Développement de conjugués peptidiques fluorocarbonés pour augmenter la stabilité plasmatique de peptides visant des récepteurs couplés aux protéines G / Development of fluorocarbon peptide conjugates to increase the plasma stability of peptides targeting GPCRs

Esteoulle, Lucie

05 October 2018

Afin d’améliorer la stabilité plasmatique de peptides, nous avons développé une nouvelle stratégie basée sur l’introduction d’une chaîne fluorocarbonée dans la séquence d’un peptide natif. En appliquant le concept à l’apeline-17, un peptide présentant un intérêt potentiel pour le traitement de maladies cardiovasculaires, nous avons amélioré sa stabilité plasmatique de 4 min à plus de 24 h ainsi que son efficacité in vivo. L’étude du mécanisme de stabilisation a permis de mettre en évidence la liaison de la fluoroapeline à l’albumine, conduisant à la protection du peptide vis-à-vis de la protéolyse. Le concept a été appliqué à d’autres peptides tels que l’apeline-13, l’angiotensine II, l’ocytocine et la spexine, démontrant ainsi l’étendue et les limitations de la méthode. Enfin, nous avons également conçu des sondes fluorescentes « turn-on » originales capables de révéler leur fluorescence uniquement après liaison au récepteur ciblé. Ces sondes pourront nous servir, par la suite, pour l’étude in vivo de la biodistribution des fluoropeptides. / In order to improve the plasma stability of peptides, we have developed a new strategy based on the introduction of a fluorocarbon chain in the sequence of a native peptide. By applying this concept to apelin-17, a peptide showing a potential interest for the treatment of cardiovascular diseases, we have improved its plasma stability from 4.6 min to more than 24 h as well as its in vivo efficacy. The mechanism leading to the increase of plasma stability has been carefully investigated demonstrating the binding of the fluoroapeline to the albumin, leading to protection towards roteolysis. The concept has been applied to other peptides such as apelin-13, angiotensin II, oxytocin and spexine, showing the extension and the limitations of this method. Finally, we have designed original fluorescent fluorogenic probes which turn on their fluorescence only after binding to the targeted receptor. These probes could be used for in vivo biodistribution studies of fluoropeptides.

RCPG

Stabilité plasmatique

Chaîne fluorocarbonée

Thérapie

Peptides

GPCRs

Plasma stability

Fluorocarbon chain

Fluorescent probes

Therapy

572.6

Fluorocarbon Post-Etch Residue Removal Using Radical Anion Chemistry

Timmons, Christopher L.

14 December 2004

During fabrication of integrated circuits, fluorocarbon plasma etching is used to pattern dielectric layers. As a byproduct of the process, a fluorocarbon residue is deposited on exposed surfaces and must be removed for subsequent processing. Conventional fluorocarbon cleaning processes typically include at least one plasma or liquid treatment that is oxidative in nature. Oxidative chemistries, however, cause material degradation to next generation low-dielectric constant (low-k) materials that are currently being implemented into fabrication processes. This work addresses the need for alternative fluorocarbon-residue removal chemistries that are compatible with next generation low-k materials. Radical anion chemistries are known for their ability to defluorinate fluorocarbon materials by a reductive mechanism. Naphthalene radical anion solutions, generated using sodium metal, are used to establish cleaning effectiveness with planar model residue films. The penetration rate of the defluorination reaction into model fluorocarbon film residues is measured and modeled. Because sodium is incompatible with integrated circuit processing, naphthalene radical anions are alternatively generated using electrochemical techniques. Using electrochemically-generated radical anions, residue removal from industrially patterned etch structures is used to evaluate the process cleaning efficiency. Optimization of the radical anion concentration and exposure time is important for effective residue removal. The efficiency of removal also depends on the feature spacing and the electrochemical solvent chosen. The synergistic combination of radical anion defluorination and wetting or swelling of the residue by the solvent is necessary for complete removal. In order to understand the interaction between the solvent and the residue, the surface and interfacial energy are determined using an Owens/Wendt analysis. These studies reveal chemical similarities between specific solvents and the model residue films. This approach can also be used to predict residue or film swelling by interaction with chemically similar solvents.

Radical anions

Fluorocarbon post-etch residue

Semiconductors Cleaning

Anions

Semiconductor wafers Cleaning

Langmuir-Blodgett films of polymers with fluorocarbon side chains as gas separation membranes

Song, Leila Shia

January 1990

No description available.

Chemistry, Polymer

Biomimetic fluorocarbon surfactant polymers designed for use on small diameter ePTFE vascular graft

Wang, Shuwu

16 July 2004

No description available.

Engineering, Biomedical

PTFE

ePTFE

fluorocarbon

vascular graft

polymer

surfactant

biomimetic

platelet

Staphylococcus epidermidis

endothelial cell

FLUORINATION OF SILICONE RUBBER BY PLASMA POLYMERIZATION

FIELDING, JENNIFER CHASE

01 July 2004

No description available.

