlLSE-)). The SPR kinetic binding affinities of all these sugar and peptide mimics were studied with commercial anti HNK-1 antibody using Biacore. Moreover, mimics with highest binding affinities were chosen for antigen-antibody interaction study in IgM gammopathy patients' serum. Gammopathie monoclonale Surface plasmon resonance Synthèse organique/peptidique Détection d'autoanticorps HNK-1 épitope Mag/sgpg Monoclonal gammopathy Surface plasmon resonance Organic/peptide synthesis Antibodies detection HNK-1 epitope Mag/sgpg

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