Engineering, Materials Science

plasma polymerization

thin film deposition

surface engineering

fluorocarbon

surface energy

oil diffusion

Perfluoroalkylated compounds at the Interfaces : surface nanodomains and spherulites : interactions with phospholipid films / Composés perfluoroalkylés aux interfaces : nanodomaines de surface et sphérulites : interactions avec les films des phospholipides

Liu, Xian-He

22 October 2018

Cette thèse concerne l’auto-assemblage d'alcanes semi-fluorés (FnHm) et de fluorocarbures (FCs) aux interfaces et leurs interactions avec des phospholipides (PLs) en 2D et 3D. Nous avons étudié les sphérulites formées dans des films de diblocs FnHm. La morphologie de ces sphérulites, concentrique ou radiale, est contrôlée par la longueur des blocs Fn et Hm et la vitesse de refroidissement. Les nanodomaines de diblocs FnHm dans les monocouches de Langmuir sont incompressibles et forment des gels physiques 2D, même à pression nulle. Les blocs Hm sont cristallisés et inclinés d’ ~30°C par rapport à la normale à la surface. La réflectivité de neutrons a montré que l’albumine adsorbée sur des monocouches de PL est désorbée par un FC gazeux. Ce résultat pourrait permettre de lutter contre l’inactivation du surfactant pulmonaire par les protéines sériques. L’ajout de diblocs à des films de PLs accroit l'élasticité des monocouches. Nous avons préparé des microbulles stables à parois de PLs/FnHm, les diblocs agissant en co-surfactants. / This thesis focuses on the self-assembly of semi-fluorinated alkanes (FnHm) and fluorocarbons (FCs) at interfaces and their interactions with phospholipids (PLs) in 2D and 3D. 2D Spherulites were identified in FnHm films for the first time. Their morphology, ring-banded or radial, was controlled by varying block lengths and cooling rate. Nanodomains of FnHm in monolayers formed incompressible 2D physical gels, even at zero surface pressure. The Hm segments are crystalline and titled by 30°C to the normal to the surface. Neutron reflectivity showed that albumin adsorbed on PLs monolayers is desorbed by exposure to FC gas, which opens the potential use of FCs to treat the inactivation of the lung surfactant by serum proteins. Incorporating FnHm into PL monolayers increases their elasticity. Small, stable microbubbles of PLs/FnHm were obtained. FnHm diblocks function as co-surfactants for stabilizing microbubbles.

Alcane semi-fluoré

Fluorocarbure

Albumine

Sphérulite

Phospholipide

Monocouche

Microbulle

Semi-fluorinated alkane

Fluorocarbon

Serum albumin

Phospholipid

Spherulite

Monolayer

Microbubble

547.1

Separation of fluorocarbon gases from a reactor plasma system / Alfred Teo Grunenberg

Grunenberg, Alfred Teo

January 2008

South Africa has natural resources in mineral feedstock containing gold, manganese, chromium, vanadium, copper, antimony, phosphate rock, uranium, fluorspar and titanium. A high percentage of these ores are exported in unbeneficiated form. There are beneficiation opportunities to transform the raw materials to value-added products, thus increasing employment and stimulating the South African economy. Fluorocarbon (CxFy) gases can be produced via high-temperature plasma processes, where fluorspar and carbon (CaF2 + C) react at -6000K. These gases are traditionally separated by means of costly and unsafe cryogenic distillation. The focus of this project is to propose a feasible separation process and to interlink it to a plasma system in order to develop a conceptual plant that can produce 2500 t/a C2F4 and 625 t/a C3F6 safely and cost-effectively, both with 96% purity. To execute the above a literature survey was done giving vital information on absorption and distillation systems as well as membranes that can be used to separate CF4 from CxFy gas streams at acceptable pressures and temperatures. / Thesis (M.Sc. Engineering Sciences (Chemical Engineering))--North-West University, Potchefstroom Campus,

Fluorocarbon

Fluorspar

CxFy

CF₄

C₂F₄

C₂F₆

C₃F₆

Teflon-coated membrane

Plasma arc system

Membranes

High-temperature plasma

Separation of fluorocarbon gases from a reactor plasma system / Alfred Teo Grunenberg

Grunenberg, Alfred Teo

January 2008

South Africa has natural resources in mineral feedstock containing gold, manganese, chromium, vanadium, copper, antimony, phosphate rock, uranium, fluorspar and titanium. A high percentage of these ores are exported in unbeneficiated form. There are beneficiation opportunities to transform the raw materials to value-added products, thus increasing employment and stimulating the South African economy. Fluorocarbon (CxFy) gases can be produced via high-temperature plasma processes, where fluorspar and carbon (CaF2 + C) react at -6000K. These gases are traditionally separated by means of costly and unsafe cryogenic distillation. The focus of this project is to propose a feasible separation process and to interlink it to a plasma system in order to develop a conceptual plant that can produce 2500 t/a C2F4 and 625 t/a C3F6 safely and cost-effectively, both with 96% purity. To execute the above a literature survey was done giving vital information on absorption and distillation systems as well as membranes that can be used to separate CF4 from CxFy gas streams at acceptable pressures and temperatures. / Thesis (M.Sc. Engineering Sciences (Chemical Engineering))--North-West University, Potchefstroom Campus,

Fluorocarbon

Fluorspar

CxFy

CF₄

C₂F₄

C₂F₆

C₃F₆

Teflon-coated membrane

Plasma arc system

Membranes

High-temperature plasma

In situ analysis of aqueous structure and adsorption at fluorocarbon, hydrocarbon and mineral surfaces

Hopkins, Adam Justin, 1980-

09 1900

xvii, 209 p. : ill. A print copy of this thesis is available through the UO Libraries. Search the library catalog for the location and call number. / Altering and controlling the properties of solid surfaces in aqueous or other liquid phase environments has been a sought after objective for decades. With the discovery of chemisorbed self-assembled monolayers, this dream has become a reality. Oxide and metal surfaces can now be readily coated with an array of commercially available products to produce a desired fnctionality. The presence of these coatings on solid surfaces affects properties of the interfacial region by altering interfacial electrostatic fields, changing the structure of interfacial water molecules and altering the interactions of adsorbed species. This dissertation reports on in situ studies of adsorption at several solid/aqueous interfaces using vibrational sum-frequency spectroscopy, a surface specific technique. These studies are augmented by the use of atomic force microscopy and contact angle goniometry to characterize the prepared surfaces and their interactions with adsorbates. The studies investigate how changes in the surface structure and chemistry, as well as the bulk aqueous phase, affect interfacial structure. The studies within are primarily focused on the interactions of water with bare and functionalized fused silica and the relationship between the aqueous phase composition and the structure of fluorocarbon and hydrocarbon self-assembled monolayers. The variations in aqueous structure are then examined in detail using ionic strength controlled experiments to understand the direct interactions of water hydrophobically coated silica. This analysis is followed by an investigation of the competitive adsorption of methanol and water at fluorocarbon and hydrocarbon monolayers which show spectroscopic signatures of the interaction strength between fluorocarbons and hydrocarbons. Further studies are performed using butylammonium chloride to verify these spectroscopic signatures and reveal different molecular structures of adsorbed species at chemically different hydrophobic surfaces. Lastly, specific ion effects on the CaF 2 /water interface are shown using equilibrium and time-resolved sum-frequency spectroscopy. The results of all these studies have implications for an array of surface chemical applications from mineral flotation to biocompatibility. This dissertation includes previously published co-authored material. / Committee in charge: Thomas Dyke, Chairperson, Chemistry; Geraldine Richmond, Advisor, Chemistry; James Hutchison, Member, Chemistry; Mark Lonergan, Member, Chemistry; Qusheng Jin, Outside Member, Geological Sciences

Aqueous structure

Fluorocarbon

Hydrocarbon

Mineral surfaces

Self assembled monolayer

Water

Methanol

Ion adsorption

Chemistry

Physical chemistry

Materials science

Bilayers with Surfactant-induced Pores and Demixing in Micelles : Studies of Segregation in Amphiphile Systems

Kadi, Mari

January 2003

<p>The focus of this thesis has been on the effects of segregation in mixtures of amphiphilic molecules. Two different systems were investigated: fluorocarbon-hydrocarbon surfactant mixtures and lipid-surfactant mixtures.</p><p>In fluorocarbon-hydrocarbon surfactant mixtures the repulsive interactions between the chains can lead to a demixing into different types of coexisting micelles, fluorocarbon rich and hydrocarbon rich. From NMR self-diffusion measurements such a demixing was found to occur in the mixture of the partially fluorinated surfactant HFDePC and C₁₆TAC. We furthermore suggested a demixing also within the micelles to explain ¹⁹F-NMR line width data and results from neutron scattering.</p><p>In lipid-surfactant mixtures, a segregation of the molecules may instead be caused by a difference in the preferred curvature of the lipid and the surfactant residing within the same aggregate. Using a surfactant selective electrode, binding isoterms of four different cationic surfactants (C₁₂TAC, C₁₄TAC, C₁₆TAC and HFDePC) to preformed lipid (GMO) vesicles were determined. Perforated vesicles were observed by cryo-TEM in the mixture with C₁₆TAC. To explain the results from the binding isoterms, the formation of pores in the bilayer was regarded as a cooperative process, similar to micelle formation. The surfactant accumulates at the edges of the pores, and increasing the surfactant concentration results in an increased number of pores with a constant surfactant/lipid ratio at the edges.</p><p>The lipid-surfactant mixtures were also studied at the solid/solution interface using AFM. An adsorbed mesh structure, a counterpart to the bulk perforated lamellar phase, was observed for the first time.</p>

Physical chemistry

fluorocarbon surfactants

amphiphile mixtures

perforated bilayers

segregation

NMR

surfactant selective electrode

cryo-TEM

SANS

AFM

Fysikalisk kemi

Physical chemistry

Fysikalisk kemi